Contents

Mitsubishi Electric CNC Meldas C6, C64 Maintenance Manual PDF

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Summary of Content for Mitsubishi Electric CNC Meldas C6, C64 Maintenance Manual PDF

CNC C6/C64

CONNECTION AND MAINTENANCE MANUAL

BNP-B2255E(ENG)

MELDAS and MELSEC are registered trademarks of Mitsubishi Electric Corporation. Other brands and product names throughout this manual are trademarks or registered trademarks of their respective holders.

Introduction

This manual is called MELDAS C6/C64 CONNECTION AND MAINTENANCE MANUAL and covers the items related to installation, connection and maintenance of this NC unit. Read this manual thoroughly before using. For safe use, fully understand "Precautions for Safety" on the next page first.

Details described in this manual:

CAUTION

For items described as "Restrictions" or "Usable State" in this manual, the instruction manual issued by the machine tool builder takes precedence over this manual.

Items that are not described in this manual must be interpreted as "not possible". This manual is written on the assumption that all option functions are added. Confirm the specifications issued by the machine tool builder before use.

Refer to the Instruction Manual issued by each machine tool builder for details on each machine tool.

Some screens and functions may differ depending on each NC system (or version), and some functions may not be possible. Please confirm the specifications before use.

The following manuals can be used for reference:

MELDAS C6/C64/C64T Instruction Manual BNP-B2259 MELDAS C6/C64/C64T PLC Interface Manual BNP-B2261 MELDAS C6/C64/C64T Parameter Manual BNP-B2267

Precautions for Safety

Always read this manual and enclosed documents before installation, operation, maintenance and inspection to ensure correct usage. Thoroughly understand the basics, safety information and precautions of the devices before using. This manual classifies the safety precautions into "DANGER", "WARNING" and "CAUTION".

DANGER

When the user could be subject to imminent fatalities or serious injuries if handling is mistaken.

WARNING

When the user could be subject to fatalities or serious injuries if handling is mistaken.

CAUTION

When the user could be subject to minor or moderate injuries or the property could be damaged if handling is mistaken.

Note that the items under " CAUTION", could lead to serious consequences as well depending on the situation. Please follow all items listed in Precautions for Safety as they are equally important.

For Safe Use

This product is not designed or manufactured on the assumption that the product will be

used for the equipment or systems that are to be subject to any fatal consequences. Please inquire our customer service department about any particular usage other than the normal usage as a machine tool.

1. Items related to prevention of electric shocks.

WARNING

Do not open/close the front cover while the power is ON or during operation. The high voltage terminals and charged sections will be exposed, and this could result in electric shocks.

Do not remove the front cover even when the power is OFF, except for the wiring works or periodic inspections. The inside of the controller and servo drive unit are charged, and this could result in electric shocks.

Always wait at least 15 minutes after turning the power OFF. Then, check the voltage with a tester, etc., before wiring works, inspections or connecting with peripheral devices. Failure to observe this could result in electric shocks.

Earth ground the controller, servo drive unit and servomotor according to the local laws. (In Japan, ground the 200V Series input products with Class C or higher protective grounding and the 400V Series input with Class D or higher protective grounding.)

All wiring works, maintenance and inspections must be carried out by a qualified technician. Failure to observe this could result in electric shocks. Contact your nearby Service Center or Service Station for replacing parts and servicing.

Wire the controller, servo drive unit and servomotor after installation. Failure to observe this could result in electric shocks.

Do not operate the switches with wet hands. Failure to observe this could result in electric shocks.

Do not damage, apply excessive stress, place heavy things on or sandwich the cables. Failure to observe this could result in electric shocks.

Insulate the power lead using a fixed terminal block. Failure to observe this could result in electric shocks.

2. Items related to prevention of fire

CAUTION

Install the controller, servo drive unit, servomotor and regenerative resistor on non-combustible material. Installation directly on or near combustible materials could result in fires.

If any malfunction in the unit is observed, shut off the power at the units input power side. Continuous flow of large current could result in fires.

Install an appropriate NFB (circuit breaker) and MC (contactor) on the power input section of the servo drive unit and configure the sequence that shuts the power off upon drive units emergency stop or alarm.

When a breaker is shared for multiple power supply units, the breaker may not function upon short-circuit failure in a small capacity unit. Do not share a breaker for multiple units as this is dangerous.

Incorrect wiring and connections could cause the devices to damage or burn.

3. Items related to prevention of bodily injury or property damage

DANGER

When transporting or installing a built-in IPM spindle or linear servomotor, be careful so that your hand or property will not be trapped in the servomotors or other metal objects. Also keep the devices with low magnetic tolerance away from the product.

CAUTION

Do not apply voltages to other than those indicated in the connection manual for the controller or specifications manual for the servo drive unit. Failure to observe this could cause the devices to rupture or damage, etc.

Incorrect terminal connections could cause the devices to rupture or damage, etc.

Incorrect polarity (+ -) could cause the devices to rupture or damage, etc.

Persons wearing medical devices, such as pacemakers, must stay away from this unit. The electromagnetic waves could adversely affect the medical devices.

Fins on the rear of the unit, regenerative resistor and servomotor, etc., will be hot during operation and for a while after the power has been turned OFF. Do not touch or place the parts and cables, etc. close to these sections. Failure to observe this could result in burns.

Do not enter the machines movable range during automatic operation. Keep your hands, feet or face away from the spindle during rotation.

4. General Precautions Always follow the precautions below. Incorrect handling could result in faults, injuries or

electric shocks, etc.

(1) Transportation and installation

CAUTION

Correctly transport the products according to the weights.

Use servomotors suspension bolts to transport the servomotor itself. Do not use it to transport the servomotor after installation onto the machine.

Do not stack the products exceeding the indicated limit.

Do not hold the cables, shaft or detector when transporting the servomotor.

Do not transport the controller or servo drive unit by suspending or holding the connected wires or cables.

Do not hold the front cover when transporting the servo drive unit, or the front cover could come off, causing the unit to drop.

Install on a non-combustible place where the units or motors weight can be withstood according to the instruction manual.

The servomotor does not have a complete water-proof (oil-proof) structure. Do not allow oil or water

to contact or enter the motor. Prevent the oil-soaked cutting chips from being accumulated on the motor.

When installing the motor facing upwards, take measures on the machine side so that gear oil, etc., will not enter the motor shaft.

Do not remove the detector from the servomotor. (The detector installation screw is treated with sealing.)

Do not allow foreign matters, especially, conductive foreign matters such as screws or metal chips, or combustible foreign matters such as oil, to enter the controller, servo drive unit or servomotor. Failure to observe this could result in rupture or damage.

Do not get on the product or place heavy objects on it.

Provide appropriate distance between the controller/servo drive unit and inner surface of the control panel/other devices.

Do not install or operate the controller, servo drive unit or servomotor that is damaged or has missing parts.

CAUTION

Take care not to cut hands, etc. with the heat radiating fins or metal edges.

Do not block the intake/outtake ports of the servomotor with the cooling fan.

Install the controllers display unit and operation board unit on the spot where cutting oil will not reach.

The controller, servo drive unit and servomotor are precision devices, so do not drop or apply thumping vibration and strong impacts on them.

Hard disk unit is a precision device, so do not drop or apply strong impacts on it.

Store and use the units according to the environment conditions indicated in each specifications manual.

Securely fix the motor to the machine. The motor could come off during operation if insecurely fixed.

Always install the servomotor with reduction gear in the designated direction. Failure to observe this could result in oil leaks.

Always install a cover, etc., over the shaft so that the rotary section of the spindle motor cannot be touched during motor rotation.

When using a coupling connection to the servomotor shaft end, do not apply impacts by hammering, etc. The detector could be damaged.

Use a flexible coupling when connecting with a ball screw, etc., and keep the shaft core deviation smaller than the tolerable radial load of the shaft.

Do not use a rigid coupling as an excessive bending load will be applied on the shaft and could cause the shaft to break.

Do not apply a load exceeding the tolerable level onto the motor shaft. The shaft or bearing could be damaged.

Before using this product after a long period of storage, please contact the Mitsubishi Service Station or Service Center.

Following the UN recommendations, battery units and batteries should be transported based on the international regulations such as those determined by International Civil Aviation Organization (ICAO), International Air Transport Association (IATA), International Maritime Organization (IMO) and U.S. Department of Transportation (DOT).

(2) Items related to wiring

CAUTION

Correctly wire this product. Failure to observe this could result in servomotor runaway, etc.

Do not install a phase advancing capacitor, surge absorber or radio noise filter on the output side of the servo drive unit.

Correctly connect the output side (terminal U, V, W). The servomotor will not run properly if incorrectly connected.

Always install an AC reactor per each power supply unit.

Always install an appropriate breaker per each power supply unit. A breaker cannot be shared for multiple power supply units.

Do not directly connect a commercial power supply to the servomotor. Failure to observe this could result in faults.

When using an inductive load such as relays, always connect a diode in parallel to the load as a noise countermeasure.

When using a capacitive load such as a lamp, always connect a protective resistor in series to the load to suppress rush currents.

Do not mistake the direction of the surge absorption diode to be installed on the DC relay for the control output signal. If mistaken, the signal will not be output due to fault in the drive unit, and consequently the protective circuit, such as emergency stop, could be disabled.

RA RA

COM (24VDC)

Control output signal

Servo drive unit

COM (24VDC)

Servo drive unit

Control output signal

Do not connect or disconnect the connection cables between each unit while the power is ON.

Do not connect or disconnect the PCBs while the power is ON.

Do not pull the cables when connecting/disconnecting it.

Securely tighten the cable connector fixing screw or fixing mechanism. Insufficient fixing could result

in dislocation during operation.

Always treat the shield cables indicated in the Connection Manual with grounding measures such as cable clamps.

CAUTION

Separate the signal wire from the drive line or power line when wiring.

Use wires and cables whose wire diameter, heat resistance level and bending capacity are compatible with the system.

Ground the device according to the requirements of the country where the device is to be used.

Wire the heat radiating fins and wires so that they do not contact.

When using the RS-232C device as a peripheral device, caution must be paid for connector connection/disconnection.

Always use a double-OFF type AC power supply switch on the device side, and connect/disconnect the connector with the AC power supply on the device side OFF.

NC unit

Device Switch AC socket

RS-232C

(3) Adjustments

CAUTION

Check and adjust programs and each parameter before starting operation. Unpredictable operations could occur depending on the machine.

Do not make drastic adjustments or changes as the operation could become unstable.

(4) Usage

CAUTION

Install an external emergency stop circuit so that the power will turn OFF followed by the immediate operation stop. A contactor, etc., is required in addition to the shutoff function mounted in the controller.

Turn OFF the power immediately if any smoke, abnormal noise or odor is generated from the controller, servo drive unit or servomotor.

Only a qualified technician may disassemble or repair this product.

CAUTION

Do not alter.

Use a noise filter, etc. to reduce the effect of electromagnetic disturbances. Electromagnetic disturbances could adversely affect the electronic devices used near the servo drive unit.

Use the servo drive unit, servomotor and each regenerative resistor with the designated

combination. Failure to observe this could result in fires or faults.

The combination of the servomotor and servo drive unit that can be used is determined. Be sure to check the models of servomotor and servo drive unit before test operation.

The brakes (electromagnetic brakes) mounted in the servomotor are used for the purpose of holding, and must not be used for normal braking. Also, do not run the motor with the motor brake applied. Motor brake is used for the purpose of holding.

For the system running via a timing belt, install a brake on the machine side so that safety can be ensured.

Be sure to confirm SERVO OFF (or READY OFF) when applying the magnetic brake. Also, be sure to confirm SERVO ON prior to releasing the brake.

When using the DC OFF type electromagnetic brake, be sure to install a surge absorber on the

brake terminal.

Do not connect or disconnect the cannon plug while the electromagnetic brakes power is ON. The cannon plug pins could be damaged by sparks.

After changing programs/parameters, or after maintenance/inspection, always carry out a test operation before starting actual operation.

Use the power (input voltage, input frequency, tolerable instantaneous power failure time) that are complied with the power specification conditions indicated in each Specifications manual.

When making detector cables, do not mistake connection. Failure to observe this could result in malfunction, runaway or fire.

When using NC card, first power ON the NC card, and then the base I/O unit. If the base I/O unit is powered ON first, current flows from the connection cable to the NC card, resulting in malfunction in the PC or the cards installed in the PC.

(5) Troubleshooting

CAUTION

Use a servomotor with electromagnetic brakes or establish an external brake mechanism for the purpose of holding; this serves as countermeasures for possible hazardous situation caused by power failure or product fault.

Use a double circuit structure for the electromagnetic brakes operation circuit so that the brakes will activate even when the external emergency stop signal is issued.

Servomotor

Electro- magnetic brake

Shut off with motor brake control output

Shut off with CNC brake control PLC output

MBR EMG

24VDC

The machine could suddenly restart when the power is restored after an instantaneous power failure, so stay away from the machine. (Design the machine so that the operator safety can be ensured even if the machine restarts.)

To secure the absolute position, do not shut off the servo drive units control power supply when its battery voltage becomes low (warning 9F)

If the battery voltage drop warning alarm occurs, make sure to back up the machining programs, tool data and parameters, etc. with the input/output device before replacing the battery. Depending on the level of voltage drop, there is the possibility of memory loss. Reload all the data backed up before the alarm occurrence.

(6) Maintenance, inspection and part replacement

CAUTION

Periodically back up the programs, tool data and parameters to avoid potential data loss. Also, back up those data before maintenance and inspections.

When replacing the battery on the controller side, the machining programs, tool data and parameters, etc., should be backed up with the input/output device beforehand. In case the memory is damaged in replacing the batteries, reload all the data backed up before the alarm occurrence.

The electrolytic capacitors capacity will drop due to deterioration. To prevent secondary damage due to capacitors faults, Mitsubishi recommends the electrolytic capacitor to be replaced approx. every five years even when used in a normal environment. Contact the Service Center or Service Station for replacements.

Do not perform a megger test (insulation resistance measurement) during inspection.

Do not replace parts or devices while the power is ON.

CAUTION

Do not short-circuit, charge, overheat, incinerate or disassemble the battery.

The hard disk unit has a service life, and must be replaced before its expiration.

As a precautionary measure, always back up the customers data stored in the hard disk unit. The

safety of the customers data stored in the hard disk unit cannot be guaranteed.

There may be a unit filled with substitute Freon in the heat radiating fins of the 37kW or smaller unit. Be careful not to break the heat radiating fins during maintenance or replacement.

(7) Disposal

CAUTION

Take the batteries and backlights for LCD off from the controller, servo drive unit and servomotor, and dispose of them as general industrial wastes.

Do not alter or disassemble controller, servo drive unit, or servomotor.

Dispose of the spent batteries and the backlights for LCD according to the local laws.

(8) General precautions

To explain the details, drawings given in this instruction manual, etc., may show the unit with the cover or safety partition removed. When operating the product, always place the cover or partitions back to their original position, and operate as indicated in the instruction manual, etc.

I

CONTENTS I. Connection Manual 1. OUTLINE .......................................................................................................................... I-1 2. CONFIGURATION ............................................................................................................. I-2 2.1 System Configuration................................................................................................ I-2 2.2 List of Configuration Units ......................................................................................... I-3 3. INSTALLATION ................................................................................................................. I-6 3.1 General Specification................................................................................................ I-6 3.2 General Connection Diagram.................................................................................... I-8 3.3 Countermeasures against Heat Radiation .............................................................. I-11 3.4 Noise Countermeasures ......................................................................................... I-12 3.4.1 Connection of Frame Ground (FG) ................................................................ I-12 3.4.2 Shield Clamping of Cables............................................................................. I-13 3.4.3 Connection of Spark Killer ............................................................................. I-14 3.4.4 Countermeasures against Lightning Surge Protection .................................. I-15 3.5 Installation............................................................................................................... I-17 3.6 Mounting Conditions ............................................................................................... I-18 3.7 Turning the Power ON Again .................................................................................. I-19 4. CONTROL UNIT CONNECTIONS................................................................................... I-20 4.1 Names of Each Control Unit Part ............................................................................ I-20 4.2 Connecting the Power Supply................................................................................. I-21 4.3 Connecting the Communication Terminal ............................................................... I-22 4.4 Connecting the Synchronous Feed Encoder .......................................................... I-23 4.5 Connecting the Sensor Signal (skip)....................................................................... I-24 4.6 Connecting the Servo Drive Unit............................................................................. I-25 4.7 Connecting the Manual Pulse Generator ................................................................ I-26 4.8 Connecting the Machine Control Signal.................................................................. I-27 4.9 Connecting the Remote I/O Unit ............................................................................. I-32 4.10 Connecting the RS-232C Device .......................................................................... I-34 4.11 Connecting Other Peripheral Devices................................................................... I-35 4.12 Connecting the Display Unit with Ethernet............................................................ I-38 4.13 Connecting the Network with MELSECNET/10 .................................................... I-39 4.14 Connecting the IO Device with CC-Link................................................................ I-41 4.15 Connecting the IO Device with DeviceNet ............................................................ I-43 4.16 Control Unit Connector Pin Assignments.............................................................. I-45

II

5. CONNECTION OF COMMUNICATION TERMINAL ....................................................... I-48 5.1 Outline of Communication Terminal........................................................................ I-48 5.2 Connection of Power Supply................................................................................... I-49

5.2.1 Connection of Power Supply to 7.2-type Monochrome LCD (FCUA-LD100/FCUA-LD10+KB20)................................................................ I-49

5.2.2 Connection of Power Supply to 10.4-type Monochrome LCD (FCU6-DUT32+KB021) .................................................................................. I-50

5.2.3 Connection of Power Supply to 9-type CRT (FCUA-CT100/FCUA-CR10+KB10) ............................................................. I-51

5.3 Internal Connections ............................................................................................... I-52 5.4 Connection of Remote I/O Unit ............................................................................... I-53 5.5 Example of Connecting Multiple Control Units to the Communication

Terminal .................................................................................................................. I-54 6. CONNECTION OF REMOTE I/O UNIT............................................................................ I-55 6.1 Outline of Remote I/O Unit ...................................................................................... I-55 6.2 Names of Each Remote I/O Unit Section................................................................ I-56 6.3 Setting the Station No. When Using Multiple Remote I/O Units.............................. I-57 6.4 Connection of Remote I/O Power Supply ............................................................... I-58 6.5 Outline of Digital Signal Input Circuit....................................................................... I-59 6.6 Outline of Digital Signal Output Circuit.................................................................... I-61 6.7 Outline of Analog Signal Output Circuit................................................................... I-62 6.8 Outline of Analog Signal Input Circuit ..................................................................... I-63 6.9 Connection of FCUA-DX10 o /13 o /14 o Unit and Machine Control Signal ........... I-64 6.10 Connection of FCUA-DX11o Unit and Machine Control Signal ............................ I-66

6.11 Connection of FCUA-DX12 o Unit and Machine Control Signal ........................... I-68 6.12 Connection of FCUA-DX13 o Unit and Manual Pulse Generator.......................... I-70 6.13 Outline of FCUA-DX13 o Unit Pulse Input Circuit ................................................. I-71 6.14 Connection of FCUA-DX14 o Unit and Analog Input/Output Signal...................... I-72 6.15 Cables................................................................................................................... I-73 APPENDIX 1 OUTLINE AND INSTALLATION DIMENSIONS FOR CONTROL UNIT .... I-74 Appendix 1.1 Outline and Installation Dimensions for Control Unit............................... I-74 Appendix 1.2 Outline and Installation Dimensions for Control Unit

with External Extension Unit .................................................................... I-75 APPENDIX 2 OUTLINE AND INSTALLATION DIMENSIONS FOR COMMUNICATION

TERMINAL .................................................................................................. I-76 Appendix 2.1 Outline and Installation Dimensions for FCUA-CT100............................ I-76 Appendix 2.2 Outline and Installation Dimensions for FCUA-CR10 ............................. I-77 Appendix 2.3 Outline and Installation Dimensions for FCUA-LD100 ............................ I-78 Appendix 2.4 Outline and Installation Dimensions for FCUA-LD10 and KB20 ............. I-79 Appendix 2.5 Outline and Installation Dimensions for FCU6-DUT32, KB021............... I-80 APPENDIX 3 OUTLINE AND INSTALLATION DIMENSIONS FOR

REMOTE I/O UNIT...................................................................................... I-81 APPENDIX 4 OUTLINE AND INSTALLATION DIMENSIONS FOR

MANUAL PULSE GENERATOR................................................................ I-82

III

APPENDIX 5 OUTLINE AND INSTALLATION DIMENSIONS FOR SYNCHRONOUS FEED ENCODER .......................................................... I-83

APPENDIX 6 OUTLINE AND INSTALLATION DIMENSIONS FOR GROUNDING PLATE AND CLAMP FITTING............................................ I-84

APPENDIX 7 CABLE MANUFACTURING DRAWINGS .................................................. I-85 Appendix 7.1 F310 Cable Manufacturing Drawing........................................................ I-86

Appendix 7.2 F311 Cable Manufacturing Drawing........................................................ I-87 Appendix 7.3 F320 Cable Manufacturing Drawing........................................................ I-88 Appendix 7.4 F321 Cable Manufacturing Drawing........................................................ I-89 Appendix 7.5 F322 Cable Manufacturing Drawing........................................................ I-90 Appendix 7.6 F340 Cable Manufacturing Drawing........................................................ I-91 Appendix 7.7 F350 Cable Manufacturing Drawing........................................................ I-92 Appendix 7.8 F351 Cable Manufacturing Drawing........................................................ I-93 Appendix 7.9 FCUA-R000 Cable Manufacturing Drawing ............................................ I-94 Appendix 7.10 FCUA-R050 Cable Manufacturing Drawing .......................................... I-95 Appendix 7.11 FCUA-R051 Cable Manufacturing Drawing .......................................... I-96 Appendix 7.12 FCUA-R054 Cable Manufacturing Drawing .......................................... I-97 Appendix 7.13 FCUA-R055 Cable Manufacturing Drawing .......................................... I-98 Appendix 7.14 FCUA-R211 Cable Manufacturing Drawing .......................................... I-99 Appendix 7.15 FCUA-R220 Cable Manufacturing Drawing ........................................ I-100 Appendix 7.16 F300 Cable Manufacturing Drawing.................................................... I-101 APPENDIX 8 LIST OF CONNECTOR SETS .................................................................. I-104 APPENDIX 9 EMC INSTALLATION GUIDELINES ........................................................ I-104 Appendix 9.1 Introduction ........................................................................................... I-104 Appendix 9.2 EMC Directives ..................................................................................... I-105 Appendix 9.3 EMC Countermeasures......................................................................... I-106 Appendix 9.4 Panel Structure ..................................................................................... I-107 Appendix 9.4.1 Countermeasures for control panel body..................................... I-107 Appendix 9.4.2 Countermeasures for door ........................................................... I-108 Appendix 9.4.3 Countermeasures for power supply ............................................. I-109 Appendix 9.5 Countermeasures for Wiring in Panel ................................................... I-110 Appendix 9.5.1 Precautions for wiring in panel ..................................................... I-110 Appendix 9.5.2 NC Unit grounding wire................................................................ I-111 Appendix 9.5.3 Shield treatment of cables ........................................................... I-112

Appendix 9.6 Parts for EMC Countermeasures ........................................................... I-114 Appendix 9.6.1 Shield clamp fitting....................................................................... I-114 Appendix 9.6.2 Ferrite core................................................................................... I-115 Appendix 9.6.3 Surge protector ............................................................................ I-116 Appendix 9.6.4 Selection of stabilized power supply ............................................ I-119

IV

II. Maintenance Manual 1. OUTLINE .........................................................................................................................II-1 1.1 Table of Configuration Lists ..................................................................................... II-1 1.2 Control Section Module Configuration ..................................................................... II-2 2. EXPLANATION OF MODULE FUNCTIONS ....................................................................II-3 2.1 HR851 Card ............................................................................................................. II-3 2.2 HR899 Card ............................................................................................................. II-5 2.3 HR891 Card ............................................................................................................. II-6 2.4 HR881/882/883/884 Card ........................................................................................ II-7 2.5 HR875/876 Card ...................................................................................................... II-8 2.6 HR877/878 Card ...................................................................................................... II-9 2.7 HR877/879 Card .................................................................................................... II-11 2.8 HR865 Card ........................................................................................................... II-13 2.9 HR871 Card ........................................................................................................... II-16 3. TROUBLESHOOTING....................................................................................................II-17 3.1 List of Unit LEDs .................................................................................................... II-17 3.2 Troubleshooting ..................................................................................................... II-18 3.2.1 Confirmation of trouble state......................................................................... II-18 3.2.2 When in trouble............................................................................................. II-19 4. Daily maintenance and periodic inspection and maintenance .................................II-23 4.1 Maintenance Tools................................................................................................. II-23 4.2 Maintenance Items................................................................................................. II-23 4.2.1 Escutcheon ................................................................................................... II-24 4.2.2 LCD Panel..................................................................................................... II-24 4.2.3 IC Card.......................................................................................................... II-24 4.3 Replacement Methods ........................................................................................... II-25 4.3.1 Cable............................................................................................................. II-25 4.3.2 Durable parts ................................................................................................ II-27 4.3.3 Control Unit ................................................................................................... II-29 4.3.4 Control PCB .................................................................................................. II-31

I. Connection Manual

1. OUTLINE

I - 1

1. OUTLINE

This manual explains the items required for installing and connecting the MELDAS C6/C64. Read this manual thoroughly and understand the product's functions and performance before starting to use. This manual is written on the assumption that all option functions are added, but the actually delivered device may not have all functions. Refer to the following documents for explanations on the functions.

MELDAS C6/C64 Specifications Manual ................................................................ BNP-B2266 MELDAS C6/C64/C64T PLC Interface Manual ...................................................... BNP-B2261 MELDAS AC Servo and Spindle MDS-C1 Series Specifications Manual .............. BNP-C3000 MELDAS MDS-B-SVJ2 Series Specifications Manual ........................................... BNP-B3937

Refer to the following document for details on the EMC Instructions for the European CE Marking.

EMC Installation Guidelines .................................................................................... BNP-B2230

2. CONFIGURATION 2.1 System Configuration

I - 2

2. CONFIGURATION 2.1 System Configuration

MITSUBISHI MELDAS

C64

Other C6/C64 control unit C6/C64 control unit

Synchronous feed encoder

Manual pulse generator RS-232C device

Max. 4 channels

Remote I/O unit DX1

Machine control signal

Servomotor Spindle motor

: Connections described in this manual.

: Connections described in separate documents.

Operation panel, etc.

Communication terminal Ethernet communication device

Remote I/O unit DX1

Sensor

Servo drive unit MDS-B-SVJ2- MR-J2-CT (Auxiliary axis)

Servo drive unit MDS-B/C1-V1/V2-

Spindle drive unit MDS-B/C1-SP- MDS-B-SPJ2-

Power supply unit MDS-B/C1-CV MDS-B-CVE-

MITSUBISHI MDS-B-SVJ2

Legend

SKIP

D IO

EX T

SERVO1

EX T

M AI

N TE

N AN

C

LED1

ENC HANDL E

SIO TERMINA L

IC CARD

DC24V IN

SERVO 2

MITSUBISHI

MELDAS C64

2. CONFIGURATION 2.2 List of Configuration Units

I - 3

2.2 List of Configuration Units

1. Control unit

Type Configuration element Details

HR851 card Main card HR891 card Back panel

FCU6-MU043 FCU6-MU042 FCU6-MU041

C6 Control unit C64 Control unit C64T Control unit HR899 card IC card interface

2. Extension unit

Type Configuration element Details

FCU6-EX871 DeviceNet (Master) HR871 card Expansion card FCU6-EX872 DeviceNet (Slave) HR872 card Expansion card FCU6-EX873 FL-net HR873 card Expansion card FCU6-EX875 Ethernet HR875/876 card Expansion card, Use as set FCU6-EX878 MELSECNET10 (Coaxial

interface) HR877/878 card Expansion card, Use as set

FCU6-EX879 MELSECNET10 (Optical interface) HR877/879 card Expansion card, Use as set

FCU6-EX878 MELSECNET/10 (Coaxial) HR877/878 card Use as set FCU6-EX879 MELSECNET/10 (Optical) HR877/879 card Use as set FCU6-HR865 CC-Link HR865 card Expansion card FCU6-EX871- 40

DeviceNet HR871 card Expansion card

FCU6-HR881 Extension DIO (Sink type) HR881 card Expansion card

FCU6-HR882 Extension DIO (Sink type, with AO) HR882 card Expansion card

FCU6-HR883 Extension DIO (Source type) HR883 card Expansion card

FCU6-HR884 Extension DIO (Source type, with AO) HR884 card Expansion card

FCU6-HR893 External extension unit HR893 card Extension back panel, a set of metal plates

2. CONFIGURATION 2.2 List of Configuration Units

I - 4

3. Communication terminal (display/NC keyboard)

Type Configuration element Details

7.2- type mono- chrome LCD RX213 card FCUA-LD100

7.2-type monochrome LCD with integrated keyboard (Integrated type/machining system sheet) Key switch /

escutcheon

Control card 24VDC input

7.2- type mono- chrome LCD Escutcheon FCUA-LD10

7.2- type monochrome LCD with display unit (Keyboard separated type) RX213 card

Use as set with FCUA-KB20 Control card 24VDC input

10.4- type mono- chrome LCD Escutcheon FCU6-DUT32

10.4- type monochrome LCD with display unit (Keyboard separated type) RX215 card

Use as set with FCUA-KB20 Control card 24VDC input

9- type CRT RX211 card FCUA-CT100

Keyboard integrated type with 9- type CRT (Integrated type/machining system sheet)

Key switch / escutcheon

Control card 24VDC input CRT 100VAC input

9- type CRT RX211 card FCUA-CT120

Keyboard integrated type with 9- type CRT (Integrated type/lathe system sheet)

Key switch / escutcheon

Control card 24VDC input CRT 100VAC input

9- type CRT Escutcheon FCUA-CR10

Display unit with 9- type CRT (Keyboard separated type)

Use as set with FCUA-KB10 Control card 24VDC input CRT 100VAC input

Key switch FCUA-KB10

Keyboard (Separated type/machining system sheet) RX211 card

Use as set with FCUA-CR10

Key switch FCUA-KB20

Keyboard (Separated type/machining system sheet)

Use as set with FCUA-LD10 or FCU6-DUT32

Key switch FCU6-KB021

Keyboard (Separated type/machining system sheet)

Use as set with FCU6-DUT32 (FCUA-KB20 with changed outline dimensions)

Key switch FCUA-KB30

Keyboard (Separated type/lathe system sheet)

Use as set with FCUA-LD10 or FCU6-DUT32

Key switch FCU6-KB031

Keyboard (Separated type/lathe system sheet)

Use as set with FCU6-DUT32 (FCUA-KB30 with changed outline dimensions)

4. Peripheral device

Type Configuration element Details

HD60 Manual pulse generator With MELDAS logo HD61-1 Manual pulse generator Without MELDAS logo Ground plate D Grounding plate D, one set Ground plate E Grounding plate E, one set

2. CONFIGURATION 2.2 List of Configuration Units

I - 5

5. Remote I/O unit

Type Configuration element Details

RX311 Base PCB : DI (sink/source)/ DO (sink) = 32/32

FCUA-DX100 DI (sink/source)/DO (sink) = 32/32

Case

RX311 Base PCB : DI (sink/source)/ DO (sink) = 32/32

RX321-1 Add-on PCB : DI (sink/source)/ DO (sink) = 32/16

FCUA-DX110 DI (sink/source)/DO (sink) = 64/48

Case

RX311 Base PCB : DI (sink/source)/ DO (sink) = 32/32

RX321

Add-on PCB : DI (sink/source)/ DO (sink) = 32/16 analog output 1 point

FCUA-DX120 DI (sink/source)/DO (sink) = 64/48 Analog output 1 point

Case

RX311 Base PCB : DI (sink/source)/ DO (sink) = 32/32

RX331 Add-on PCB : Manual pulse generator 2ch

FCUA-DX130 DI (sink/source)/DO (sink) = 32/32 Manual pulse 2ch

Case

RX311 Base PCB : DI (sink/source)/ DO (sink) = 32/32

RX341 Add-on PCB : Analog input 4

points, analog output 1 point

FCUA-DX140

DI (sink/source)/DO (sink) = 32/32 Analog input 4 points, analog output 1 point

Case

RX312 Base PCB : DI (sink/source)/ DO (source) = 32/32

FCUA-DX101 DI (sink/source)/ DO (source) = 32/32

Case

RX312 Base PCB : DI (sink/source)/ DO (source) = 32/32

RX322-1 Add-on PCB : DI (sink/source)/ DO (source) = 32/16

FCUA-DX111 DI (sink/source)/ DO (source) = 64/48

Case

RX312 Base PCB : DI (sink/source)/ DO (source) = 32/32

RX322

Add-on PCB : DI (sink/source)/ DO (source) = 32/16 analog output 1 point

FCUA-DX121 DI (sink/source)/ DO (source) = 64/48 Analog output 1 point

Case

RX312 Base PCB : DI (sink/source)/ DO (source) = 32/32

RX331 Add-on PCB : Manual pulse generator 2ch

FCUA-DX131 DI (sink/source)/ DO (source) = 32/32 Manual pulse 2ch

Case

RX312 Base PCB : DI (sink/source)/ DO (source) = 32/32

RX341 Add-on PCB : Analog input 4

points, analog output 1 point

FCUA-DX141

DI (sink/source)/ DO (source) = 32/32 Analog input 4 points, analog output 1 point

Case

3. INSTALLATION 3.1 General Specification

I - 6

3. INSTALLATION 3.1 General Specification

Type name FCU6-MU043/MU042/MU041 Unit name Control unit

During operation 0 to 55C Ambient temperature During storage 20 to 60C

During operation Long term, Up to 75% RH (with no dew condensation) Short term (Within 1 month), Up to 95% RH (with no dew condensation)Ambient

humidity During storage Up to 75% RH (with no dew condensation)

Vibration resistance 4.9m/s2 or less (during operation) Shock resistance 29.4m/s2 or less (during operation) Working atmosphere No corrosive gases, dust or oil mist G

en er

al s

pe ci

fic at

io ns

Power noise 1kV (P-P) Power voltage 24VDC5% Ripple 5% (P-P) Instantaneous stop tolerance time 2.1ms (during 24VDC line cutting)

P ow

er

sp ec

ifi ca

-t io

ns

Current consumption 3A (max.) Heating value 70W (during full option) Weight 1.6kg Unit size Refer to Appendix.

Type name MDS-B-SPJ2- MDS-B-SVJ2- Unit name Spindle drive unit Servo drive unit

During operation 0 to 55C Ambient temperature During storage 20 to 65C

During operation Up to 90% RH (with no dew condensation) Ambient humidity During storage Up to 90% RH (with no dew condensation) Vibration resistance 5.9m/s2 or less (during operation) Working atmosphere No corrosive gases, dust or oil mist

G en

er al

sp

ec ifi

ca tio

ns

Power noise 1kV (P-P)

Power voltage 3-phase 200VAC/230VAC 15% +10% 50/60Hz 5%

Instantaneous stop tolerance time 20ms P ow

er

sp ec

ifi ca

- tio

ns

Power consumption Heating value

Differs according to motor in use (Note 1)

Differs according to motor in use (Note 2)

Type name MDS-B/C1-SP-

MDS-B/C1-V1/V2-

MDS-A-CR/MDS- C1-CV

Unit name Spindle drive unit Servo drive unit Power supply unit During operation 0 to 55C Ambient

temperature During storage 15 to 70C During operation Up to 90% RH (with no dew condensation) Ambient

humidity During storage Up to 90% RH (with no dew condensation) Vibration resistance 4.9m/s2 or less (during operation) Working atmosphere No corrosive gases, dust or oil mist

G en

er al

sp

ec ifi

ca tio

ns

Power noise 1kV (P-P)

Power voltage 3-phase 200VAC/230VAC 15% +10% 50/60Hz 5%

Instantaneous stop tolerance time 20ms P ow

er

sp ec

ifi ca

- tio

ns

Power consumption Heating value

Differs according to motor in use (Note 3)

(Note 1) Refer to the MDS-B-SPJ2 Specifications Manual. (Note 2) Refer to the MDS-B-SVJ2 Specifications Manual. (Note 3) Refer to the MDS-B Series Specifications Manual and MDS-C1 Series Specifications Manual.

3. INSTALLATION 3.1 General Specification

I - 7

Type name FCUA-LD100/ FCUA-LD10+KB20

FCU6-DUT32 +KB021

FCUA-CT100/ FCUA-CR10+KB10

Unit name Communication terminal During operation 0 to 50C 0 to 55C Ambient

temperature During storage 20 to 60C 20 to 65C

During operation Long term, Up to 75% RH (with no dew condensation) Short term (Within 1 month), Up to 95% RH (with no dew condensation)Ambient

humidity During storage Up to 75% RH (with no dew condensation)

Vibration resistance 4.9m/s2 or less (during operation) Shock resistance 29.4m/s2 or less (during operation) Working atmosphere No corrosive gases, dust or oil mist G

en er

al s

pe ci

fic at

io ns

Power noise 1kV (P-P) Single phase 100 to

115VAC 15%+10%

50/60Hz5% Power voltage 24VDC5% Ripple 5% (P-P)

24VDC5% Ripple 5% (P-P)

Instantaneous stop tolerance time Follows specifications of 24VDC power supply being used

P ow

er s

pe ci

fic at

io ns

Current consumption 24V, 0.9A 100V, 0.4A 24V, 0.6A

Heating value 20W 55W Weight 1600g 2200g 4800g Unit size Refer to Appendix.

Type name FCUA- DX10

FCUA- DX11

FCUA- DX12

FCUA- DX13

FCUA- DX14

Unit name Remote I/O unit During operation 0 to 55C Ambient

temperature During storage 20 to 65C

During operation Long term, Up to 75% RH (with no dew condensation) Short term (Within 1 month), Up to 95% RH (with no dew condensation)Ambient

humidity During storage Up to 75% RH (with no dew condensation)

Vibration resistance 4.9m/s2 or less (during operation) Shock resistance 29.4m/s2 or less (during operation) Working atmosphere No corrosive gases, dust or oil mist G

en er

al s

pe ci

fic at

io ns

Power noise 1kV (P-P) Power voltage 24VDC5% Ripple 5% (P-P) Instantaneous stop tolerance time

P ow

er

sp ec

ifi ca

- tio

ns

Current consumption 24V, 0.7A (Note 4) 24V, 1.5A (Note 4) 24V, 0.7A (Note 4)

Heating value 60W (Note 5) 110W (Note 5) 60W (Note 5)

Weight 470g 570g 590g 550g Unit size Refer to Appendix.

(Note 4) Only the amount consumed by the control circuit. (Note 5) When all points of the machine input/output interface circuit are operating.

3. INSTALLATION 3.2 General Connection Diagram

I - 8

3.2 General Connection Diagram

R S T

No-fuse breaker (NFB)

3-phase 200VAC to 230VAC

Insert when required

OFF ON

MC

MC

C6

DCIN

Stablized power supply

24VDC

FG

RIO1 RIO2

24VDC R220 cable DC24V

FG

Operation panel

Terminator R-TM

or

Remote I/O unit DX1

IC memory card

To next remote I/O unit

MC link B

R211 cable

R211 cable

R220 cable

Expansion card 2

(When network card is selected.)

Expansion card 1

(When DIO card is selected.)

R211 cable

R211 cable

Communication terminal LD100/LD10+KB20/DUT32+KB021 /CT100/CR10+KB10 R300 cable

/R301 cable

R300 cable /R301 cable

SERVO2

HANDLE

ENC

SIO

SERVO1

TERMINAL

SKIP

DIO RIO-MRIO-M/S

F310 cable /F311 cable /F312 cable

R000 cable RS-232C cable

RS-422 cable F340 cable F351 cable

F351 cable

F350 cable

RS-232C device

Machine control relay/contact

Machine control relay/contact

MC link B Terminator R-TM

or

To next remote I/O unit

R211 cable

MC link A Terminator A-TM

For standard specifications final axis

For absolute position specifications final axis

CN1A1

R000 cable

Battery unit BT-

Spindle drive unit MDS-B-SPJ2-

CN1A CN1B

L2 L3 L11

C

L1

L21 MC1

P N D U V W

FG FG FG

CN2

CN1A CN1B

L2 L3 L11

C

L1

L21 MC1

P N D U V W

FG FG FG

CN2

Spindle motor with detector

AC servomotor with detector

IMSM

Detector

L11 L21

MC1 MC1

MC1

DCIN RIO1 RIO2

DC24V FG R220 cable

L11 L21

L11 L21

MC1 Regenerative resistor FCUA-

CNV2 cable /CNV12 cable

CNV2 cable /CNV12 cable

Servo drive unit MDS-B-SVJ2-

Regenerative resister FCUA-

Remote I/O unit DX1

R300 cable /R301 cable

R300 cable /R301 cable

Sensor contact Max.4 points

Manual pulse generator FCUA-HD60 Synchronous feed encoder

OSE1024-3-15-

F320 cable/F321 cable /F322 cable

R050 cable/R051 cable R054 cable/R055 cable

MELSEC, etc.

FG

CR02 CR01 CR05

DI

DO

To next unit R000 cable

NFB

: User-prepared parts

: Connectors enclosed with remote I/O unit and communication terminal.

Key

Control unit

24VDC R220 cable

DCIN

FG

MC

R

R

R

R

R000 cable

Personal computer (GX-Developer)

(1) When using the communication terminal for the display unit

Detector

(Only the access from R register)

(Note) This diagram shows a general connection example. The actual connection may differ depending on the specifications.

3. INSTALLATION 3.2 General Connection Diagram

I - 9

CN1A CN1B

L2 L3

C

L1

L21 MC1

N D U V W

FG FG FG

CN2

L1

P

CN1A CN1B

L2 L3

C

L1

L21 MC1

N D U V W

FG FG FG

CN2

P

L1

IM

Detector

SM

Spindle motor with detector

AC servomotor with detector

Spindle drive unit MDS-B-SPJ2-

Servo drive unit MDS-B-SVJ2-

MC link A Terminator A-TM

For standard specifications final axis

For absolute position specifications final axis

CN1A1 R000 cable

Battery unit BT-

: User-prepared parts

: Connectors enclosed with remote I/O unit and communication terminal

R S T

No-fuse breaker (NFB)

3-phase 200VAC to 230VAC

Stabilized power supply

DC24V

FG

DC24V R220 cable

C6

IC memory card Expansion card 2

(Ethernet)

Expansion card 1

(When DIO card is selected.)

R211 cable

SERVO2

HANDLE

ENC

SIO

SERVO1

TERMINAL

SKIP

DIO RIO-MRIO-M/S

DCIN

RS-232C cable

RS-422 cable

F340 cable

F351 cable

F351 cable

F350 cable

Machine control relay/contact

Machine control relay/contact

R

R

R

R

MC link B Terminator R-TM

or

To next remote I/O unit

R211 cable

DCIN RIO1 RIO2

DC24V FG R220 cable

Remote I/O unit DX1

R300 cable /R301 cable

R300 cable /R301 cable

R000 cable

RS-232C device

Sensor contact Max. 4 points

Manual pulse generator FCUA-HD60 Synchronous feed encoder

OSE1024-3-15-

F320 cable/F321 cable /F322 cable R050 cable/R051 cable R054 cable/R055 cable

Insert when required

OFF ON

MC

MC

L11 L21

L11 L21

L11 L21 MC1

Regenerative resistor FCUA-

Regenerative resistor FCUA-

MC1 MC1

MC1

GOT

Key

MC

R211 cable

DI

DO

CNV2 cable /CNV12 cable

NFB

To next unit R000 cable

CNV2 cable /CNV12 cable

Ethernet cable

FG Control unit

F310 cable /F311 cable /F312 cable

GOT Personal computer (GX-Developer)

RS-232C cable

(2) When using GOT or personal computer for the display unit

Detector

(Note) When using GOT or personal computer for the display unit, an Ethernet card (FCU6-EX875) must be mounted in the control unit's extension slot (EXT2).

3. INSTALLATION 3.2 General Connection Diagram

I - 10

(3) Example of Connection when Using V1/V2/SP for Drive Section

Connect to control unit SERVO1

AC servomotor

Motor end detector

Spindle motor

Battery unit

R000 cable

Motor end detector

R000 cableR000 cable

Power supply unit

MDS-A-BT-44-axis MDS-A-BT-22-axis

CN4 CN4

CN1A CN1B

U V W E

L+ L- L11 L21

(Note 2)

SM IM

ENCENC

L+ L- L11 L21 MC1

Spindle drive unit MDS-B/C1-SP-

Servo drive unit MDS-B/C1-V1/V2-

CN2CN2 L1 L2 L3 E

MC

B-AL

R S T

CN1A CN1B

U V W E

(Note 1) The drive section connection will differ according to the configuration of the servo amplifier and motor being used. (Note 2) The R000 cable has the same specifications (connector types and connections) as the SH21 cable. (Note 3) When connecting the spindle amplifier, set the axis No. to the value after the last servo axis. (Note 4) The axis connected to the power supply unit is the last axis, or the axis connected to the battery unit.

CAUTION

Separate the signal wire from the drive line/power line when wiring.

3. INSTALLATION 3.3 Countermeasures against Heat Radiation

I - 11

3.3 Countermeasures against Heat Radiation Please refer to the following procedures for heat radiation countermeasures.

Example of heat radiation countermeasures

(1) Average temperature in cabinet : T 55C (2) Cabinet peripheral temperature : Ta 0C to 45C (3) Internal temperature rise value : T = T - Ta(max) = 10 C

Procedures for heat design and verification

(1) Refer to section "3.1 General Specification" for the heat generated by each unit.

(2) Enclosed cabinet (thin steel plate) cooling capacity (W1) calculation equation

W1 = U x A x T U: 6W/m2 C

---with internal circulation fan 4W/m2 C

---without internal circulation fan A: Effective heat radiation area (m2) T: Internal temperature rise value (10C)

(Area where heat can be radiated from cabinet)

When calculating the effective heat radiation area, do not include the parts that contact other objects.

(3) Points of caution for heat radiation countermeasures when designing mounting state * Consider convection in cabinet (eliminate heat spots) * Collect hot air at suction port in heat exchanger cabinet.

(4) Criterion for internal temperature rise distribution data T (average value) 10C Tmax (maximum value) 15C

R (inconsistency Tmax Tmin) 6C (Evaluate existence of heat spots)

Comparison between W and W1

Calculate total heat generated by each mounted unit (W)

Calculate cabinets cooling capacity (W1)

Selection of heat exchanger

Mounting design

Collection of internal temperature rise distribution data

Evaluation

Improvements

Completion

W W1

W > W1

T 10C

T > 10C

Refer to section "3.1 General Specification" for the heat generated by each unit. If heat accumulates at the top of the control unit, install a circulation fan in the operation box.

If the following conditions are not satisfied, install a circulation fan in the cabinet. Criterion for internal temperature rise distribution data T (average value) 10C Tmax (maximum value) 15C

3. INSTALLATION 3.4 Noise Countermeasures

I - 12

3.4 Noise Countermeasures 3.4.1 Connection of Frame Ground (FG)

The frame should basically be grounded at one ground point. Connect the control unit and base I/O unit's 0V (RG) to the FG on the 24VDC stabilized power supply side.

FG cable

Main grounding plate for electric cabinet

Stabilized power supply (Prepare separately)

FG cable AC input

R220 cable (24VDC)

R220 cable (24VDC)

Control unit

Short bar

FG0V

D C

24V (+)

FG cable

J1

J2 CR03

CR01

CN24

CR02

CR06 CR05

OPERATION BOARD Ver. FCU6-DUT32

MITSUBISHI ELECTRIC CORP.

Communication terminal

3. INSTALLATION 3.4 Noise Countermeasures

I - 13

3.4.2 Shield Clamping of Cables

The shield cable connected to the control unit, servo amplifier and spindle amplifier must be connected to the grounding plate to stabilize operation while preventing malfunctioning due to noise. The shield can be connected to the grounding plate with lead wires, clamp fittings or the connector GND plate. Refer to the following drawings to treat the shield cable.

(1) Peel off part of the cable sheath and expose the shield as shown in the drawing. Press the exposed part against the grounding plate with the cable clamp fittings.

(2) If the cable is thin, clamp several together in a bunch. (3) Use adequate force when tightening the cable so that

the wire material is not damaged. (4) Connect each grounding plate together and ground them at one point. (5) Refer to APPENDIX 6 about the outline drawing of clamp fittings and grounding

plate.

Soldering

Shield Cable

Cable

Unit

Example of connection with lead wire

Example of connection with connector GND plate

GND plate Shield

Cable

Fold the cable shield over the sheath, and wrap copper foil tape around it. Connect the wound copper foil tape to the connectors GND plate.

Example of connection with clamp fitting

Shield Cable

Clamp fitting Grounding plate

Cable

Less than 0.8m Shield

Clamp fitting

Grounding plate

Lead wire

Unit

3. INSTALLATION 3.4 Noise Countermeasures

I - 14

The cables connected to the control unit for which the shield must be connected to the ground are shown below.

Unit name Connector name Application/function Cable shield treatment SERVO1 Servo drive unit/spindle drive unit Required SERVO2 Auxiliary axis Required HANDLE Manual pulse generator Required ENC Synchronous feed encoder Required SIO RS-232C Required TERMINAL Communication terminal Required SKIP Sensor signal Required DIO Machine input/output signal Not required RIO-M Remote I/O unit Required

Control unit (FCU6-MU043) (FCU6-MU042) (FCU6-MU041)

RIO-M/S Remote I/O unit Required 3.4.3 Connection of Spark Killer

The noise generated when the coil/contact operates must be removed. As a countermeasure, connect a spark killer in parallel with the coil/contact.

Coil

Contact

E

SK

S K

The CR compound element is effective in removing the noise generated due to magnetic induction.

Spark killer C: 0.033 to 0.1F R: 10 to 120

3. INSTALLATION 3.4 Noise Countermeasures

I - 15

3.4.4 Countermeasures against Lightning Surge Protection

Generally, lightning surge infiltrates the control power supply from the power supply line. This control power supply or the internal circuit can be damaged by lightning surge via the control power supply. If this countermeasure is not taken throughout the control panel as shown in Fig. 1, the lightning surge could flow over the signal line and damage the other devices.

Power supply line

NC control section

Power supply for panel

NC drive section (Servo, spindle amplifier)

Control panel (Relay panel, etc.)

Lightning surge path

Fig. 1 Path of damage caused by lightning surge

(1) Protective measures

Install the surge absorber on the power supply line for the separately prepared power supply units, etc., as shown in Fig. 2 and Fig. 3. The following two countermeasures are required as protection against general damage.

1) Installation of surge absorber 2) Installation of circuit protector

Control panel (Relay panel, etc.)

Other device (Power supply for panel, etc.)

Surge absorber (1)

Circuit protector

Power supply line

Fig. 2 Lightning surge countermeasures for single-phase power supply line

Control panel (Relay panel, etc.)

Other device (Power supply for panel, etc.)

Surge absorber (2)

Circuit protector

Power supply line

Surge absorber (3) Fig. 3 Lightning surge countermeasures for 3-phase power supply line

3. INSTALLATION 3.4 Noise Countermeasures

I - 16

(2) Examples of surge absorbers

Types of Okaya Electric surge absorbers

Surge absorber Type

Circuit voltage [Vrms]

Max. tolerable circuit voltage

[Vrms]

Clamp voltage

[V] 10%

Surge resistance

level 8/20s [A]

Surge withstand voltage (Electrical-discharge

start voltage) 1.2/50s [V]

(1) RAV-781BWZ-4 250 500 700 2500 2k (2) RAV-781BYZ-2 250 300 783 2500 20k (3) RAV-781BXZ-4 250 500 700 2500 2k

* Refer to the manufacturer's catalog for detailed characteristics, outline and connection methods of the surge absorber.

(3) Surge absorber installation method

Surge absorber installation method

Control panel (Relay panel, etc.)

Surge absorber (2) Surge absorber (1)

Earth leakage breaker for panel

Input 200V/ 230VAC

No-fuse breaker

No-fuse breaker MC Reactor

Transformer

Circuit protector

Grounding Grounding

From power supply

C

BA

NC drive section

Other devices (power supply for panel, etc.)

Other devices (power supply for panel, etc.)

NC control section

Precautions 1) Thick wiring enhances the lightning surge absorbing effect, so make the wiring as thick and short as

possible. Wire material : Wire diameter 2mm2 or more Wire length : Connection to surge absorber (1): Wire length (A) is 2m or less

Connection to surge absorber (2): Wire length (B) is 2m or less Grounding to surge absorber (2) : Wire length (C) is 2m or less

2) When carrying out a dielectric voltage-withstand test on the power supply line, remove surge absorber (2) as the surge absorber will function with the applied voltage.

3) A short-circuit accident will occur if a surge exceeding the tolerance is applied on the surge absorber. Thus, always insert a circuit protector to protect the power supply line.

The current does not flow constantly to surge absorbers (1) and (2), so the circuit protector can also be used for the other devices.

3. INSTALLATION 3.5 Installation

I - 17

3.5 Installation

Each unit is installed in the sealed structure cabinet as a principle. When installing into the cabinet, refer to the following drawings to consider the control unit's heat radiation and wiring, and secure enough space for ventilation.

(1) Install each unit vertically so that the front is visible. (2) Refer to the following drawings to consider the control unit's heat radiation and wiring, and secure

enough space for ventilation.

d

(Top)

(Bottom)

Servo drive unit Spindle drive unit Power supply unit Control unit

50mm or more (heat dissipation, wiring allowance)

*10mm or more when there is a unit on the left

100mm or more (heat dissipation, wiring allowance)

10mm or more (heat dissipation, wiring allowance)

MITSUBISHI

MELDAS C64

50mm or more (heat radiation

allowance)

(Note) The right side of the control unit will temporarily expand by approx. 2mm when the expansion card is inserted and removed.

It will not be possible to insert or remove the expansion card if there is no space between the control unit and adjacent unit. Always provide sufficient space.

CAUTION

Install the control unit and communication terminal on noncombustible material. Installation directly on or near combustible material may lead to fires.

Always observe the installation direction.

Do not install or operate a control unit or communication terminal that is damaged or that has missing parts.

The control unit and communication terminal are precision devices so do not drop or apply strong impacts on them.

3. INSTALLATION 3.6 Mounting Conditions

I - 18

3.6 Mounting Conditions

(1) Parts, highly susceptible to dust, are mounted with a high density inside the unit. Always use a sealed structure for the cabinet, and provide the following treatments.

Always plug the cable inlet with packing to prevent dust and oil from entering. Take care so that outdoor air does not enter the heat radiation holes, etc. Plug all clearances. Always install door packing. If there is a back lid, always install packing. Oil will easily accumulate at the ceiling, and can enter the cabinet from the screw holes. Always

take special countermeasures such as using oil-preventing packing. Packing is attached to the installation surface of the communication terminal and ready to use.

Cable

Cable inlet (Example)

Fitting

Packing

Door Display

Cabinet Rear plate

Packing

Packing

Communication terminal

Communication terminal

Packing

CAUTION

Install the communication terminal where it will not be subjected to cutting oil.

(2) Avoid machining in the area after installing each unit. Cutting chips, etc., could get on the electronic parts and cause damage.

Display

CAUTION

Do not allow conductive foreign matter such as screws or metal chips or combustible foreign matter such as oil enter the control unit or communication terminal.

(3) Design so that the cabinet's internal temperature will not exceed the ambient temperature by 10C or higher, and so that the control unit and communication terminal, etc., are within the temperature conditions. (Refer to Section 4.3 for details.) Avoid installing the cabinet where the surface temperature of the communication terminal could reach 45C or more.

(4) The CRT display may not operate correctly because of external magnetic fields. Separate sources of magnetic fields (transformer, fan, magnetic switcher, solenoid relay, magnet stand, magnetized workpiece, power lines with large currents, etc.) at least 200mm or more away from the CRT display. Note that the magnetic fields generated by these sources are each different, and will also differ depending on the installation direction. Thus, correct operation may not be possible even if the source is separated by 200mm or more. When determining the layout of magnetic field generating sources, consider the direction that the field is generated, and confirm with the actual machine.

3. INSTALLATION 3.7 Turning the Power ON Again

I - 19

3.7 Turning the Power ON Again

When turning the control unit power ON again after turning it OFF, wait at least five seconds or more. If the power is turned ON in less than five seconds, the system may not start up.

4. CONTROL UNIT CONNECTIONS 4.1 Names of Each Control Unit Part

I - 20

4. CONTROL UNIT CONNECTIONS The methods for connecting to each unit and device from the control unit are briefly explained in this section.

4.1 Names of Each Control Unit Part

(1) Battery connection connector (2) Battery (3) Display unit rotary switch (4) 24VDC input connector (5) Connector 1 for servo drive unit connection (6) Connector 2 for servo drive unit connection (7) Synchronous feed encoder connection connector (8) Manual pulse generator connection connector (9) IC memory card holder (10) RS-232C/RS-422 device connection connector (11) Communication terminal connection connector (12) Sensor signal (skip) connection connector (13) Digital signal input/output connector (14) Terminator ON/OFF switch (15) Extension slot 2 (16) Extension slot 1 (17) Maintenance connector (for memory card) (18) Remote I/O master station connector (19) Mitsubishi testing connector (20) Remote I/O master, slave station connector (21) Mitsubishi testing connector

(Note 1) The drawing option card shows the case with the Ethernet card and extension DIO card mounted.

Front view Front view

SKIP

D IO

E X

T2

SERVO1

E X

T1

M A

IN TE

N A

N C

E

LED1 LED2

ENC HANDLE

SIO TERMINAL

IC CARD

DC24V IN SERVO2

R I O - M

R I O - M / S

(17)MAINTENANCE

(14)

(13)DIO

(12)SKIP

(10)SIO

(7)ENC

(5)SERVO1

(3)

(1)

Bottom view

(16) EXT1

(15) EXT2

(11) TERMINAL

(9) IC CARD

(8) HANDLE

(6) SERVO2

(4) DC24VIN

(2)

(18)RIO-M

(19)

(20)RIO-M/S

(21)

4. CONTROL UNIT CONNECTIONS 4.2 Connecting the Power Supply

I - 21

4.2 Connecting the Power Supply

A 24VDC power supply is required for the control unit. Prepare a stabilized power supply that satisfies the following conditions. The DC24VIN connector is used to connect the power supply. Use the CN220 connector set (optional, with one end) when manufacturing the R220 cable. (Refer to the CABLE MANUFACTURING DRAWINGS for details.)

Output voltage 24VDC 5% Ripple 5% (p-p) Maximum output current 3.0A or more

24VDC(+) DC24VIN

FG

0V

R220 cable

Control unit

SKIP

D IO

EX T2

SERVO1

EX T1

M AI

N TE

N AN

C E

LED1 LED2

ENC HANDLE

SIO TERMINAL

IC CARD

DC24V IN SERVO2

MITSUBISHI

MELDAS C64

Stablized power supply (Prepare separately)

FG

Y

CAUTION

Separate the signal wire from the drive line/power line when wiring.

Do not apply a voltage other than that specified in this manual onto the connector. Failure to observe this could lead to rupture or damage.

Incorrect connections could cause device damage, so always connect the cables to the designated connectors.

4. CONTROL UNIT CONNECTIONS 4.3 Connecting the Communication Terminal

I - 22

4.3 Connecting the Communication Terminal

The TERMINAL connector is used to connect the communication terminal (FCUA-LD100, etc.). On the communication terminal side, connect the R000 cable to the CR02 connector, and supply the 24VDC power supply to the CR01 connector. Use the enclosed connector and contact to supply the +24VDC power supply. If the accessories are insufficient, prepare the one-ended CN220 connector set (optional, with one end). (Refer to the cable manufacturing drawings for details.) When connecting the communication terminal and control unit one-on-one as shown below, confirm that the switch SW2-1 under the DIO connector of the control unit is set to ON (left side).

FCUA-LD100 rear view

Recommended adaptive connector (Enclosed with FCUA-LD100) Connector : 2-178288-3 (Tyco Electronics AMP) Contact : 1-175218-5 (Tyco Electronics AMP)

Control unit

R000 cable

Note) When connecting the control unit and communication terminal one-on-one, set SW2-1 to ON (left side).

MITSUBISHI

CR01

1 2

TERMINAL

Y

O N

S W

2

TERMINAL connector

pin No.

MELDAS C64

SERVO1 SERVO2 DC24VIN

ENC HANDLE ICCARD

SIO TERMINAL

SKIP

FG 0V 24VDC

CR02

1

10

11

20

CAUTION

Incorrect connections could cause device damage, so always connect the cables to the designated connectors.

Do not connect or disconnect the connection cable between each unit while the power is ON.

4. CONTROL UNIT CONNECTIONS 4.4 Connecting the Synchronous Feed Encoder

I - 23

4.4 Connecting the Synchronous Feed Encoder

The ENC connector is used to connect the synchronous feed encoder. Use the CS050 or CS054 connector set (optional, with both ends) when manufacturing the R050 or R054 cable. (Refer to the cable manufacturing drawings for details.) Note that the synchronous feed encoder may be connected via the spindle drive unit.

ENC

Control unit

SKIP

D IO

EX T2

SERVO 1

EX T1

M AI

N TE

N AN

C E

ENC HANDLE

SIO TERMINAL

IC CARD

DC24V IN

SERVO 2

MITSUBISHI

MELDAS C64

1

10

11

20

ENC connector

pin No.

Synchronous feed encoder OSE1024-3-15-68

R054 cable

R050 cable

Connection when connecting via a spindle drive unit Control unit

ENC Spindle drive unit CN-8 (Connection of 1st channel)

(Connection of 2nd channel)

PC1 2 PC1* 12 PB1 3 PB1* 13 PA1 4 PA1* 14 GND 1 GND 11

PC2 7 PC2* 17 PB2 8 PB2* 18 PA2 9 PA2* 19 GND 5 GND 15

4 14 3

13 2

12 1

11

4 14 3

13 2

12 1

11

Recommended adaptive connector Connector: 10120-3000VE (Sumitomo 3M) Case: 10320-52F0-008 (Sumitomo 3M)

The wire material shall be a shielded stranded cable

equivalent to AWG22(0.3mm2) compliant with the UL1061-2464 standards. The shield shall be connected to the connector cases GND plate.

This cable is not available from Mitsubishi.

CAUTION

Incorrect connections could cause device damage, so always connect the cables to the designated connectors.

Do not connect or disconnect the connection cable between each unit while the power is ON.

4. CONTROL UNIT CONNECTIONS 4.5 Connecting the Sensor Signal (skip)

I - 24

4.5 Connecting the Sensor Signal (skip)

The SKIP connector is used to connect the sensor signal (skip). The sensor signal is used for high-speed signal processing, so take special care to prevent noise induction, etc., from occurring. If the cable is long, always use a shielded wire. Note that the input conditions, such as the input signal holding time, differ from the machine input/output signal's input conditions.

C6/C64 control unit

FG

SKIP

SKIP

Control unit

LED1

F340 cable

Input circuit

24VDC(+)

0V

FG

Stabilized power supply

1

5

6

9

SKIP connector

pin No.

S KIP

1

6

4

9

3

8

2

7

Control circuit

SKIP IN0

SKIP IN2

SKIP IN3

SKIP IN1

2.2k

2.2k

2.2k

2.2k

Input conditions

1 Input voltage when external contact is ON 18V or more 2 Input current when external contact is ON 9mA or more 3 Input voltage when external contact is OFF 4V or less 4 Input current when external contact is OFF 1mA or less 5 Input signal holding time (Ton) 2ms or more 6 Internal response time 0.08ms or less

7 Machine side contact capacity 30V or more, 16mA or more

+24V

GND

Ton

Ton 2ms

t

CAUTION

Do not apply a voltage other than that specified in this manual onto the connector. Failure to observe this could lead to rupture or damage.

Incorrect connections could cause device damage, so always connect the cables to the designated connectors.

Do not connect or disconnect the connection cable between each unit while the power is ON.

4. CONTROL UNIT CONNECTIONS 4.6 Connecting the Servo Drive Unit

I - 25

4.6 Connecting the Servo Drive Unit

The SERVO1 connector is used to connect the servo drive unit. Connect the R000 cable from SERVO1 connector on the control unit to CN1A connector on the servo drive unit. Depending on the specifications, the SERVO2 connector may be used. When using multiple servo drive units, or when connecting in parallel with the spindle drive unit, connect the R000 cable from CN1B connector to CN1A connector on the next drive unit. On the drive unit that is the final axis, connect the A-TM (terminator) to CN1B connector. When using the absolute position specifications, connect the battery unit with the R000 cable instead of the A-TM. Use CS000 connector set (optional, with both ends) when manufacturing the R000 cable. (Refer to the cable manufacturing drawings for details.) Refer to the "MDS-C1 Series Specifications Manual" for details on connecting with the servo drive unit.

or

Servo drive unit MDS-B/C1-V1/V2-

A-TM

Note) The R000 cable has the same specifications (connector, connection) as the SH21 cable.

SERVO

SKIP

D IO

EX T2

SERVO1

E XT

1

M A

IN TE

N AN

C E

LED1 LED2

ENC HANDLE

SIO TERMINAL

IC CARD

DC24V IN SERVO2

MITSUBISHI

MELDAS C64

R000 cable R000 cable

Control unit

CN1A

1

10

11

20

SERVO1 connector

pin No.

CN1A1

Battery unit MDS-A-BT-

CN1B

CAUTION

Incorrect connections could cause device damage, so always connect the cables to the designated connectors.

Do not connect or disconnect the connection cable between each unit while the power is ON.

4. CONTROL UNIT CONNECTIONS 4.7 Connecting the Manual Pulse Generator

I - 26

4.7 Connecting the Manual Pulse Generator

The HANDLE connector is used to connect the manual pulse generator. Up to three manual pulse generators can be connected. Use the CS000 connector set (optional, with both ends) when manufacturing the F320, F321 or F322 cable. (Refer to the cable manufacturing drawings for details.)

HANDLE

Manual pulse generator FCUA-HD60 rear drawing

When connecting one manual pulse generator

Manual pulse generator FCUA-HD60 rear drawing

NO.1

12V

4-M3

0V A B

F320 cable

When connecting two manual pulse generators

Manual pulse generator FCUA-HD60 rear drawing

NO.1

12V

4-M3

0V A B

NO.2

12V0V A B

F321 cable

When connecting three manual pulse generators

NO.1

12V

4-M3

0V A B

NO.2

12V0V A B

NO.3

12V 0V A B

F322 cable

1

10

11

20

HANDLE connector

pin No.

Control unit

SKIP

D IO

E X

T2

SERVO1

E X

T1

M A

IN TE

N A

N C

E

LED1 LED2

ENC HANDLE

SIO TERMINAL

IC CARD

DC24V IN SERVO2

MITSUBISHI

MELDAS C64

CAUTION

Incorrect connections could cause device damage, so always connect the cables to the designated connectors.

Do not connect or disconnect the connection cable between each unit while the power is ON.

4. CONTROL UNIT CONNECTIONS 4.8 Connecting the Machine Control Signal

I - 27

4.8 Connecting the Machine Control Signal

Machine input/output signal types and No. of points

Input Output Analog output Standard control unit 16 points (Note 1) 1 point (Note 2) Extension DIO card (option mounted) 32 points 32 points 1 point

(Note 1) Includes one EMG (emergency stop signal) input point. (Note 2) Uses as the SA (servo READY) output.

The DIO connector is used to connect the machine input/output signal. This connector is also used for the emergency stop signal input and SA (servo READY) output. Up to two extension DIO cards can be added by mounting with the option.

DO

Machine input/output signal

DIO F350 cable

DI

Control unit

SKIP

D IO

E X

T2

SERVO1

E X

T1

M A

IN TE

N A

N C

E

LED1 LED2

ENC HANDLE

SIO TERMINAL

IC CARD

DC24V IN SERVO2

MITSUBISHI

MELDAS C64

DIO connector

pin No.

A1

A10

B1

B10

F351 cable Machine input signal

Machine output signal (including analog output signal)

DI/DO connector

pin No.

B20

B1

A20

A1

CAUTION

Incorrect connections could cause device damage, so always connect the cables to the designated connectors.

Do not connect or disconnect the connection cable between each unit while the power is ON.

4. CONTROL UNIT CONNECTIONS 4.8 Connecting the Machine Control Signal

I - 28

A2 B2

Machine control panel

DIO

B1

A1

24VDC(+) COM

2.2k

SA

0V

PL

Input circuit sink type

Output circuit source type

Control circuit

Stabilized power supply

DCIN

24VDC(+) 0V FG

0V

1 2 3

RA

A2 B2

DIO

B1

A1

24VDC(+) 0V

COM

2.2k

SA

0V

PL

Input circuit source type

Output circuit source type

DCIN

24VDC(+) 0V FG

1 2 3

RA

Machine control panel

Stabilized power supply

Control circuit

(Note 1) Only the machine input signal can be changed between the sink type and source type.

24VDC(+)

24VDC(+)

0V Machine control panel

DI Extension DIO card HR881/HR882

COM A3 B3

B1 B2 A1 A2

B1 B2 A1 A2

Analog output B4 A4

2.2k Input circuit sick type

Output circuit sink type

DO

DAC R R

220

0V

RA

PL

24VDC(+)

24VDC(+)

0V

DI Extension DIO card HR883/HR884

COM A3 B3

B1 B2 A1 A2

B1 B2 A1 A2

Analog output B4 A4

2.2k Input circuit source type

Output circuit source type

DO

DAC R

R

220

0

RA

0

PL

Machine control panel

CAUTION

Incorrect connections could cause device damage, so always connect the cables to the designated connectors.

Do not connect or disconnect the connection cable between each unit while the power is ON.

4. CONTROL UNIT CONNECTIONS 4.8 Connecting the Machine Control Signal

I - 29

DIO

Note) The emergency stop signal is input into X7. The PLC interface assignments correspond to X400 to X40F.

DO

RA

DI DO

DI

Extension DIO unit (option mounting)

DIO

Machine side control panel, etc.

24VDC(+)

0V

24VDC(+)

DIO Crimp type connector : 7920-6500SC Strain relief : 3448-7920 Maker : Sumitomo 3M

DI/DO Crimp type connector : 7940-6500SC Strain relief : 3448-7940 Maker : Sumitomo 3M

Note) The PLC interface assignment corresponds as shown below. When EXT1 is mounted: X200 to X21F, Y200 to Y21F When EXT2 is mounted: X280 to X29F, Y280 to Y29F

24VDC(+)

0V

24VDC(+)

0V

PL

B X0 X1 X2 X3 X4 X5 X6 X7 COM SA

B

A X8 X9 XA XB XC XD XE XF COM 0V

A

10 9 8 7 6 5 4 3 2 1

A 0V 0V COM X1F X1E X1D X1C X1B X1A X19 X18 X17 X16 X15 X14 X13 X12 X11 X10

A

1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20

B +24V +24V COM X0F X0E X0D X0C X0B X0A X09 X08 X07 X06 X05 X04 X03 X02 X01 X00

B

A 0V 0V AG Y1F Y1E Y1D Y1C Y1B Y1A Y19 Y18 Y17 Y16 Y15 Y14 Y13 Y12 Y11 Y10

A

1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20

B +24V +24V AO Y0F Y0E Y0D Y0C Y0B Y0A Y09 Y08 Y07 Y06 Y05 Y04 Y03 Y02 Y01 Y00

B

DCIN

1 2 3

+24V 0V FG

Y

4. CONTROL UNIT CONNECTIONS 4.8 Connecting the Machine Control Signal

I - 30

The digital signal input circuit includes the sink type and source type. These can be selected by each connector unit.

Input circuit

Control circuit

2.2k

COM 24VDC(+)

DIO

0V

(Machine side)

Sink type

0V

2.2k

2.2k

2.2k

(Machine side)

0V

COM

DIO

24VDC(+)

24VDC(+)

Source type

Control circuit

Input conditions The input signal must be used within the following condition range.

Sink type Input voltage at external contact ON 6V or less Input current at external contact ON 9mA or more Input voltage at external contact OFF 20V or more Input current at external contact OFF 2mA or less Tolerable chattering time 2.2ms or less (Refer to T1 below) Input signal holding time 40ms or more (Refer to T2 below) Input circuit operation delay time 2.2ms T3T4 16ms Machine side contact capacity 30V or more, 16mA or more

Source type Input voltage at external contact ON 18V or more Input current at external contact ON 9mA or more Input voltage at external contact OFF 4V or less Input current at external contact OFF 2mA or less Tolerable chattering time 2.2ms or less (Refer to T1 below) Input signal holding time 40ms or more (Refer to T2 below) Input circuit operation delay time 2.2ms T3T4 16ms Machine side contact capacity 30V or more, 16mA or more

T1 T1 T1T1

T2T2

T4 T4 T3T3

4. CONTROL UNIT CONNECTIONS 4.8 Connecting the Machine Control Signal

I - 31

There are a sink type (HR881/882) and source type (HR883/884) digital signal output circuits. The SA (servo READY) output circuit is a source type. Use within the following specifications range.

Output circuit

R

Source type (HR883/884/SA)

RA

PL

0V

24VDC(+) DIO/DO

R

(Machine side)

Control circuit

24VDC(+)

Sink type (HR881/882)

RA

PL

DO (Machine side)

Control circuit

Output conditions

Insulation method Non-insulated Rated load voltage 24VDC Maximum output current 60mA Output delay time 40s

When using an inductive load such as a relay, always connect a diode (voltage resistance 100V or more, 100mA or more) in parallel to the load. Note that the device could be damaged if the diode's direction is incorrect. When using a capacity load such as a lamp, always connect a protective resistor (R = 150) serially to the load to suppress rush currents. (Make sure that the current is less than the above tolerable current including the instantaneous current.)

CAUTION

When using an inductive load such as relays, always connect a diode in parallel to the load as a noise countermeasure.

When using a capacitive load such as a lamp, always connect a protective resistor in series to the load to suppress rush currents.

4. CONTROL UNIT CONNECTIONS 4.9 Connecting the Remote I/O Unit

I - 32

4.9 Connecting the Remote I/O Unit

The RIO-M connector is used to connect the remote I/O unit. Connect the R211 cable from the RIO-M connector on the control unit to RIO1 on the remote I/O unit. When connecting multiple remote I/O units, connect the R211 cable from the RIO2 connector to the RIO1 connector on the next remote I/O unit. Connect the terminator (R-TM) to RIO2 connector on the final remote I/O unit. Use the accessories for the connectors and contacts when manufacturing the R211 cable. If the accessories are insufficient, prepare the CN221 one end connector set (optional, with one end). (Refer to the CABLE MANUFACTURING DRAWINGS for details.)

Back

Front

RIO-M

R211 cable

RIO-M Bottom

Back

RIO1/RIO 2

FCUA-DX

Connect the terminator (R-TM) to RI02 connector on the final remote I/O unit.

Front

R IO

-M R

IO -M

/S

R211 cable

RIO2

RIO1

RIO2

Recommended adaptive connector (Enclosed with FCUA-DX )

Terminator (R-TM)

Front

Back

Bottom

RIO1

RIO2

DCIN

Connector : 1-178288-3 2pcs. Contact : 1-175218-2(gold plate) 6 pcs.

(Tyco Electronics AMP)

R I O -M

R I O -M

/

Bottom

RIO-M RIO-M/S

1 TxRx 2 TxRx* 3 LG

Terminator

R-TM (Tyco Electronics AMP)

X X

R211 cable X

R211 cable X

R211 cable X

X

X RIO1

1 TxRx 2 TxRx* 3 LG

CAUTION

Incorrect connections could cause device damage, so always connect the cables to the designated connectors.

Do not connect or disconnect the connection cable between each unit while the power is ON.

Separate the signal wire from the drive line/power line when wiring.

4. CONTROL UNIT CONNECTIONS 4.9 Connecting the Remote I/O Unit

I - 33

When using the C64 and M600 Series, etc., as the master station and C6 as the slave station, use the RIO-M/S connector. Connect the R211 cable from the master station to the RIO-M/S connector on C6. When connecting multiple C6 units, use a relay cable or terminal block, etc., as a relay. Set the terminator ON/OFF slide switch SW2-2. Set the slave station number with the rotary switch CS2.

3

1

X

3 2 1

Connector : 1-178802-3 Contact : 175289-2 (Tyco Electronics AMP)

Master station remote I/O connector

C64

R211 cable

C6

C6

RIO-M

RIO-M/S

RIO-M/S

C6

RIO-M/S

Set SW2-2 to OFF (right side) except for the final station. Set to ON (left side) for the final station. The final station refers to the station with no subsequent slave stations.

R211 cable (Note 3) R211 cable (Note 3)

Relay cable

Connector : 1-178802-3 Contact : 175289-2 (Tyco Electronics AMP)

Connector : 1-178288-3 Contact : 1-175218-2 (Tyco Electronics AMP)

RIO-M

C64

R IO

-M

R IO

-M /S

R IO

-M R

IO -M

/S

R IO

-M R

IO -M

/S

R IO

-M R

IO -M

/S

3 2 1

R IO

-M

R IO

-M /S

0 0 C S

1

C S

2

1 2

O N

S W

2

(Note 1) The maximum number of C6 control units and remote I/O units that can be connected is within the range that the total

number of occupied stations (channels) is 8 or less. (Note 2) Set the C6 control unit slide switch SW2-2 to ON (left side) only for the final station. (Note 3) Connect the crimp terminal connected to the shield of the R211 cable to the frame ground of the control unit.

Note that to improve the noise withstand level, there may be cases when one end, both ends or neither end is connected. (Note 4) The RIO-M connector is dedicated for the master station, and RIO-M/S changes between the master and slave with

parameter settings. When using as a slave station, the parameter must be set for the slave.

CAUTION

Incorrect connections could cause device damage, so always connect the cables to the designated connectors.

Do not connect or disconnect the connection cable between each unit while the power is ON.

Separate the signal wire from the drive line/power line when wiring.

4. CONTROL UNIT CONNECTIONS 4.10 Connecting the RS-232C Device

I - 34

4.10 Connecting the RS-232C Device The SIO connector is used to connect the RS-232C device (serial I/O). The F310 and F311 relay cables are required to connect the RS-232C cable. (Refer to the CABLE MANUFACTURING DRAWINGS for details.)

SIO

LED1

Control unit

1

10 11

20

SIO connector

pin No.

F311 cable

F310 cable RS-232C relay

or RS-232C/RS-422

(For GPP)relay

RS-232C device

MELSEC perfipheral device connection connector (Note) When connecting GPP with RS-232C, use

a conversion cable, and connect to the TERMINAL connector.

Cabinet side wall

The specifications of the cross cable are shown below. Cross cable connection

For DC code control Panel relay

connector side RS-232C

device side 1 GND 2 TXD 3 RXD

1 GND 2 TXD 3 RXD 4 RTS 5 CTS 6 DSR

20 DTR 7 GND

1 GND 2 TXD 3 RXD 4 RTS 5 CTS 6 DSR

20 DTR 7 GND

1 GND 2 TXD 3 RXD 4 RTS 5 CTS 6 DSR

20 DTR 7 GND

6 DSR 20 DTR

7 GND

For RS/CS code control RS-232C

device side

Recommended adaptive connector Connector : HDBB-25PF(05)(Hirose Electric) Case : HDB-CTF(Hirose Electric)

Do not connect anything to the open pins. Keep the total cable length at 15m or less.

Cross cable

Cross cable Maximum cable length15m

R S

232C R

S 422

Panel relay connector side

CAUTION

Incorrect connections could cause device damage, so always connect the cables to the designated connectors.

Do not connect or disconnect the connection cable between each unit while the power is ON.

Separate the signal wire from the drive line/power line when wiring.

4. CONTROL UNIT CONNECTIONS 4.11 Connecting Other Peripheral Devices

I - 35

4.11 Connecting Other Peripheral Devices When connecting the MELSEC PLC peripheral devices using the RS-422 interface, connect to the GPP connector side of the F311 relay cable connected to the SIO connector. When connecting using the RS-232C interface, use the cables indicated below and connect to the connector terminal. In this case, the general-purpose RS-232C port can be used together.

RS-232C/RS-422 (for GPP) relay General-purpose RS-232C device

connection connector

Cabinet side wall TERMINAL

F311 cable

SIO

LED1

Control unit

R S

-232C

G P

P

Conversion cable (F313/F314)

RS-422 cable GOT

Personal computer (GX Developer)

RS-422/RS-232C conversion cable

Personal computer (GX Developer)

GOT RS-232C cable (F316)

RS-232C cable (F315)

Only one can be used

(1)

(2)

(3) (4)

(5)

Cable specifications are as described below.

(1) RS-422/RS-232C Conversion cable DAFXIH-CABV (Diatrend Corp.), SC-09 (MEAU)

(2) RS-422 cable

Cable for GOT (MELSEC) AC30R4-25P (3.0m), AC100R4-25P (10.0m), AC300R4-25P (30.0m)

(3) Conversion cable (F313/F314)

(a) F313 (For personal computer) NC side (TERMINAL)

(20pin half-pitch)

PC side

(25pin D-SUB)

Signal Pin No.

Cable connection & Signal direction

Pin No. Signal

TXD 6 2 TXD

RXD 16 3 RXD

DTR 18 20 DTR

GND 1

7 GND

[NC side connector (Recommended)] Connector10120-3000VE (Sumitomo 3M) Case10320-52F0-008 (Sumitomo 3M)

[PC side connector (Recommended)] ConnectorHDBB-25S (Hirose Electric) CaseHDB-CTF (Hirose Electric)

4. CONTROL UNIT CONNECTIONS 4.11 Connecting Other Peripheral Devices

I - 36

(b) F314 (For personal computer/communication terminal) NC side (TERMINAL)

(20pin half-pitch)

PC side

(25pin D-SUB)

Signal Pin No.

Cable connection & Signal direction

Pin No. Signal

TXD 6 2 TXD

RXD 16 3 RXD

DTR 18 20 DTR

GND 1 7 GND

Communication

terminal side

(25pin D-SUB)

TXD 2 2 TXD

TXD* 12 12 TXD*

RXD 4 4 RXD

RXD* 14 14 RXD*

ENCT* 8 8 ENCT*

GND 11 11 GND

GND 5 5 GND

GND 15

15 GND

[PC side connector (Recommended)] ConnectorHDBB-25S (Hirose Electric) CaseHDB-CTF (Hirose Electric)

[NC side connector (Recommended)] Connector10120-3000VE (Sumitomo 3M) Case10320-52F0-008 (Sumitomo 3M)

[Communication terminal side connector (Recommended)] Connector10120-3000VE (Sumitomo 3M) Case10320-52F0-008 (Sumitomo 3M)

(4) RS-232C cable (F315) NC side (TERMINAL)

(25pin D-SUB)

PC side

(9pin D-SUB)

Signal Pin No.

Cable connection & Signal direction

Pin No. Signal

GND 1 1 GND

2 RD

SD 2 3 SD

RD 3 4

ER(DTR) 20 5 GND

6 DR(DSR)

7

8 CS(CTS)

GND 7

9

[NC side connector (Recommended)] ConnectorHDBB-25S (Hirose Electric) CaseHDB-CTF (Hirose Electric)

[PC side connector (Recommended)] The recommended connector on the PC side is as indicated below. The connector on the partner side has to be matched with this connector.

9pinD-sub (Male) Inch screw fixing type (DDK) 17LE-23090-27(D3CC)

4. CONTROL UNIT CONNECTIONS 4.11 Connecting Other Peripheral Devices

I - 37

(5) RS-232C cable (F316) MELDAS C6/C64 side

(20pin half-pitch)

GOT side

(9pin D-SUB)

Signal Pin No.

Cable connection & Signal direction

Pin No. Signal

GND 1 1 CD

2 RD(RXD)

SD 6 3 SD(TXD)

RD 16 4 DTR(ER)

ER(DTR) 18 5 SG(GND)

6 DSR(DR)

7 RS(RTS)

8 CS(CTS)

GND 11

9

[GOT side connector (Recommended)] The recommended connector on the GOT side is as indicated below. The connector on the partner side has to be matched with this connector.

9pin D-sub (Male) Inch screw fixing type (DDK) 17LE-23090-27(D3CC)

[NC side connector (Recommended)] Connector10120-3000VE (Sumitomo 3M) Case10320-52F0-008 (Sumitomo 3M)

(Note 1) The conversion cable is not available from Mitsubishi. (Note 2) Do not connect anything to the open pins. (Note 3) Keep the total length of the cable to 15m or less. (Note 4) For details on GOT, refer to GOT-A900 Series Users Manual (GT Works2

Version1/GT Designer2 Version1 compatible Connection System Manual) and other relevant materials.

CAUTION

Incorrect connections could cause device damage, so always connect the cables to the designated connectors.

Do not connect or disconnect the connection cable between each unit while the power is ON.

Separate the signal wire from the drive line/power line when wiring.

4. CONTROL UNIT CONNECTIONS 4.12 Connecting the Display Unit with Ethernet

I - 38

4.12 Connecting the Display Unit with Ethernet

To connect the display unit with Ethernet, the Ethernet card (FCU6-EX875) must be mounted to the extension slot EXT2 on the control unit. Connect the Ethernet cable to the modular jack on the Ethernet card. As the Ethernet cable is easily affected by noise, separate the drive line and power line, and install the enclosed ferrite core on the control unit side. When using in an adverse environment, or when compliance to EMC Directives is required, use a shielded cable. Refer to the instruction manual for the display to be connected for details on other precautions.

LED1

(Note 1) Install the ferrite core with the following procedure. (1) Wind the cable once. (2) Securely insert the case until a click is heard. (3) Fix with constraining bands so that the position does not

deviate. (Note 2) When using a shielded cable, a separate FG cable is required for

connecting the shield to the FG. Normally, the cable is connected to the FG terminal on the control

unit. However, if the ground plate is closer, connect the cable directly.

(Note 3) To comply with the EMC Directives, a ferrite core may also need to be installed on the display side.

GOT or personal computer

Wind once

(Note 1)

Ferrite core Ferrite core (Note 3) Ethernet

Ethernet FG wire (Note 2)

FG cable assembly diagram

Protective tube or connector housing AMP: 171809-2 (black)

Recommended terminal type: AMP 250 Series 170232-2 (for AWG 20-14) 170234-2 (for AWG 12-10)

Select according to the terminal block being used.

Crimp terminal

Control unit

2

Applicable tab shape 0.80.025

0.9

5.0

6.2

9.6

CAUTION

Incorrect connections could cause device damage, so always connect the cables to the designated connectors.

Do not connect or disconnect the connection cable between each unit while the power is ON.

Separate the signal wire from the drive line/power line when wiring.

4. CONTROL UNIT CONNECTIONS 4.13 Connecting the Network with MELSECNET/10

I - 39

4.13 Connecting the Network with MELSECNET/10

The coaxial bus type and optical loop type networks can be used between the controllers in the MELSECNET/10 data link system. When using the coaxial bus type, the FCU6-EX878 MELSECNET/10 unit must be mounted in the control unit's extension slot, and when using the optical loop type, the FCU6-EX879 MELSECNET/10 unit must be mounted. This unit functions as the control station and normal station of the MELSECNET/10 data link system. Refer to the AJ71QLP21 (S1)/AJ71QBR11 type MELSECNET/10 Network Unit User's Manual (Hardware Section) for details on MELSECNET/10.

(1) Connecting the coaxial bus type MELSECNET/10

Connect a dedicated coaxial cable to the MELSECNET/10 unit (FCU6-EX878) connector. Use the enclosed F-shape connector, and always install the terminator A6RCON (optional) on the final unit.

Terminator

MELSEC NET/10

Control unit Control unit

MELSECNET/10 FG wire (Note 5)

F-shape connector

LED1 LED1

(Note 1) Use a high-frequency coaxial cable 3C-2V or

5C-2V (compliant with JIS-C-3501). The BNC-P- -Ni-CAU (DDK) is recommended. (Note 2) Lay the coaxial cable at least 100mm away from

the other drive lines and control cables. When using in an adverse environment, or when

compliance to EMC Directives is required, use a double shielded coaxial cable (Mitsubishi Wire 5C-2V-CCY, etc.). Connect the outer shield to the FG using the shield clamp fitting.

(Note 3) Use the following length of coaxial cable according to the total number of stations.

Total number of stations Distance between stations 1 to 9 stations 1 to 500m

10 to 32 stations

1 to 5m 13 to 17m

25 to 500m (Note 4) The BNC-TMP-05 (75) (Hirose Electric) terminator

can be used instead of the A6RCON-R75 (optional). (Note 5) Connect the FG wire from the FG terminal on the

front of the MELSECNET/10 unit (FCU6-EX878) to the FG terminal on the bottom of the control unit.

FG cable assembly diagram Protective tube or connector housing AMP: 171809-2 (black)

Recommended terminal type: AMP 250 Series 170232-2 (for AWG 20-14) 170234-2 (for AWG 12-10)

Select according to the terminal block being used.

Crimp terminal 2

Applicable tab shape 0.80.025

0.9

5.0

6.2

9.6

CAUTION

Incorrect connections could cause device damage, so always connect the cables to the designated connectors.

Do not connect or disconnect the connection cable between each unit while the power is ON.

Separate the signal wire from the drive line/power line when wiring.

4. CONTROL UNIT CONNECTIONS 4.13 Connecting the Network with MELSECNET/10

I - 40

(2) Connecting the optical loop type MELSECNET/10 Connect a dedicated optical fiber cable to the optical connector on the MELSECNET/10 unit (FCU6-EX879).

(Note 1) An indoor standard cable AS-2P-5M-A, etc., is

recommended for the optical fiber cable. Consult with Mitsubishi Electric System Service.

(Note 2) The optical loop system's optical module follows SI specifications. The total distance within one network is 30km, and the distance between stations is 500m.

(Note 3) The optical loop system is a double loop transmission path method. The following system is used to connect the optical fiber cables.

MELSEC NET/10

OUT T(F-SD) Main loop transmission (F) SD (OUT T(F-SD))

OUT R(R-RD) Sub-loop transmission (R) RD (OUT R(R-RD))

IN T(R-SD) Sub-loop transmission (R) SD (IN T(R-SD))

IN R(F-RD) Main loop transmission (F) RD (IN R(F-RD))

Control unit

LED1

Control unit

LED1

IN : Connect to OUT on previous station OUT : Connect to IN on next station

(Connection example) Station No.1

OUT IN OUT IN INOUT

Station No.2 Station No.3

CAUTION

Incorrect connections could cause device damage, so always connect the cables to the designated connectors.

Do not connect or disconnect the connection cable between each unit while the power is ON.

Separate the signal wire from the drive line/power line when wiring.

4. CONTROL UNIT CONNECTIONS 4.14 Connecting the IO Device with CC-Link

I - 41

4.14 Connecting the IO Device with CC-Link

The CC-Link unit (FCU6-HR865) must be mounted in the control unit's extension slot to connect IO devices using CC-Link. Connect a dedicated CC-Link cable to the CC-Link unit (FCU6-HR865) terminal block. Always install the enclosed terminator on the final station. This unit functions as the CC-Link system's master and local station. Refer to the MELSEC A1SJ61QBT11 type CC-Link System Master/Local Unit's User Manual, etc., for details on the CC-Link system.

CC-Link

Remote I/O station Terminal block

Terminator (Note 2)

(Note 4)

(Note 1) The performance of the CC-Link system cannot be guaranteed when a cable other than the CC-Link dedicated cable is used. For details on the CC-Link dedicated cable, refer to the CC-Link Partner Association's web site (http://www.cc-link.org/). (Information is provided in the section "Introduction to Partner Makers".)

(Note 2) Use the enclosed terminator. The terminator value differs according to the cable being used. The CC-Link dedicated cable uses 110, and the CC-Link dedicated high-performance cable uses 130.

(Note 3) Connect the FG wire from the FG terminal on the C64 control unit's CC-Link terminal block to the FG terminal on the bottom of the control unit.

(Note 4) Pull out the CC-Link unit from the control unit and set the C64 control unit's station No. setting rotary switch and baud rate setting rotary switch.

Control unit

C64 control unit CC-Link terminal block

CC-Link FG wire (Note 3)

Shielded twisted pair cable (3-core type) (Note 1)

Shielded twisted pair cable (3-core type) (Note 1)

5 FG 4 SLD 3 DG 2 DB 1 DA

Terminator (Note 2)

Remote I/O station Remote I/O stationLED1

DA

FG

SLD

DG

DB

DA

FG

SLD

DG

DB

Remote I/O station Terminal block

CAUTION

Incorrect connections could cause device damage, so always connect the cables to the designated connectors.

Do not connect or disconnect the connection cable between each unit while the power is ON.

Separate the signal wire from the drive line/power line when wiring.

4. CONTROL UNIT CONNECTIONS 4.14 Connecting the IO Device with CC-Link

I - 42

Wiring the CC-Link terminal block (1) Peel the cable's sheath, and separate the inner wire from the shield mesh. (2) Peel the shield mesh and the inner wire's sheath, and twist the core wires.

Approx. 10mm

Shield mesh

3-core twisted pair cable

(3) Twist together one of the wires in the cables or the shield meshes of the cable to be connected

to the previous station or next station. (4) For the final station, treat the enclosed terminator as shown below, and then install.

Cut

Terminator

Shorten sheath

Bend lead wire Cut

(5) Insert the wire's core wire into an opening on the terminal block, and tighten with a flat-tip

screwdriver so that the wire does not dislocate. Make sure that the terminal screw is sufficiently loosened before inserting the wire into the

opening.

To previous station To next station

Flat-tip screwdriver (for fixing terminal block)

(Note) Solder plating of the core wires must be avoided as a contact fault could result.

Flat-tip screwdriver (for fixing wire)

(6) After wiring to the terminal block, fit the terminal block into the CC-Link connector and fix it

with a flat-tip screwdriver.

4. CONTROL UNIT CONNECTIONS 4.15 Connecting the IO Device with DeviceNet

I - 43

4.15 Connecting the IO Device with DeviceNet

The DeviceNet unit (FCU6-EX871-40) must be mounted in the control unit's extension slot to connect IO devices with DeviceNet. Connect the dedicated DeviceNet cable to the DeviceNet unit's terminal block (enclosed). When setting the parameters in the DeviceNet unit using the configuration software (parameter setting tool), connect an RS-232C cross cable between the DeviceNet unit and personal computer (PC/AT compatible unit). The configuration software must be installed in the personal computer at this time. This unit functions as the DeviceNet master station. Refer to the DeviceNet Specifications (Release 2.0) issued by ODVA (Open DeviceNet Vendor Association) for details on the DeviceNet system.

Tap

DeviceNet

DeviceNet cable

RS-232C connector for configuration

DeviceNet connector

(Note 1) Connect the FG wire between the shield terminal on the DeviceNet terminal block (enclosed) and FG terminal on the bottom of the control unit.

(Note 2) Labels corresponding to the DeviceNet cable colors are attached to the DeviceNet unit plate. Match the cable color with the label color when connecting the cables to the DeviceNet terminal block (enclosed).

Control unit

LED1

DeviceNet FG wire (Note 1)

DeviceNet terminal block (Note 2)

5 (red) V+ 4 (white) CAN_H 3 Shield 2 (blue) CAN_L 1 (black) V-

P la

te Label

RS-232C cross cable

PC/AT compatible unit + configuration software

There are open pins on the DeviceNet unit side, but connections should be made to all pins to eliminate the cable orientation.

PC/AT compatible unit D-sub female connector (9 pin)

DeviceNet unit D-sub female connector (9 pin)

2 RXD 3 TXD 4 DTR 6 DSR 5 GND 1 DCD 7 RTS 8 CTS 9 RI

RS-232C cross cable connection

RXD TXD DTR GND RTS CTS

2 3 4 6 5 1 7 8 9

CAUTION

Incorrect connections could cause device damage, so always connect the cables to the designated connectors.

Do not connect or disconnect the connection cable between each unit while the power is ON.

Separate the signal wire from the drive line/power line when wiring.

4. CONTROL UNIT CONNECTIONS 4.15 Connecting the IO Device with DeviceNet

I - 44

Wiring the DeviceNet terminal block (1) Peel the cable's sheath, and separate the inner wire from the shield mesh. (2) Peel the shield mesh and the inner wire's sheath, and twist the core wires.

Approx. 10mm

Shield mesh

DeviceNet cable

(3) Insert the wire's core wire into an opening on the terminal block, and tighten with a flat-tip screwdriver so that the wire does not dislocate.

Make sure that the terminal screw is sufficiently loosened before inserting the wire into the opening.

DeviceNet cable

Flat-tip screwdriver (for fixing terminal block)

(Note) Solder plating of the core wires must be avoided as a contact fault could result.

Flat-tip screwdriver (for fixing wire)

(4) After wiring to the terminal block, fit the terminal block into the DeviceNet connector and fix it

with a flat-tip screwdriver.

Contact ODVA for details on the following devices required to structure the DeviceNet network. Network power supply unit Power supply tap Tap Terminator Cable

The ODVA contacts are listed below. Open DeviceNet Vendor Association, Inc. PMB 499 20423 State Road 7 #F6 Boca Raton, FL 33498-6797 USA TEL: +1-954-340-5412 FAX: +1-954-340-5413

Contact the following company for details on the configuration software. Hilscher Gesellschaft fr Systemautomation mbH Rheinstrasse 78 D-65795 Hattersheim Germany TEL: +49-6190-9907-0 FAX: +49-6190-9907-50

CAUTION

Incorrect connections could cause device damage, so always connect the cables to the designated connectors.

Do not connect or disconnect the connection cable between each unit while the power is ON.

Separate the signal wire from the drive line/power line when wiring.

4. CONTROL UNIT CONNECTIONS 4.16 Control Unit Connector Pin Assignments

I - 45

4.16 Control Unit Connector Pin Assignments Servo drive unit

SERVO1 110

1120

Plug : 10120-6000EL Shell : 10320-3210-000 Recommended maker : Sumitomo 3M

1 2 3 4 5 6 7 8 9

10

11 12 13 14 15 16 17 18 19 20

O I I

O

GND SVTXD1 SVALM1 SVRXD1 GND SVEMG1

O I I

O

GND SVTXD1* SVALM1* SVRXD1* GND SVEMG1*

Servo drive unit

SERVO2 110

1120

Plug : 10120-6000EL Shel : 10320-3210-000 Recommended maker : Sumitomo 3M

1 2 3 4 5 6 7 8 9

10

11 12 13 14 15 16 17 18 19 20

O I I

O

GND SVTXD2 SVALM2 SVRXD2 GND SVEMG2

O I I

O

GND SVTXD2* SVALM2* SVRXD2* GND SVEMG2*

Manual pulse generator

HANDLE 110

1120

Plug : 10120-3000VE Shell : 10320-52F0-008 Recommended maker : Sumitomo 3M

1 2 3 4 5 6 7 8 9

10

11 12 13 14 15 16 17 18 19 20

I I

O I

GND 2HA 1HA GND +12V 3HA

I I

O I

GND 2HB 1HB GND +12V 3HB

Synchronous feed encoder

ENC 110

1120

Plug : 10120-3000VE Shell : 10320-52F0-008 Recommended maker : Sumitomo 3M

1 2 3 4 5 6 7 8 9

10

11 12 13 14 15 16 17 18 19 20

I I I

I I I O

GND PC1 PB1 PA1 GND PC2 PB2 PA2 +5V

I I I I I I O

GND PC1* PB1* PA1* GND PC2* PB2* PA2* +5V

4. CONTROL UNIT CONNECTIONS 4.16 Control Unit Connector Pin Assignments

I - 46

Serial

SIO 110

1120

Plug : 10120-6000EL Shell : 10320-3210-000 Recommended maker : Sumitomo 3M

1 2 3 4 5 6 7 8 9

10

11 12 13 14 15 16 17 18 19 20

I I I

O O I I O

GND RXD1 CTS DSR1 GND DTR2 TXD2 RXD2 DCD2 +5V

O O O

O O I I O

GND TXD1 RTS1 DTR1 GND DTR2* TXD2* RXD2* DCD2* +5V

Communication

terminal

TERMINAL

110

1120

Plug : 10120-6000EL Shell : 10320-3210-000 Recommended maker : Sumitomo 3M

1 2 3 4 5 6 7 8 9

10

11 12 13 14 15 16 17 18 19 20

O

I

O

I

GND TXD RXD GND (TXD2) ENCT*

O I I

O

GND TXD* RXD* GND (RXD2) (DTR2)

1 2 3 4 5

I I I I

SKIP 0 SKIP 1 SKIP 2 SKIP 3

Skip

SKIP 1 5

6 9

Connector : CDE-9PF Contact : CD-PC-111 Case : HDE-CTH Recommended maker : Hirose Electric

6 7 8 9

I I I I

SKIP 0* SKIP 1* SKIP 2* SKIP 3*

Machine

input/output

DIO

1A10A

1B10B

Connector : 7920-6500SC Strain relief : 3448-7920 Recommended maker : Sumitomo 3M Note) This differs depending on whether sink or source is used.

Supply the following voltage to the COM. Sink : 24VDC Source : GND

10 9 8 7 6 5 4 3 2 1

10 9 8 7 6 5 4 3 2 1

I I I I I I I I I O

B X0 X1 X2 X3 X4 X5 X6 X7(EMG) COM SA

I I I I I I I I I

A X8 X9 XA XB XC XD XE XF COM 0V

4. CONTROL UNIT CONNECTIONS 4.16 Control Unit Connector Pin Assignments

I - 47

1 2 3

I/O I/O

TXRX1 TXRX1* GND

Remote I/O

RIO-M

3 1 Connector : 1-178288-3 Contact : 1-175218-2 Recommended maker : Tyco Electronics AMP

2

1 2 3

I/O I/O

TXRX2 TXRX2* GND

Remote I/O

RIO-M/S

3 1 Connector : 1-178288-3 Contact : 1-175218-2 Recommended maker : Tyco Electronics AMP

2

1 2

I

GND +3.6V

Battery

BAT 2 1

The connector and contact depend on the battery.

1 2 3

I

+24V GND FG

+24V input

DC24VIN

3 1 Connector : 1-178288-3 Contact : 1-175218-5 Recommended maker : Tyco Electronics AMP

2

CAUTION

Do not apply a voltage other than that specified in this manual onto the connector. Failure to observe this could lead to rupture or damage.

Incorrect connections could cause device damage, so always connect the cables to the designated connectors.

5. CONNECTION OF COMMUNICATION TERMINAL 5.1 Outline of Communication Terminal

I - 48

5. CONNECTION OF COMMUNICATION TERMINAL

The communication terminal is described in this chapter. 5.1 Outline of Communication Terminal

The communication terminal is configured of the display and keyboard. The following types are available according to the display type, etc. 7.2-type monochrome LCD/integrated keyboard

7.2-type LCD

FCUA-LD100

7.2-type monochrome LCD/Keyboard separated type

7.2-type LCD

FCUA-LD10 FCUA-KB20/KB30

10.4-type monochrome LCD/Keyboard separated type

10.4-type LCD

FCU6-DUT32 FCUA-KB021/KB031

9-type CRT/Keyboard integrated type

9-type CRT

FCUA-CT100/CT120

9-type CRT/Keyboard separated type

9-type CRT

FCUA-CR10 FCUA-KB10

5. CONNECTION OF COMMUNICATION TERMINAL 5.2 Connection of Power Supply

I - 49

5.2 Connection of Power Supply

The 24VDC must be supplied to the communication terminal. Prepare a stabilized power supply that satisfies the following conditions. The 9-type CRT type requires 100VAC for the CRT power supply.

Type FCUA-LD100/ LD10 FCU6-DUT32 FCUA-CT100/

CT120/KB10

Power voltage 24VDC5% Ripple 5% (p-p)

Instantaneous power failure tolerable time Follows specifications of 24VDC power supply being used

Current consumption 24VDC, 0.9A 24VDC, 0.9A 24VDC, 0.6A 5.2.1 Connection of Power Supply to 7.2-type Monochrome LCD

(FCUA-LD100/FCUA-LD10+KB20)

Supply 24VDC to the CR01 connector on the rear of the LCD.

LCD

J1

J2

CR03

CR02

CR05 CR06

CNZ24

CR01

[FCUA-LD100/LD10+KB20 rear side]

FG 3 0V 2

24VDC(+) 1

R220 cable 24VDC(+) 0V FG

Stabilized power supply

FG

Y

CAUTION

Separate the signal wire from the drive line/power line when wiring.

Do not apply voltages other than those indicated in this manual on the connector. Doing so may lead to destruction or damage.

Incorrect connections may damage the devices, so connect the cables to the specified connectors.

Recommended adaptive connector (Enclosed with FCUA-LD100/FCUA-LD10+KB20) Connector : 2-178288-3 Contact : 1-175218-5 (tin plated) (Tyco Electronics AMP)

5. CONNECTION OF COMMUNICATION TERMINAL 5.2 Connection of Power Supply

I - 50

5.2.2 Connection of Power Supply to 10.4-type Monochrome LCD (FCU6-DUT32+KB021)

Supply 24VDC to the CR01 connector on the rear of the LCD.

FG 3 0V 2

24VDC(+) 1

R220 cable 24VDC(+) 0V FG

Stabilized power supply (Prepare separately)

FG

[FCU6-DUT32+KB021 rear view]

J1

J2 CR03

CR01

CN24

CR02 CR06 CR05

OPERATION BOARD Ver.A FCU6-DUT32

MITSUBISHI ELECTRIC CORP.

Y

CAUTION

Separate the signal wire from the drive line/power line when wiring.

Do not apply voltages other than those indicated in this manual on the connector. Doing so may lead to destruction or damage.

Incorrect connections may damage the devices, so connect the cables to the specified connectors.

Recommended adaptive connector (Enclosed with FCU6-DUT32) Connector : 2-178288-3 Contact : 1-175218-5 (tin plated) (Tyco Electronics AMP)

5. CONNECTION OF COMMUNICATION TERMINAL 5.2 Connection of Power Supply

I - 51

5.2.3 Connection of Power Supply to 9-type CRT (FCUA-CT100/FCUA-CR10+KB10)

Supply 100VAC to the connector CRT2 on the rear of the CRT, and 24VDC to the connector CR01 on the rear of the keyboard.

Recommended adaptive connector

(Enclosed with FCUA-CT100/FCUA-CR10+KB10) Connector : 2-178288-3 Contact : 1-175218-5 (tin plated) (Tyco Electronics AMP)

1 24VDC(+) 2 0V 3 FG

Y

R220 cable 24VDC(+)

0V

FG

Stabilized power supply (Prepare separately)

FG

Use a two-circuit ON/OFF switch and always establish a double-off system.

Terminal block (M4) 100VAC115VAC

100VAC

3 2 1

Recommended adaptive connector (Connected to R100 cable)

Connector : 3191-03R1 Contact : 1381TL(Morex)

R100 cable (Enclosed with FCUA-CT100/CT120/CR10+KB10)

[FCUA-CT100/CT120/CR10+KB10 rear view]

CRT

CRT2

CRV

CRT1

Cable clamp

CR04-1 cable

CR03 CR01

CR06

CR05 CR02

CR04

CAUTION

Separate the signal wire from the drive line/power line when wiring.

Do not apply voltages other than those indicated in this manual on the connector. Doing so may lead to destruction or damage.

Incorrect connections may damage the devices, so connect the cables to the specified connectors.

5. CONNECTION OF COMMUNICATION TERMINAL 5.3 Internal Connections

I - 52

5.3 Internal Connections

7.2-inch LCD

Menu keys J2

Data keys

J2

J1

CNZ24 PCB

CR03

CNZ22A

CR01 R220 cable

R000 cable

24VDC(+)

To control unit CR02

Remote I/O unit

R211 cable

CR03 cable

NZ24-2 cable

: Enclosed cable : Enclosed connector

CR05 CR06

(2) Internal connection of 10.4-type monochrome LCD (FCU6-DUT32+KB021)

J2 Menu keys

Data keys

J2

J1

PCB

R220 cable

R000 cable

24VDC(+)

To control unit

Remote I/O unit

R211 cable

NZ24 cable 10.4-inch

monochrome LCD

CR01

CNZ24

CR03

CNZ22

: Enclosed cable : Enclosed connector

CR06 CR05 CR02

CR03 cable

Enclosed cable

Enclosed cable

(3) Internal connection of 9-type CRT (FCUA-CT100/FCUA-CR10+KB10)

CRT2 9-inch CRT

CRT1

Menu keys J2

Data keys

J2

J1

CR04

PCB

CRV

CR03R220 cable

R000 cable

24VAC(+)

To control unit

CR02

Remote I/O unit

R211 cable

CR03 cable

CR04-1 cable

: Enclosed cable : Enclosed connector

CR06

CR05

R100 cable(2m)

CR01

100VAC

(1) Internal connection of 7.2-type monochrome LCD (FCUA-LD100/FCUA-LD10+KB20)

5. CONNECTION OF COMMUNICATION TERMINAL 5.4 Connection of Remote I/O Unit

I - 53

5.4 Connection of Remote I/O Unit A maximum of two remote I/O units can be connected to the communication terminal. Manufacture the R211 cable (refer to cable manufacturing drawings for details) and connect it to the connector CR5 on the rear of the communication terminal as shown below. Use the enclosed connectors and contacts. If the accessories are insufficient, use the CN211 connector set (optional, with one end). The remote I/O unit serial link station No. setting method, etc., are the same as for when connecting to the control unit. However, the machine control input/output signal assignment addresses will differ. (Refer to "PLC Interface Manual" for details.)

FCUA-DX1

Connector : 1-178288-3 1 piece Contact : 1-175218-2 (gold plated) 3 pieces (Tyco Electronics AMP)

Terminator (sold separately) (R-TM)

CR05

Recommended adaptive connector (Enclosed with communication terminal)

Recommended adaptive connector (Enclosed with FCUA-DX1 )

R211 cable

24VDC input

Communication terminal rear view

(Front)

(Rear)

Bottom view

CR05 3 LG 2 TxRx* 1 TxRx

X

The remote I/O unit requires a separate 24VDC(+) power supply. Refer to section "6.4 Connection of remote I/O power supply".

RIO1

3 LG 2 TxRx* 1 TxRx

X

RIO2

3 LG 2 TxRx* 1 TxRx

X

If there is a second remote I/O unit, connect the R211 cable from RIO2 connector to the second remote I/O unit's RIO1 connector. A terminator (R-TM) must be installed on the final station's remote I/O units RIO2.

CAUTION

Incorrect connections could damage the device, so always connect the cable to the designated connector.

Do not connect or disconnect the connection cables between each unit while the power is ON.

5. CONNECTION OF COMMUNICATION TERMINAL 5.5 Example of Connecting Multiple Control Units to the Communication Terminal

I - 54

5.5 Example of Connecting Multiple Control Units to the Communication Terminal

R000 cable

Communication terminal DUT32+KB20/DUN33+KB20 /LD100/LD10+KB20 /CT100/CR10+KB10

LED1

Control unit C6/C64

SW2-1 (ON)

TERMINAL R000

LED1

Control unit C6/C64

SW2-1 (OFF)

TERMINAL R000

LED1

Control unit C6/C64

SW2-1 (OFF)

TERMINAL R000

CR02

HR591

R000 R000

HR591 HR591

Terminator M-TM

O N

1 2

SW2SW1

CS1 CS2 0 0

C S1

C S2

SW 1 ON

OFF

2 1 LDCON

LED1 LED2 BAT

Set SW2-1 to OFF except for the final station. Set to ON for the final station. The final station refers to the station with no subsequent slave stations.

When connecting multiple control units, the station No. of each control unit must be set. To set the station No., set SW1 to ON, set the rotary switch CS1 to "D", set the station No. in CS2, and turn the power ON. After setting, return each switch to their original settings. The same station No. cannot be set in duplicate for multiple control units.

(Note 1) Up to 16 control units can be connected. (Note 2) The R000 cable has the same specifications (both connector and specifications) as the SH21 cable. (Note 3) Install the terminator M-TM to the HR591 card for the control unit having the longest cable length from the

communication terminal (LD100, etc.). (Note 4) Set the control unit's slide switch SW2-1 to ON only for the final station. (Note 5) The total length of the cable connected to each unit must be 30m or less. The cable connected between the control unit and HR591 card must be 1m or less. (Note 6) An R001 cable (distribution cable) can be used instead of the HR591 card.

CAUTION

Incorrect connections could damage the device, so always connect the cable to the designated connector.

Do not connect or disconnect the connection cables between each unit while the power is ON.

6. CONNECTION OF REMOTE I/O UNIT 6.1 Outline of Remote I/O Unit

I - 55

6. CONNECTION OF REMOTE I/O UNIT

This chapter describes the connection between remote I/O unit and machine control signals. 6.1 Outline of Remote I/O Unit

The following ten types of remote I/O units (FCUA-DX ) are available, depending on the type of input/output signal and No.of contacts. Use serial link connections (MC link B) to connect the unit with the control unit or the communication terminal. When the remote I/O unit is connected with serial links, multiple units can be used as long as the total No. of occupied stations (channels) is within 8 stations. (Refer to Section 6.3 "Setting the Station No. When Using Multiple Remote I/O Units" for details.)

Unit name Machine control signals that can be handled No. of occupied serial link stations

FCUA-DX100 Digital input signal (DI) : 32 points (insulation) sink/source type Digital output signal (DO) : 32 points (non-insulation) sink type 1

FCUA-DX101 Digital input signal (DI) : 32 points (insulation) sink/source type Digital output signal (DO) : 32 points (non-insulation) source type 1

FCUA-DX110 Digital input signal (DI) : 64 points (insulation) sink/source type Digital output signal (DO) : 48 points (non-insulation) sink type 2

FCUA-DX111 Digital input signal (DI) : 64 points (insulation) sink/source type Digital output signal (DO) : 48 points (non-insulation) source type 2

FCUA-DX120 Digital input signal (DI) : 64 points (insulation) sink/source type Digital output signal (DO) : 48 points (non-insulation) sink type Analog output (AO) : 1 point

2

FCUA-DX121 Digital input signal (DI) : 64 points (insulation) sink/source type Digital output signal (DO) : 48 points (non-insulation) source type Analog output (AO) : 1 point

2

FCUA-DX130 Digital input signal (DI) : 32 points (insulation) sink/source type Digital output signal (DO) : 32 points (non-insulation) sink type Handle input : 2 points

2

FCUA-DX131 Digital input signal (DI) : 32 points (insulation) sink/source type Digital output signal (DO) : 32 points (non-insulation) source type Handle input : 2 points

2

FCUA-DX140

Digital input signal (DI) : 32 points (insulation) sink/source type Digital output signal (DO) : 32 points (non-insulation) sink type Analog input (AI) : 4 points Analog output (AO) : 1 point

2

FCUA-DX141

Digital input signal (DI) : 32 points (insulation) sink/source type Digital output signal (DO) : 32 points (non-insulation) source type Analog input (AI) : 4 points Analog output (AO) : 1 point

2

6. CONNECTION OF REMOTE I/O UNIT 6.2 Names of Each Remote I/O Unit Section

I - 56

6.2 Names of Each Remote I/O Unit Section

DS

FCUA-DX10

Front view

FCUA-DX11 /FCUA-DX12 FCUA-DX13 FCUA-DX14

5

6

7

(Front)

Bottom view

5

6

7

5

6

7

5

6

7

11

3

1

2

3

4

1

2

3

4

8

3

9

1

2

3

4

10

3

1

2

3

4

1 DI-L (machine input signal connector)

2 DS (baud rate changeover switch)

3 CS (station No. changeover switch)

4 DO-L (machine output signal connector)

5 RIO1 (serial connection connector #1)

6 RIO2 (serial connection connector #2)

7 DCIN (24VDC(+) power input connector)

8 DI-R (machine input signal connector)

9 DO-R (machine output signal connector)

10 HANDLE (manual pulse generator signal input connector)

11 AIO (analog signal input/output connector)

CS

For changeover of baud rate. Normally set to left side. Not used

Selection of station No.

Enlarged drawing of DS and CS

1

4 2 5

6 7

AD

9

B

F

E

0

C

8

3

Front view Front view Front view

(Front) (Front) (Front)

Bottom view

Bottom view

Bottom view

(Back) (Back) (Back) (Back)

6. CONNECTION OF REMOTE I/O UNIT 6.3 Setting the Station No. When Using Multiple Remote I/O Units

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6.3 Setting the Station No. When Using Multiple Remote I/O Units

When the remote I/O unit is connected with serial links (MC link B), multiple units can be used as long as the total No. of occupied stations is within 8 stations.

Unit name No. of occupied serial link stations FCUA-DX10 1 FCUA-DX11 2 FCUA-DX12 2 FCUA-DX13 2 FCUA-DX14 2

When using multiple remote I/O units, a characteristic station No. must be set for each unit. The FCUA-DX10 unit has one station No. setting switch, and FCUA-DX11 , DX12 , DX13 and DX14

units have two switches. Each of these switches must be set to a characteristic station No.

FCUA-DX10

0 1

No. of occupied stations: 1

FCUA-DX11 or FCUA-DX12 4 units

Maximum configuration

2

FCUA-DX11 or FCUA-DX12

0 1 2 3 4 5 6 7

No. of occupied stations: 2 Total No. of occupied stations: 3

No. of occupied stations: 2

No. of occupied stations: 2

No. of occupied stations: 2

No. of occupied stations: 2

Total No. of occupied stations: 8

The assignment of each unit's input/output signal address will change with the setting of the station No. Refer to "PLC Interface Manual" for details.

6. CONNECTION OF REMOTE I/O UNIT 6.4 Connection of Remote I/O Power Supply

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6.4 Connection of Remote I/O Power Supply

24VDC(+) is required to run the remote I/O unit. Prepare a stabilized power supply that satisfies the following conditions.

Output voltage 24VDC5%

Ripple 5% (P-P) FCUA-DX10 2.4A or more FCUA-DX11 3.8A or more FCUA-DX12 3.8A or more FCUA-DX13 3.4A or more

Max. output current

FCUA-DX14 3.4A or more

The 24VDC(+) power for the control circuit is supplied from the DCIN connector on the bottom of the unit or from DI-L, DI-R, DO-L or DO-R connectors on the front. When supplying from the front connector, supply to all corresponding pins. When manufacturing the R300 cable, use the CN300 one end connector (optional, with one end), and when manufacturing the R301 cable, use the CS301 connector set (optional, with both ends).

Remote I/O unit

DI-L DI-R

Machine control panel, electric cabinet, etc.

R300 cable or

R301 cable

Supply to either method

DI-L

Front

(Front)

(Back)

Bottom

DO-L DO-R

DI-R

DO-L DO-R

24VDC(+)

0V

DCIN

24VDC(+) 0V FG

1 2 3

B1 B2

A1 A2

B1 B2

A1 A2 PL

RA

24VDC(+)

FG

0V

R220 cable

Stabilized power supply (Prepare separately)

FG

Y Y

B1 B2

A1 A2

B1 B2

A1

A2

CAUTION

Do not apply voltages other than those indicated in this manual on the connector. Doing so may lead to destruction or damage.

Incorrect connections could damage the device, so always connect the cable to the designated connector.

6. CONNECTION OF REMOTE I/O UNIT 6.5 Outline of Digital Signal Input Circuit

I - 59

6.5 Outline of Digital Signal Input Circuit

The digital signal input circuit can be selected from sink type or source type in card units.

Input circuit

COM

(Machine side)

A3,B3

Sink type

DI-L/DI-R

0V

0V

0V

0V

0V

24VDC(+)

2.2k

2.2k

2.2k

2.2k

2.2k

Control circuit

COM

(Machine side)

A3,B3

Source type

DI-L/DI-R

0V

24VDC(+) 2.2k

2.2k

2.2k

2.2k

2.2k

24VDC(+)

24VDC(+)

24VDC(+)

24VDC(+)

Control circuit

6. CONNECTION OF REMOTE I/O UNIT 6.5 Outline of Digital Signal Input Circuit

I - 60

Input conditions

The input signals must be used within the following condition ranges.

Sink type

Input voltage at external contact ON 6V or less Input current at external contact ON 9mA or more Input voltage at external contact OFF 20V or more, 25.2V or less Input current at external contact OFF 2mA or less Tolerable chattering time 3ms or less (Refer to T1 below) Input signal holding time 40ms or more (Refer to T2 below) Input circuit operation delay time 3ms T3 =. . T4 16ms

Machine side contact capacity 30V or more, 16mA or more

Source type Input voltage at external contact ON 18V or more, 25.2V or less Input current at external contact ON 9mA or more Input voltage at external contact OFF 4V or less Input current at external contact OFF 2mA or less Tolerable chattering time 3ms or less (Refer to T1 below) Input signal holding time 40ms or more (Refer to T2 below) Input circuit operation delay time 3ms T3 =. . T4 16ms

Machine side contact capacity 30V or more, 16mA or more

T1 T1 T1T1

T2T2

T4 T4 T3T3

6. CONNECTION OF REMOTE I/O UNIT 6.6 Outline of Digital Signal Output Circuit

I - 61

6.6 Outline of Digital Signal Output Circuit

The digital signal output circuit uses a sink type (DX1 0) or source type (DX1 1). Use within the specification ranges shown below. Output circuit

R

(Machine side)

Control circuit

24VDC(+)

Sink type (DX1 0)

RA

PL

DO-L/DO-R

R

Source (DX1 1)

RA

PL

24VDC(+)

DO-L/DO-R (Machine side)

Control circuit

Output conditions

Insulation method Non-insulation Rated load voltage 24VDC Max. output current 60mA Output delay time 40s

When using an inductive load such as a relay, always connect a diode (voltage resistance 100V or more, 100mA or more) in parallel to the load.

When using a capacity load such as a lamp, always connect a protective resistor (R=150) serially to the load to suppress rush currents. (Make sure that the current is less than the above tolerable current including the instantaneous current.)

>

CAUTION

When using an inductive load such as relays, always connect a diode in parallel to the load as a noise countermeasure.

When using a capacitive load such as a lamp, always connect a protective resistor in series to the load to suppress rush currents.

6. CONNECTION OF REMOTE I/O UNIT 6.7 Outline of Analog Signal Output Circuit

I - 62

6.7 Outline of Analog Signal Output Circuit

The analog signal output circuit can be used only for the FCUA-DX120/DX121/DX140/DX141. Output circuit

DAC

R

220 R A0

A0*

Output conditions

Output voltage 0V to 10V (5%)

Resolution 12bit (10V n/4096) (Note) Load conditions 10k load resistance

Output impedance 220

(Note) n = (20 to 211)

6. CONNECTION OF REMOTE I/O UNIT 6.8 Outline of Analog Signal Input Circuit

I - 63

6.8 Outline of Analog Signal Input Circuit

The analog signal input circuit can be used only for the FCUA-DX140/DX141.

Input circuit

ADC150 AI

AI*

Input conditions

Max. input rating 15V Resolution 10V/2000 (5mV) Precision Within 25mV

AD input sampling time 14.2ms (AI0)/42.6ms (AI1 to 3)

6. CONNECTION OF REMOTE I/O UNIT 6.9 Connection of FCUA-DX10 /13 /14 Unit and Machine Control Signal

I - 64

6.9 Connection of FCUA-DX10 /13 /14 Unit and Machine Control Signal Input Output Type of machine input/output

signal and No. of points 32 points 32 points

DO-L

R300 cable/ R301 cable

DI-L

R300 cable/ R301 cable

Machine signal

FCUA-DX10 or

FCUA-DX13 or

FCUA-DX14

Machine signal

The remote I/O unit cable types include the R300 and R301 cables. The R300 cable has one end cut off, and the R301 cable is used for connection to the Izumi Denki terminal block BX1F-T40A (Note 1). The R300-3M and R301-3M cables are available. If a cable longer than 3m is required, use the CN300 and CS301 connector set. The CN300 connector set (optional, with one end) includes the DI-L and DO-L connectors. The CS301 connector set (optional, with both ends) includes the DI-L and DO-L connectors, and two connectors for connection with the terminal block (Izumi Denki).

(Note 1) Izumi Denki I/O terminal BX1F-T40

24VDC(+)

24VDC(+)

Machine control panel

DI-L FCUA-DX100/130/140

COM A3 B3

B1 B2 A1 A2

B1 B2 A1 A2

2.2k Input circuit sink type

Output circuit sink type

DO-L

0V

RA

PL

Control circuit

Stabilized power supply

DCIN

24VDC(+) 0V FG

1 2 3 RIO2 RIO1

FG

24VDC(+)

DI-L FCUA-DX101/131/141

COM A3 B3

B1 B2 A1 A2

B1 B2 A1 A2

2.2k Input circuit source type

Output circuit source type

DO-L

0V

RA

PL

DCIN

24VDC(+) 0V FG

1 2 3 RIO2 RIO1

FG

0V

Machine control panel

Control circuit

Stabilized power supply

CAUTION

Incorrect connections could damage the device, so always connect the cable to the designated connector.

Do not connect or disconnect the connection cables between each unit while the power is ON.

6. CONNECTION OF REMOTE I/O UNIT 6.9 Connection of FCUA-DX10 /13 /14 Unit and Machine Control Signal

I - 65

DI-L

Machine side control panel, etc.

When using two or more remote I/O units or when connecting to the communication terminal, the signal assignment will differ. Refer to the "PLC interface manual" for details.

24VDC(+)

0V

RA

24VDC(+)

0V

PL

0V

24VDC(+)

DO-L

FCUA-DX10 /13 /14

B X00 X01 X02 X03 X04 X05 X06 X07 X08 X09 X0A X0B X0C X0D X0E X0F COM +24V +24V

B

20 19 18 17 16 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1

A X10 X11 X12 X13 X14 X15 X16 X17 X18 X19 X1A X1B X1C X1D X1E X1F COM 0V 0V

A

DI-L

B Y00 Y01 Y02 Y03 Y04 Y05 Y06 Y07 Y08 Y09 Y0A Y0B Y0C Y0D Y0E Y0F +24V +24V

B

20 19 18 17 16 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1

A Y10 Y11 Y12 Y13 Y14 Y15 Y16 Y17 Y18 Y19 Y1A Y1B Y1C Y1D Y1E Y1F 0V 0V

A

DO-L

Control unit

Communication terminal

R-TM Remote I/O unit

Y

DCIN 1 2 3

+24V 0V FG

RIO1 1 2 3

TxRx TxRx* LG

RIO2 1 2 3

TxRx TxRx* LG

X X

X

DCIN (CN220) Connector : 2-178288-3 Contact : 1-175218-5 Maker : Tyco

Electronics AMP

Y DI-L/DO-L (CN300) Crimp type :7940-6500SC connector Maker : Sumitomo 3M

Terminator (R-TM)

Maker: Tyco Electronics AMP

RIO1/RIO2 (CN211) Connector : 1-178288-3 Contact : 1-175218-2 Maker : Tyco

Electronics AMP

X

6. CONNECTION OF REMOTE I/O UNIT 6.10 Connection of FCUA-DX11 Unit and Machine Control Signal

I - 66

6.10 Connection of FCUA-DX11 Unit and Machine Control Signal Input Output Type of machine input/output

signal and No. of points 64 points 48 points

DO-L

R300 cable/ R301 cable

Machine signal

DI-L

R300 cable/ R301 cable

Machine signal

FCUA-DX11

DCIN RIO2

RIO1

DI-R

DO-R

The remote I/O unit cable types include the R300 and R301 cables. The R300 cable has one end cut off, and the R301 cable is used for connection to the Izumi Denki terminal block BX1F-T40A (Note 1). The R300-3M and R301-3M cables are available. If a cable longer than 3m is required, use the CN300 and CS301 connector set. The CN300 connector set (optional, with one end) includes the DI-L (DI-R) and DO-L (DO-R) connectors. The CS301 connector set (optional, with both ends) includes the DI-L and DO-L connectors, and two connectors for connection with the terminal block (Izumi Denki).

(Note 1) Izumi Denki I/O terminal BX1F-T40

24VDC(+)

24VDC(+)

Machine control panel

DI-L/R FCUA-DX110

COM A3 B3

B1 B2 A1 A2

B1 B2 A1 A2

2.2k Input circuit sink type

Output circuit sink type

DO-L/R

0V

RA

PL

Control circuit

Stabilized power supply

DCIN

24VDC(+) 0V FG

1 2 3 RIO2 RIO1

FG

24VDC(+)

COM A3 B3

B1 B2 A1 A2

B1 B2 A1 A2

2.2k Input circuit source type

Output circuit source type

0V

RA

PL

DCIN

24VDC(+) 0V FG

1 2 3 RIO2 RIO1

FG

0V

DI-L/R

DO-L/R

FCUA-DX111

Machine control panel

Stabilized power supply

Control circuit

CAUTION

Incorrect connections could damage the device, so always connect the cable to the designated connector.

Do not connect or disconnect the connection cables between each unit while the power is ON.

6. CONNECTION OF REMOTE I/O UNIT 6.10 Connection of FCUA-DX11 Unit and Machine Control Signal

I - 67

When using two or more remote I/O units or when connecting to the communication terminal, the signal assignment will differ. Refer to the "PLC interface manual" for details.

Machine side control panel, etc.

24VDC(+)

0V

RA

24VDC(+)

0V

PL

0V

24VDC(+)

FCUA-DX11

Y

DCIN 1 2 3

+24V 0V FG

RIO1 1 2 3

TxRx TxRx* LG

RIO2 1 2 3

TxRx TxRx* LG

X X

24VDC(+)

0V

RA

24VDC(+)

0V

PL

DI-L

DI-R

DO-L

DO-R

B X20 X21 X22 X23 X24 X25 X26 X27 X28 X29 X2A X2B X2C X2D X2E X2F COM +24V +24V

B

20 19 18 17 16 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1

A X30 X31 X32 X33 X34 X35 X36 X37 X38 X39 X3A X3B X3C X3D X3E X3F COM 0V 0V

A

DI-R

B Y20 Y21 Y22 Y23 Y24 Y25 Y26 Y27 Y28 Y29 Y2A Y2B Y2C Y2D Y2E Y2F AO +24V +24V

B

20 19 18 17 16 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1

A AO* 0V 0V

A

DO-R

B Y00 Y01 Y02 Y03 Y04 Y05 Y06 Y07 Y08 Y09 Y0A Y0B Y0C Y0D Y0E Y0F +24V +24V

B

20 19 18 17 16 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1

A Y10 Y11 Y12 Y13 Y14 Y15 Y16 Y17 Y18 Y19 Y1A Y1B Y1C Y1D Y1E Y1F 0V 0V

A

DO-L

DI-L

20 19 18 17 16 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1

A X10 X11 X12 X13 X14 X15 X16 X17 X18 X19 X1A X1B X1C X1D X1E X1F COM 0V 0V

A

B X00 X01 X02 X03 X04 X05 X06 X07 X08 X09 X0A X0B X0C X0D X0E X0F COM +24V +24V

B

Control unit

Communication terminal

R-TM

Remote I/O unit

X

Y Terminator (R-TM)

Maker: Tyco Electronics

AMP

X DI-L/DO-L (CN300) DI-R/DO-R Crimp type : 7940-6500SC connector Maker : Sumitomo 3M

RIO1/RIO2 (CN211) Connector : 1-178288-3 Contact : 1-175218-2 Maker : Tyco Electronics AMP

DCIN (CN220) Connector : 2-178288-3 Contact : 1-175218-5 Maker : Tyco Electronics AMP

6. CONNECTION OF REMOTE I/O UNIT 6.11 Connection of FCUA-DX12 Unit and Machine Control Signal

I - 68

6.11 Connection of FCUA-DX12 Unit and Machine Control Signal

Input Output Analog output Type of machine input/output

signal and No. of points 64 points 48 points 1 point

DO-L

R300 cable/ R301 cable

DI-L

R300 cable/ R301 cable

Machine signal

FCUA-DX12

DCIN RIO2

RIO1 Machine signal

DI-R

DO-R

The remote I/O unit cable types include the R300 and R301 cables. The R300 cable has one end cut off, and the R301 cable is used for connection to the Izumi Denki terminal block BX1F-T40A (Note 1). The R300-3M and R301-3M cables are available. If a cable longer than 3m is required, use the CN300 and CS301 connector set. The CN300 connector set (optional, with one end) includes the DI-L (DI-R) and DO-L (DO-R) connectors. The CS301 connector set (optional, with both ends) includes the DI-L and DO-L connectors, and two connectors for connection with the terminal block (Izumi Denki).

(Note 1) Izumi Denki I/O terminal BX1F-T40

24VDC(+)

24VDC(+)

Machine control panel

DI-L/R FCUA-DX120

COM A3 B3

B1 B2 A1 A2

B1 B2 A1 A2

2.2k Input circuit sink type

Output circuit sink type

DO-L/R

0V

RA

PL

24VDC(+)

COM A3 B3

B1 B2 A1 A2

B1 B2 A1 A2

2.2k Input circuit source type

Output circuit source type

0V

RA

PL

0V

DI-L/R

DO-L/R

FCUA-DX121

B4 A4

DAC R

R

220

DCIN

24VDC(+) 0V FG 1 2 3

RIO2 RIO1

FG

DO-R

Analog output

B4 A4

DAC R R

220

Stabilized power supply

DCIN

24VDC(+) 0V FG

1 2 3 RIO2 RIO1

FG

DO-R

Control circuit

Stabilized power supply

Control circuit Machine

control panel

Analog output

CAUTION

Incorrect connections could damage the device, so always connect the cable to the designated connector.

Do not connect or disconnect the connection cables between each unit while the power is ON.

6. CONNECTION OF REMOTE I/O UNIT 6.11 Connection of FCUA-DX12 Unit and Machine Control Signal

I - 69

When using two or more remote I/O units or when connecting to the communication terminal, the signal assignment will differ. Refer to the "PLC interface manual" for details.

24VDC(+)

0V

RA

24VDC(+)

0V

PL

0V

24VDC(+)

FCUA-DX12

Y

DCIN

1 2 3

+24V 0V FG

RIO1 1 2 3

TxRx TxRx* LG

RIO2 1 2 3

TxRx TxRx* LG

X X

24VDC(+)

0V

RA

24VDC(+)

0V

PL

DI-L

DI-R

DO-L

DO-R

B X20 X21 X22 X23 X24 X25 X26 X27 X28 X29 X2A X2B X2C X2D X2E X2F COM +24V +24V

B

20 19 18 17 16 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1

A X30 X31 X32 X33 X34 X35 X36 X37 X38 X39 X3A X3B X3C X3D X3E X3F COM 0V 0V

A

DI-R

B Y20 Y21 Y22 Y23 Y24 Y25 Y26 Y27 Y28 Y29 Y2A Y2B Y2C Y2D Y2E Y2F AO +24V +24V

B

20 19 18 17 16 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1

A AO* 0V 0V

A

DO-R

B Y00 Y01 Y02 Y03 Y04 Y05 Y06 Y07 Y08 Y09 Y0A Y0B Y0C Y0D Y0E Y0F +24V +24V

B

20 19 18 17 16 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1

A Y10 Y11 Y12 Y13 Y14 Y15 Y16 Y17 Y18 Y19 Y1A Y1B Y1C Y1D Y1E Y1F 0V 0V

A

DO-L

DI-L

20 19 18 17 16 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1

A X10 X11 X12 X13 X14 X15 X16 X17 X18 X19 X1A X1B X1C X1D X1E X1F COM 0V 0V

A

B X00 X01 X02 X03 X04 X05 X06 X07 X08 X09 X0A X0B X0C X0D X0E X0F COM +24V +24V

B

Control unit

Communication Terminal

R-TM

Remote I/O unit

Machine side control panel, etc.

X

Y Terminator (R-TM)

Maker: Tyco Electronics AMP

X DI-L/DO-L (CN300) DI-R/DO-R Crimp type : 7940-6500SC connector Maker : Sumitomo 3M

RIO1/RIO2 (CN211) Connector : 1-178288-3 Contact : 1-175218-2 Maker : Tyco Electronics AMP

DCIN (CN220) Connector : 2-178288-3 Contact : 1-175218-5 Maker : Tyco Electronics AMP

6. CONNECTION OF REMOTE I/O UNIT 6.12 Connection of FCUA-DX13 Unit and Manual Pulse Generator

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6.12 Connection of FCUA-DX13 Unit and Manual Pulse Generator

When connecting the manual pulse generator, the R041 or R042 cable is connected to HANDLE. Up to two manual pulse generators can be connected. Use the CS000 connector set (optional, with both ends) when manufacturing the R041 or R042 cable. Connecting one manual pulse generator

HANDLE

FCUA-DX13

1

10

11

20

Pin No.

Manual pulse generator FCUA-HD60

Rear view

NO.1

4-M3 R041 cable

12V 0V A B

Connecting two manual pulse generators

12V 0V A B HANDLE

Manual pulse generator FCUA-HD60

Rear view

R042 cable

NO.2

SEL*

NO.1

4-M3

When connecting the second manual pulse generator, connect the SEL* signal to the No.1, 0V.

FCUA-DX13

12V 0V 12V 0V A B

CAUTION

Incorrect connections could damage the device, so always connect the cable to the designated connector.

Do not connect or disconnect the connection cables between each unit while the power is ON.

6. CONNECTION OF REMOTE I/O UNIT 6.13 Outline of FCUA-DX13 Unit Pulse Input Circuit

I - 71

6.13 Outline of FCUA-DX13 Unit Pulse Input Circuit

When connecting a pulse generator other than the manual pulse generator (FCUA-HD60) to the FCUA-DX13 unit, use within the specifications range given below. Commercially available pulse generators include the 25P/R type and the 100P/R type. A pulse is multiplied by four internally, so use the 25P/R type.

Input/output conditions

Input pulse signal format A-phase and B-phase difference 90 (Refer to waveform (e) below)

Input signal voltage H level 3.5V to 5.25V, L level 0V to 0.5V Input pulse maximum frequency 100kHz

Pulse generator power voltage 12VDC 10% Maximum output current 300mA Number of pulses per rotation 25P/R (FCUA-HD60 is 25P/R)

Input waveform

The phase difference of the input waveform (e) must be 45 or less.

e : A-phase and B-phase difference e : Rising phase error of A phase or B phase (-45 e 45) T : A or B phase cycle (minimum 10s)

A (B) phase

e T

90

e B (A) phase

Input/output circuit

+12 6

1 0V Output

Input

HC14 or equivalent

HA2

FCUA-DX13

Connector pin No.

HB2

HA1

HB1

4 470

4700pF

+5V

220

14 470

4700pF

+5V

220

13 470

4700pF

+5V

220

3 470

4700pF

+5V

220

Control circuit

R041-3M (for one) and R042-3M (for two) are prepared for the handle cable.

6. CONNECTION OF REMOTE I/O UNIT 6.14 Connection of FCUA-DX14 Unit and Analog Input/Output Signal

I - 72

6.14 Connection of FCUA-DX14 Unit and Analog Input/Output Signal For the analog input/output signal, the R031 cable is connected to AI0. Up to four input points and one output point of the analog input/output signal can be connected. When manufacturing the R031 cable, use the CS000 connector set (optional, with both ends).

AIO

FCUA-DX14

1

10

11

20

Pin No.

R031 cable

Input/output circuit

DAC220 R

R

150

ADC

A10

A0

FCUA-DX14

7

GND

Input

Output

Connector pin No.

GND GND GND

A11

A12 A13 13

12

2

3

150

150

150

1

11

5

15

CAUTION

Incorrect connections could damage the device, so always connect the cable to the designated connector.

Do not connect or disconnect the connection cables between each unit while the power is ON.

6. CONNECTION OF REMOTE I/O UNIT 6.15 Cables

I - 73

6.15 Cables

The remote I/O unit cable types include the R300 and R301 cables. The R300 cable has one end cut off, and the R301 cable is used for connections with the Izumi Denki terminal block BX1F-T40A (Note 1). The R300-3M and R301-3M cables are available. If a cable longer than 3m is required, use the CN300 or CS301 connector set. The R041-3M (one-piece) and R042-3M (two-piece) manual pulse generator cables are available. The analog input/output cable R031 must be prepared by the user.

(Note 1) Izumi Denki I/O terminal BX1F-T40A

RA

PL

Machine control panel, electric cabinet, etc. R300 cable

R301 cable

ID E

C

B X

1F-T40A

15 13

9 11

7 5

3 1

31 29

25 27

23 21

19 17

33 35 37 39

16 14

10 12

8 6

4 2

32 30

26 28

24 22

20 18

34 36 38 40

Terminal block BX1F

DX1

2 B1 34 B2 6 B3 8 B4 10 B5 12 B6 14 B7 16 B8 18 B9 20 B10 22 B11 24 B12 26 B13 28 B14 30 B15 32 B16 34 B17 36 B18 38 B19 40 B20

Terminal block BX1F

DX1

1 A1 3 A2 5 A3 7 A4 9 A5 11 A6 13 A7 15 A8 17 A9 19 A10 21 A11 23 A12 25 A13 27 A14 29 A15 31 A16 33 A17 35 A18 37 A19 39 A20

Connector pin correspondence table

APPENDIX 1 OUTLINE AND INSTALLATION DIMENSIONS FOR CONTROL UNIT Appendix 1.1 Outline and Installation Dimensions for Control Unit

I - 74

APPENDIX 1 OUTLINE AND INSTALLATION DIMENSIONS FOR CONTROL UNIT Appendix 1.1 Outline and Installation Dimensions for Control Unit

RIO-M RIO-M/S

30

60

2-M50.8 screw

80 180

Wiring allowance

Top

Bottom

6

15 15

10 10

H ea

t r ad

ia tio

n an

d w

ir in

g al

lo w

an ce

35 0

36 0

H ea

t r ad

ia tio

n al

lo w

an ce

11

38 0

50

DC24VIN SERVO1

ENC HANDLE

SIOTERMINAL

ICCARD

SKIP

MITSUBISHI

MEL DAS C64

SERVO2

Top

Bottom

1 0 0

APPENDIX 1 OUTLINE AND INSTALLATION DIMENSIONS FOR CONTROL UNIT Appendix 1.2 Outline and Installation Dimensions for Control Unit with External Extension Unit

I - 75

Appendix 1.2 Outline and Installation Dimensions for Control Unit with External Extension Unit

30

60

38 0

36 0

0. 3

10

10

13 0

0. 3

15 0

60

600.3 Control unit

2-M5 screw

2-M5 screw

180(C64 dimension) 181.2(HR893 dimension) 1.6

MITSUBISHI

MELDAS C64

30 60

36 0

35 0

15

12 0

13 0

15 0

6

60 60

66

Control unit Extension unit

6

10

(1 0)

(1

5)

10

38 0

(1 5)

(1

0)

8 15

E XT

3

APPENDIX 2 OUTLINE AND INSTALLATION DIMENSIONS FOR COMMUNICATION TERMINAL Appendix 2.1 Outline and Installation Dimensions for FCUA-CT100

I - 76

APPENDIX 2 OUTLINE AND INSTALLATION DIMENSIONS FOR COMMUNICATION TERMINAL Appendix 2.1 Outline and Installation Dimensions for FCUA-CT100

MITSUBISHI

382(Square hole)9 9

5 130 140

130130

260

8-4hole(For M3 screw) 5

18 0

9 9

250

382 (Square hole dimensions)

1300.2 1300.2 1300.2

18 2

(S qu

ar e

ho le

d im

en si

on s)

19 0

0. 2

8-M3screw

5 5

5 5

18 2(

S qu

ar e

ho le

)

Panel cut drawing

APPENDIX 2 OUTLINE AND INSTALLATION DIMENSIONS FOR COMMUNICATION TERMINAL Appendix 2.2 Outline and Installation Dimensions for FCUA-CR10

I - 77

Appendix 2.2 Outline and Installation Dimensions for FCUA-CR10

250

242 (Square hole dimensions)

1200.21300.2

6-M3 screw

19 0

0. 2

10

18 0

10

MITSUBISHI

242 (Square hole)9

120130

260

6-4 hole(for M3 screw) 5

18 0

9 9

20 0

5 5

5 5

9

18 2

(S qu

ar e

ho le

)

18 2

(S qu

ar e

ho le

d

im en

si on

s)

5

Panel cut drawing

APPENDIX 2 OUTLINE AND INSTALLATION DIMENSIONS FOR COMMUNICATION TERMINAL Appendix 2.3 Outline and Installation Dimensions for FCUA-LD100

I - 78

Appendix 2.3 Outline and Installation Dimensions for FCUA-LD100

MITSUBISHI

382 (Square hole)9 9

5 130 140

130130

260

8-4hole(for M3 screw) 5

5 18

0 10

9 9

19 0

5

10

70

1300.2 1300.2 1300.2

382 (Square hole dimensions) 44 8-M3 screw

4

18 2

(S qu

ar e

ho le

di

m en

si on

s)

4

19 0

0. 2

18 2

(S qu

ar e

ho le

)

Panel cut drawing

APPENDIX 2 OUTLINE AND INSTALLATION DIMENSIONS FOR COMMUNICATION TERMINAL Appendix 2.4 Outline and Installation Dimensions for FCUA-LD10 and KB20

I - 79

Appendix 2.4 Outline and Installation Dimensions for FCUA-LD10 and KB20

MITSUBISHI

120130

260

6-4 hole (for M3 screw) 5

5 18

0

6-M3 screw 248

(square hole dimensions

1300.2 1200.2

19 0

0. 2

11 4-M3 screw 132 (square hole

dimensions

1300.2

19 0

0. 2

5 130 140

18 0

5

19 0

20 0

10

5 10

5

30

19 0

20 0

10

5 10

5 70

4-4 hole (for M3 screw)

Panel cut drawing

18 2

(s qu

ar e

ho le

di

m en

si on

s)

4 4

18 2

(s qu

ar e

ho le

di

m en

si on

s)

4 4

11

APPENDIX 2 OUTLINE AND INSTALLATION DIMENSIONS FOR COMMUNICATION TERMINAL Appendix 2.5 Outline and Installation Dimensions for FCU6-DUT32, KB021

I - 80

Appendix 2.5 Outline and Installation Dimensions for FCU6-DUT32, KB021

140

21 0

Menu keys 270

Escutcheon M3x8 screw

Protective cover

45

(50) 20

20 30

6-4 hole

18 2

0. 3

(S qu

ar e

ho le

d im

en si

on s)

19 0

0. 3

1

Square hole

4

132 (Square hole dimensions)

4-4 hole

1 1

140(Keyboard outline) 1300.3

5

(9 ) (5 )

9

5 (1)

20 0

0. 3

18 2

(S qu

ar e

ho le

d im

en si

on s)

21 0

(K ey

bo ar

d ou

tli ne

)

21 0

1300.3

248 (Square hole dimensions)

1200.3

4

SFG EDIT MDI

MONI- TOR

TOOL PARAM

DIAGN IN/OUT

CB CAN

FO

9 N G

1 2 3

4 5 6

7 8

/

$

. ,

- +

* DELETE

INS

SHIFT

INPUT CALC

RESET

READY

O

Square hole

A

B

C

X U

Y V

Z W

F F

D L

D !

P I

Q J

R K

M (

S )

T [

EOB ]

0 SP

=

#

Panel cut drawing

APPENDIX 3 OUTLINE AND INSTALLATION DIMENSIONS FOR REMOTE I/O UNIT

I - 81

APPENDIX 3 OUTLINE AND INSTALLATION DIMENSIONS FOR REMOTE I/O UNIT

40

135

70

Wiring allowance

135

6

168

H ea

t r ad

ia tio

n al

lo w

an ce

2-M5-0.8 screw

156

6

6

34 6

DX

Top

Bottom

Installation Hole

10 0

H ea

t r ad

ia tio

n an

d w

iri ng

a llo

w an

ce

15 0

APPENDIX 4 OUTLINE AND INSTALLATION DIMENSIONS FOR MANUAL PULSE GENERATOR

I - 82

APPENDIX 4 OUTLINE AND INSTALLATION DIMENSIONS FOR MANUAL PULSE GENERATOR

3 -4.8 Equal

62 +2 0

72 0.2

(Trisection) 120

Packing t2.0 3.6

770.5

801

600.5 16 24 270.5 600.5

12V 0V A B

8.89 7.60

Installation other than M3 x 6 not possible

3 - M4 stud bolts L10

Panel cut drawing

APPENDIX 5 OUTLINE AND INSTALLATION DIMENSIONS FOR SYNCHRONOUS FEED ENCODER

I - 83

APPENDIX 5 OUTLINE AND INSTALLATION DIMENSIONS FOR SYNCHRONOUS FEED ENCODER

A 1chA K 0V B 2chZ L C 3chB M D N 1chA E Case ground P 2chZ F R 3chB G S H +5V T J

68 56

68 56 68

Caution plate Detector (1024P/rev)

50

19.5

5 3

2 28

20

33102

135

Encoder side: 97F3102E20-29P

(or equivalent) Adaptive cable side: MS3106A20-29S

50 -0.009 -0.025

16 15

-0.006 -0.017

2

2

26

1.15 +0.14 0 1.15 +0.14

0

50 -0.012 -0.042

3 0 +0.1

Enlarged view of key

4-5.4 hole

Cross-section BB The effective depth of the key way is 21mm.

14.3 0 -0.11

-0.009 -0.025

APPENDIX 6 OUTLINE AND INSTALLATION DIMENSIONS FOR GROUNDING PLATE AND CLAMP FITTING

I - 84

APPENDIX 6 OUTLINE AND INSTALLATION DIMENSIONS FOR GROUNDING PLATE AND CLAMP FITTING The shield wire generally only needs to be grounded to the connector's case frame. However, the effect can be improved by directly grounding to the grounding plate as shown on the right. Install the grounding plate near each unit. Peel off part of the cable sheath as shown on the right to expose the shield sheath. Press that section against the grounding plate with the clamp fitting. Note that if the cable is thin, several can be clamped together. Install the grounding plate directly onto the cabinet or connect a grounding wire so that sufficient frame grounding is achieved. If the AERSBAN- SET, containing the grounding plate and clamp fitting, is required, please contact Mitsubishi.

Clamp section drawing

Clamp fitting Fitting A,B

Grounding Plate

Cable

Shield sheath

40

Outline drawing

Grounding plate

2-5 hole Installation hole

17.5

M4 screw Note 1)

6 22 35

10MAX L

Clamp fitting

A

35

C

24 -0

.2

0

B 0

.3

6 3 7

11

30

24

0 +0

.3

Note 1) Screw hole for wiring to cabinet's grounding plate

Note 2) The grounding plate thickness is 1.6mm

A B C Enclosed fittings L AERSBAN-DSET 100 86 30 Two clamp fittings A Clamp fitting A 70 AERSBAN-ESET 70 56 One clamp fitting B Clamp fitting B 45

APPENDIX 7 CABLE MANUFACTURING DRAWINGS

I - 85

APPENDIX 7 CABLE MANUFACTURING DRAWINGS

As a rule, most F /R cables used with this product are not sold by Mitsubishi. Thus, manufacture the required cables using the cable manufacturing drawings on the following pages as a reference. Note that the cable-compatible connectors can be purchased from Mitsubishi. If crimp tools are not available when manufacturing the power supply cable (R200, R220) and communication cable (R211), the cables can be manufactured by soldering a wire and connector as shown in the following procedures.

1. Carry out preparatory soldering onto the wire.

(Peel 3.5mm of the sheath.) 2. Insert the wire into the contact. Hold the sheath

retainer.

Soldering iron

Solder

Wire

Contact

3. Lightly press down one side of the wire barrel

using radio pliers. 4. Firmly press down the other side of the wire

barrel. (Press firmly enough that the wire will not come out when pulled lightly.)

Wire barrel This is a barrier to prevent incorrect insertion. Do not bend.

Radio pliers

5. Firmly press down the sheath retainer in the same manner as the wire barrel.

6. Apply the soldering iron, and melt the preparatory solder inside. (Better results will be achieved if an additional, small amount of solder is applied.)

Sheath retainer

7. Lastly, insert the soldered contact with wire into the housing.

Contact section

Soldering iron

Be careful that the solder does not flow into the contact section.

Pay attention to the insertion direction.

APPENDIX 7 CABLE MANUFACTURING DRAWINGS Appendix 7.1 F310 Cable Manufacturing Drawing

I - 86

Appendix 7.1 F310 Cable Manufacturing Drawing Application : Control unit - serial device connection

(Cable from control unit to junction plate.) List of parts used

1 2 3

4 5 6

7

F310

F310

Note (3)

Control unit side

Junction plate side

Assembly drawing

No. Part name/type Maker Qty

1 Connector 10120-3000VE Sumitomo 3M 1

2 Connector case 10320-52F0-008 Sumitomo 3M 1

3 Wire material UL1061-2464 AWG22 6P

Note (1) (1)

4 Connector CDB-25S Hirose Electric 1

5 Contact CD-SC-111 Hirose Electric 7

6 Lock nut HD-LNA Hirose Electric 2

7 F installation plate N750D714H01

Mitsubishi Electric (Refer to dimen-

sion drawing) 1

Case GND plate

Junction plate RS-232C

Maximum cable length: 8m Note (4)

Control unit side SIO

2 12 3

13 4

14 1

3 2 5 4 6

20 7

RXD TXD CTS RTS DSR DTR SG

Connection diagram

(5.5) 5.565

47.10.2 42.60.2

2-R2.5 2-R1.75

5

38 76

60.1

12 24

Plate thickness: 1.6mm

F installation plate outline dimensions drawing

Manufacturing precautions

(1) The wire material shall be a shielded, 6-pair stranded cable equivalent to UL1061-2464 Standards AWG22 (0.3mm2).

(2) The parts used shall be Mitsubishi recommended parts. Equivalent parts may be used providing they are compatible with the specifications.

(3) Attach the nameplate (with protective cover stamped with the cable name) in the position designated in the assembly drawing.

(4) The total length of the cable, including the length from this cable to the cable connected to the RS-232C device, must be 15m or less.

APPENDIX 7 CABLE MANUFACTURING DRAWINGS Appendix 7.2 F311 Cable Manufacturing Drawing

I - 87

Appendix 7.2 F311 Cable Manufacturing Drawing Application : Control unit - serial device connection

(Cable from control unit to junction plate.) List of parts used

Control unit side

1 2

3

7

7

4 5 6

4 5 6

F311A

F311A

Note (3)

R S

232 G

P P

Note (4)

S IO

Junction plate side Assembly drawing No. Part name/type Maker Qty

1 Connector 10120-6000VE

Sumitomo 3M 1

2 Connector case 10320-3210-000 Sumitomo 3M 1

3 Wire material UL20276 AWG28 10P

Note (1) (1)

4 Connector CDB-25S

Hirose Electric 2

5 Contact CD-SC-111

Hirose Electric 21

6 Lock nut HD-LNA

Hirose Electric 4

7 F installation plate N750D714H01

Mitsubishi Electric (Refer to dimen-

sion drawing) 2

Maximum cable length: 8m (Note 5)

RS-232C Control unit side

SIO 2

12 3

13 4

14 1

3 2 5 4 6

20 7

Case GND plate

RS-422(GPP)

11 5

15 10 20 7

17 8

18 6

16 9

19

20 7 8

21 12 13 3

16 2

15 5

18 4

17

RXD TXD CTS RTS DSR DTR SG

SG SG SG SG(SEL) +5V +5V TXD TXD* RXD RXD* DTR DTR* DCD DCD*

Connection diagram

(5.5) 5.565

47.10.2 42.60.2

2-R2.5 2-R1.75

5

38 76

60.1

12 24

Plate thickness: 1.6mm

F installation plate outline dimensions drawing

Manufacturing precautions (1) The wire material shall be a shielded, 10-pair stranded cable equivalent to UL20276 Standards

AWG28 (0.08mm2). (2) The parts used shall be Mitsubishi recommended parts. Equivalent parts may be used providing

they are compatible with the specifications. (3) Attach the nameplate (with protective cover stamped with the cable name) in the position

designated in the assembly drawing. The Mitsubishi-supplied cable is labeled F311A due to a change of its connection.

(4) Provide a protective cover from the exposed part of the branching section wire to the connector, and fix with a bundling band.

(5) The total length of the cable, including the length from this cable to the cable connected to the RS-232C device, must be 15m or less.

APPENDIX 7 CABLE MANUFACTURING DRAWINGS Appendix 7.3 F320 Cable Manufacturing Drawing

I - 88

Appendix 7.3 F320 Cable Manufacturing Drawing

Application : Control unit - manual pulse generator connection (When connecting one manual pulse generator)

Option (Compatible connector set) FCUA-CS000 (Note that only the control unit connector is compatible)

List of parts used

F320

F320

Note (3)

1 2 3

4

Control unit side

Manual pulse generator side

Assembly drawing No. Part name/type Maker Q'ty

1 Connector 10120-3000VE Sumitomo 3M 1

2 Connector case 10320-52F0-008 Sumitomo 3M 1

3 Wire material UL1061-2464 AWG22 6P

Note (1) (1)

4 Crimp terminal V1.25-3 J. S. T 4

Case GND plate

Manual pulse generator side

Maximum cable length: 30m

Control unit side

4 14

6 1

1HA 1HB +12V GND

1HA 1HB

+12V GND

Connection diagram

Manufacturing precautions

(1) The wire material shall be a shielded, 6-pair stranded cable equivalent to UL1061-2464 Standards AWG22 (0.3mm2).

(2) The parts used shall be Mitsubishi recommended parts. Equivalent parts may be used providing they are compatible with the specifications.

(3) Attach the nameplate (with protective cover stamped with the cable name) in the position designated in the assembly drawing.

(4) Fold the wire material shield on the control unit side over the sheath, and wrap copper foil tape over it. Connect to the connector case GND plate.

(5) Stamp the name of each signal on the crimp terminal side mark tube and install. (6) In the catalog specifications, the part 1 connector uses AWG24 (0.2mm2) or less wire material,

but AWG22 (0.3mm2) can also be used.

APPENDIX 7 CABLE MANUFACTURING DRAWINGS Appendix 7.4 F321 Cable Manufacturing Drawing

I - 89

Appendix 7.4 F321 Cable Manufacturing Drawing

Application : Control unit - manual pulse generator connection (When connecting two manual pulse generators)

Option (Compatible connector set) FCUA-CS000 (Note that only the control unit connector is compatible)

List of parts used

F321

Note (3)

1 2 3

4

Control unit side

Manual pulse generator side

F321

Assembly drawing No. Part name/type Maker Q'ty

1 Connector 10120-3000VE Sumitomo 3M 1

2 Connector case 10320-52F0-008 Sumitomo 3M 1

3 Wire material UL1061-2464 AWG22 6P

Note (1) (1)

4 Crimp terminal V1.25-3 J. S. T 8

Manual pulse generator side

Maximum cable length: 30m Control unit side

4 14 6 1

1HA 1HB +12V GND

Case GND plate

3 13 16 11

2HA 2HB +12V GND

1HA 1HB +12V GND 2HA 2HB +12V GND

Connection diagram

Manufacturing precautions

(1) The wire material shall be a shielded, 6-pair stranded cable equivalent to UL1061-2464 Standards AWG22 (0.3mm2).

(2) The parts used shall be Mitsubishi recommended parts. Equivalent parts may be used providing they are compatible with the specifications.

(3) Attach the nameplate (with protective cover stamped with the cable name) in the position designated in the assembly drawing.

(4) Fold the wire material shield on the control unit side over the sheath, and wrap copper foil tape over it. Connect to the connector case GND plate.

(5) Stamp the name of each signal on the crimp terminal side mark tube and install. (6) In the catalog specifications, the part 1 connector uses AWG24 (0.2mm2) or less wire material,

but AWG22 (0.3mm2) can also be used.

APPENDIX 7 CABLE MANUFACTURING DRAWINGS Appendix 7.5 F322 Cable Manufacturing Drawing

I - 90

Appendix 7.5 F322 Cable Manufacturing Drawing

Application : Control unit - manual pulse generator connection (When connecting three manual pulse generators)

Option (Compatible connector set) FCUA-CS000 (Note that only the control unit connector is compatible)

List of parts used

F322

Note (3)

1 2 3

4

Control unit side

Manual pulse generator side

F322

Assembly drawing No. Part name/type Maker Q'ty

1 Connector 10120-3000VE Sumitomo 3M 1

2 Connector case 10320-52F0-008 Sumitomo 3M 1

3 Wire material UL1061-2464 AWG22 6P

Note (1) (1)

4 Crimp terminal V1.25-3 J. S. T 12

1HA 1HB

+12V GND 2HA 2HB

+12V GND 3HA 3HB GND

Maximum cable length: 30m

Manual pulse generator side

Control unit side

4 14 6 1

1HA 1HB +12V

3 13 16 5 7

17

11

Case GND plate

GND 2HA 2HB +12V GND 3HA 3HB +12V GND

Connection diagram

Manufacturing precautions

(1) The wire material shall be a shielded, 6-pair stranded cable equivalent to UL1061-2464 Standards AWG22 (0.3mm2).

(2) The parts used shall be Mitsubishi recommended parts. Equivalent parts may be used providing they are compatible with the specifications.

(3) Attach the nameplate (with protective cover stamped with the cable name) in the position designated in the assembly drawing.

(4) Fold the wire material shield on the control unit side over the sheath, and wrap copper foil tape over it. Connect to the connector case GND plate.

(5) Stamp the name of each signal on the crimp terminal side mark tube and install. (6) In the catalog specifications, the part 1 connector uses AWG24 (0.2mm2) or less wire material,

but AWG22 (0.3mm2) can also be used.

APPENDIX 7 CABLE MANUFACTURING DRAWINGS Appendix 7.6 F340 Cable Manufacturing Drawing

I - 91

Appendix 7.6 F340 Cable Manufacturing Drawing

Application : External skip signal input (4 points)

List of parts used

F340

Note (2)

1 2 3 5Cotrol unit side

Skip signal input

4

S KI

P

F340

Assembly drawing No. Part name/type Maker Q'ty

1 Connector CDE-9PF

Hirose Electric 1

2 Contact CD-PC-111

Hirose Electric 8

3 Connector case HDE-CTH

Hirose Electric 1

4 Wire material B-22(19)X2SJ-1X9

Sumitomo Denko (4)

5 Crimp terminal V1.25-4

J. S. T 8

Maximum cable length: 30m

Skip signal input Control unit side

1 6 2 7 3 8 4 9

Case GND plate

SKIP0 SKIP0* SKIP1 SKIP1* SKIP2 SKIP2* SKIP3 SKIP3*

SKIP0 SKIP0* SKIP1 SKIP1* SKIP2 SKIP2* SKIP3 SKIP3*

Connection diagram

Manufacturing precautions

(1) The parts used shall be Mitsubishi recommended parts. Equivalent parts may be used providing they are compatible with the specifications.

(2) Attach the nameplate (with protective cover stamped with the cable name) in the position designated in the assembly drawing.

(3) Fold the wire material shield on the control unit side over the sheath, and wrap copper foil tape over it. Connect to the connector case GND plate.

(4) Stamp the name of each signal on the crimp terminal side mark tube and install. (5) Insulate the crimp terminals of unused signal wires with vinyl tape, etc.

APPENDIX 7 CABLE MANUFACTURING DRAWINGS Appendix 7.7 F350 Cable Manufacturing Drawing

I - 92

Appendix 7.7 F350 Cable Manufacturing Drawing

Application : Control unit - machine electric cabinet

List of parts used No. Part name/type Maker Q'ty

1 Connector 7920-6500SC Sumitomo 3M 1

2 Strain relief 3448-7920

Sumitomo 3M 1

3 Wire material B20-S

Note (1) (1)

1 2 First wire is colored 3 Machine power distribution

panel side

Maximum cable length: 50m

F350

Note (2)

Control unit side

Assembly drawing

Manufacturing precautions

(1) The parts used shall be Mitsubishi recommended parts. Equivalent parts may be used providing they are compatible with the specifications.

(2) Attach the nameplate (with protective cover stamped with the cable name) in the position designated in the assembly drawing.

APPENDIX 7 CABLE MANUFACTURING DRAWINGS Appendix 7.8 F351 Cable Manufacturing Drawing

I - 93

Appendix 7.8 F351 Cable Manufacturing Drawing

Application : Extension DIO - machine electric cabinet

List of parts used No. Part name/type Maker Q'ty

1 Connector 7940-6500SC

Sumitomo 3M 1

2 Strain relief 3448-7940

Sumitomo 3M 1

3 Wire material B40-S

Note (1) (1)

1 2 First wire is colored

3 Machine power distribution panel side

Maximum cable length: 50m

F351

Note (2)

Control unit side

Assembly drawing

Manufacturing precautions (1) The parts used shall be Mitsubishi recommended parts. Equivalent parts may be used providing

they are compatible with the specifications. (2) Attach the nameplate (with protective cover stamped with the cable name) in the position

designated in the assembly drawing. (3) The DI and DO cables are the same. Stamp DI or DO on the connector to prevent incorrect

insertion.

APPENDIX 7 CABLE MANUFACTURING DRAWINGS Appendix 7.9 FCUA-R000 Cable Manufacturing Drawing

I - 94

Appendix 7.9 FCUA-R000 Cable Manufacturing Drawing

Application : Control unit servo drive unit connection Servo drive unit servo drive unit connection Control unit - communication terminal connection, etc.

Option (Compatible connector set) FCUA-CS000

List of parts used

1 2

3

R000

1 2

R000

Note (3)

Assembly drawing

No. Part name/type Maker Q'ty

1 Connector 10120-6000EL

Sumitomo 3M 2

2 Connector case 10320-3210-000

Sumitomo 3M 2

3 Wire material UL20276 AWG28 10P

Note (1) (1)

(Note) This cable is the same as SH21 cable.

Maximum cable length: 30m

1 11 2

12 3

13 4

14 5

15 6

16 7

17 8

18 9

19 10 20

Case GND plate Case GND plate

1 11 2

12 3

13 4

14 5

15 6

16 7

17 8

18 9

19 10 20

Connection diagram

Manufacturing precautions

(1) The wire material shall be a shielded, 10-pair stranded cable equivalent to UL20276 Standards AWG28 (0.08mm2).

(2) The parts used shall be Mitsubishi recommended parts. Equivalent parts may be used providing they are compatible with the specifications.

(3) Attach the nameplate (with protective cover stamped with the cable name) in the position designated in the assembly drawing.

(4) Fold the wire material shield over the sheath, and wrap copper foil tape over it. Clamp with the connector case frame.

(5) The part 1 connector and part 2 connector case are crimp type parts. If soldered types are preferred, use the 10120-3000VE connector and 10320-52F0-008 connector case (both Sumitomo 3M).

APPENDIX 7 CABLE MANUFACTURING DRAWINGS Appendix 7.10 FCUA-R050 Cable Manufacturing Drawing

I - 95

Appendix 7.10 FCUA-R050 Cable Manufacturing Drawing

Application : Control unit - synchronous feed encoder connection (Straight type)

Option (Compatible connector set) FCUA-CS050

List of parts used

Note (3)

R050

3

1 2 Control unit side

4 5

Synchronous feed encoder side

R050

Assembly drawing

No. Part name/type Maker Q'ty

1 Connector 10120-3000VE Sumitomo 3M 1

2 Connector case 10320-52F0-008 Sumitomo 3M 1

3 Wire material UL1061-2464 AWG22 12P

Note (1) (1)

4 Straight plug MS3106B20-29S ITT Cannon1

5 Cable clamp MS3057-12A ITT Cannon1

Maximum cable length: 30m

2 12

3 13

4 14 10

20

1

11

Case GND plate

Control unit side Synchronous feed encoder side

PC1 PC1* PB1 PB1* PA1 PA1* +5V +5V GND GND

B P C R A N H

K

Connection diagram

Manufacturing precautions

(1) The wire material shall be a shielded, 12-pair stranded cable equivalent to UL1061-2464 Standards AWG22 (0.3mm2).

(2) The parts used shall be Mitsubishi recommended parts. Equivalent parts may be used providing they are compatible with the specifications.

(3) Attach the nameplate (with protective cover stamped with the cable name) in the position designated in the assembly drawing.

(4) Fold the wire material shield on the control unit side over the sheath, and wrap copper foil tape over it. Connect to the connector case GND plate.

(5) For the batch connection treatment and shield treatment wire, use AWG24 (0.2mm2) or equivalent.

(6) In the catalog specifications, the part 1 connector uses AWG24 (0.2mm2) or less wire material, but AWG22 (0.3mm2) can also be used.

APPENDIX 7 CABLE MANUFACTURING DRAWINGS Appendix 7.11 FCUA-R051 Cable Manufacturing Drawing

I - 96

Appendix 7.11 FCUA-R051 Cable Manufacturing Drawing

Application : Control unit - synchronous feed encoder connection (Straight type)

Option (Compatible connector set) FCUA-CS050

List of parts used

1 2 3

R051

Note (3)

Control unit side 4 5

Synchronous feed encoder side

R051

Assembly drawing

No. Part name/type Maker Q'ty

1 Connector 10120-3000VE Sumitomo 3M 1

2 Connector case 10320-52F0-008 Sumitomo 3M 1

3 Wire material UL1061-2464 AWG22 12P

Note (1) (1)

4 Straight plug MS3106B20-29S ITT Cannon1

5 Cable clamp MS3057-12A ITT Cannon1

Maximum cable length: 30m

7 17 8

18 9

19 10

20

1

11

5

15

Case GND plate

B P C R A N H

K

Control unit side Synchronous feed encoder side

PC2 PC2* PB2 PB2* PA2 PA2* +5V +5V GND GND GND GND

Connection diagram

Manufacturing precautions

(1) The wire material shall be a shielded, 12-pair stranded cable equivalent to UL1061-2464 Standards AWG22 (0.3mm2).

(2) The parts used shall be Mitsubishi recommended parts. Equivalent parts may be used providing they are compatible with the specifications.

(3) Attach the nameplate (with protective cover stamped with the cable name) in the position designated in the assembly drawing.

(4) Fold the wire material shield on the control unit side over the sheath, and wrap copper foil tape over it. Connect to the connector case GND plate.

(5) For the batch connection treatment and shield treatment wire, use AWG24 (0.2mm2) or equivalent.

(6) In the catalog specifications, the part 1 connector uses AWG24 (0.2mm2) or less wire material, but AWG22 (0.3mm2) can also be used.

APPENDIX 7 CABLE MANUFACTURING DRAWINGS Appendix 7.12 FCUA-R054 Cable Manufacturing Drawing

I - 97

Appendix 7.12 FCUA-R054 Cable Manufacturing Drawing

Application : Control unit - synchronous feed encoder connection (Right angle type)

Option (Compatible connector set) FCUA-CS054

List of parts used

Note (3)

1 2

Control unit side

4 5

Synchronous feed encoder side

3

R054

R054

Assembly drawing

No. Part name/type Maker Q'ty

1 Connector 10120-3000VE Sumitomo 3M 1

2 Connector case 10320-52F0-008 Sumitomo 3M 1

3 Wire material UL1061-2464 AWG22 12P

Note (1) (1)

4 Right angle plug MS3108B20-29S ITT Cannon1

5 Cable clamp MS3057-12A ITT Cannon1

Maximum cable length: 30m

2 12 3

13 4

14 10

20

1

11

Case GND plate

B P C R A N H

K

Control unit side Synchronous feed encoder side

PC1 PC1* PB1 PB1* PA1 PA1* +5V +5V GND GND

Connection diagram

Manufacturing precautions

(1) The wire material shall be a shielded, 12-pair stranded cable equivalent to UL1061-2464 Standards AWG22 (0.3mm2).

(2) The parts used shall be Mitsubishi recommended parts. Equivalent parts may be used providing they are compatible with the specifications.

(3) Attach the nameplate (with protective cover stamped with the cable name) in the position designated in the assembly drawing.

(4) Fold the wire material shield on the control unit side over the sheath, and wrap copper foil tape over it. Connect to the connector case GND plate.

(5) For the batch connection treatment and shield treatment wire, use AWG24 (0.2mm2) or equivalent.

(6) In the catalog specifications, the part 1 connector uses AWG24 (0.2mm2) or less wire material, but AWG22 (0.3mm2) can also be used.

APPENDIX 7 CABLE MANUFACTURING DRAWINGS Appendix 7.13 FCUA-R055 Cable Manufacturing Drawing

I - 98

Appendix 7.13 FCUA-R055 Cable Manufacturing Drawing

Application : Control unit - synchronous feed encoder connection (Right angle type)

Option (Compatible connector set) FCUA-CS054

List of parts used

1 2

3

R055

4 5

Note (3)

Control unit side Synchronous feed encoder side

R055

Assembly drawing

No. Part name/type Maker Q'ty

1 Connector 10120-3000VE Sumitomo 3M 1

2 Connector case 10320-52F0-008 Sumitomo 3M 1

3 Wire material UL1061-2464 AWG22 12P

Note (1) (1)

4 Right angle plug MS3108B20-29S ITT Cannon1

5 Cable clamp MS3057-12A ITT Cannon1

Maximum cable length: 30m

7 17 8

18 9

19 10

20

1

11

5

15

Case GND plate

B P C R A N H

K

Control unit side Synchronous feed encoder side

PC2 PC2* PB2 PB2* PA2 PA2* +5V +5V GND GND GND GND

Connection diagram

Manufacturing precautions (1) The wire material shall be a shielded, 12-pair stranded cable equivalent to UL1061-2464

Standards AWG22 (0.3mm2). (2) The parts used shall be Mitsubishi recommended parts. Equivalent parts may be used providing

they are compatible with the specifications. (3) Attach the nameplate (with protective cover stamped with the cable name) in the position

designated in the assembly drawing. (4) Fold the wire material shield on the control unit side over the sheath, and wrap copper foil tape

over it. Connect to the connector case GND plate. (5) For the batch connection treatment and shield treatment wire, use AWG24 (0.2mm2) or

equivalent. (6) In the catalog specifications, the part 1 connector uses AWG24 (0.2mm2) or less wire material,

but AWG22 (0.3mm2) can also be used.

APPENDIX 7 CABLE MANUFACTURING DRAWINGS Appendix 7.14 FCUA-R211 Cable Manufacturing Drawing

I - 99

Appendix 7.14 FCUA-R211 Cable Manufacturing Drawing

Application: Control unit remote I/O unit connection Remote I/O unit remote I/O unit connection Remote I/O unit communication terminal connection

Option (Compatible connector set) FCUA-CN211 (Note that when a one end connector and contact are used, there is no crimp terminal)

List of parts used

1 2

3

45

1 2

R211

X

X

R211

Control unit side

Note (3)

Assembly drawing No. Part name/type Maker Qty.

1 Connector 1-178288-3

Tyco Electronics

AMP 2

2 Contact 1-175218-2

Tyco Electronics

AMP 6

3

Wire material MIX3CHRV-SV-SB Twisted pair cable with compound 3-pair shield. Note (1)

TOA Electric Industry

(1)

4 Crimp terminal V1.25-3 J. S. T 1

5 Crimp terminal V1.25-5 J. S. T 1

1 2 3

1 2 3

TXRX TXRX* LG

FG Note (5)

TXRX TXRX* LG

FG

Maximum cable length: 50mConnection diagram

Manufacturing precautions

(1) The wire material shall be a shielded 3-pair stranded pair cable equivalent to AWG20 (0.5mm2). (2) The parts used shall be Mitsubishi recommended parts. Equivalent parts may be used providing

they are compatible with the specifications. (3) Attach the nameplate (with protective cover stamped with the cable name) in the position

designated in the assembly drawing. (4) Install each crimp terminal side after stamping the name of each signal on the mark tube. (5) Protect both ends of the wire material with insulation bushing. (6) Use AWG18 (0.75mm2) or equivalent for the shield treatment wire material. (7) Ground the crimp terminal connected to the shield to the control unit or communication terminal

frame ground. Note that there may be cases where only one end is connected, both ends are connected, or neither end is connected to improve the noise resistance,.

APPENDIX 7 CABLE MANUFACTURING DRAWINGS Appendix 7.15 FCUA-R220 Cable Manufacturing Drawing

I - 100

Appendix 7.15 FCUA-R220 Cable Manufacturing Drawing

Application: Supply of 24V to control unit, remote I/O unit and communication terminal

Option (Compatible connector set) FCUA-CN220 (Note that this corresponds only to the connector on the control unit side.)

List of parts used

1 2 3 4

FG

GND

+24V

R220

Note (3)

Y R220

Assembly drawing No. Part

name/model Maker Q'ty

1 Connector 2-178288-3

Tyco Electronics

AMP 1

2 Contact 1-175218-5

Tyco Electronics

AMP 3

3 Wire material JPVV-SB 1P 0.5mm2

BANDO Electric Industry Note (1)

(1)

4 Crimp terminal V1.25-3 J. S. T 3

WHITE

BROWN

Maximum cable length: 30m

FG GND +24V

3 2 1

FG GND +24V

Connection diagram

Manufacturing precautions

(1) The wire material shall be a shielded 1-pair stranded cable equivalent to AWG20 (0.5mm2). If the cable is 10m or longer, select AWG16 (1.25mm2) material or equivalent.

(2) The parts used shall be Mitsubishi recommended parts. Equivalent parts may be used providing they are compatible with the specifications.

(3) Attach the nameplate (with protective cover stamped with the cable name) in the position designated in the assembly drawing.

(4) Install each crimp terminal side after stamping the name of each signal on the mark tube. (5) Protect both ends of the wire material with insulation bushing. (6) Use AWG18 (0.75mm2) or equivalent for the shield treatment wire material.

APPENDIX 7 CABLE MANUFACTURING DRAWINGS Appendix 7.16 F300 Cable Manufacturing Drawing

I - 101

Appendix 7.16 F300 Cable Manufacturing Drawing

Application : Main card in control unit front panel internal connection List of parts used

1 2 43

F300

F300 Y

1155mm

Assembly drawing No. Part name/model Maker Q'ty

1 Connector 2-177648-3

Tyco Electronics

AMP 1

2 Contact 1-175289-5

Tyco Electronics

AMP 3

3 Connector 2-178288-3

Tyco Electronics

AMP 1

4 Contact 1-175218-5

Tyco Electronics

AMP 3

B20-2 B20-9 B20-5

1 2 3

1 2 3

+24V RG FG

Connection diagram

Manufacturing precautions

(1) The wire material shall be AWG20 (0.5mm2) or equivalent. (2) The parts used shall be Mitsubishi recommended parts. Equivalent parts may be used providing

they are compatible with the specifications. (3) Attach the nameplate (with protective cover stamped with the cable name) in the position

designated in the assembly drawing.

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I 102

APPENDIX 8 LIST OF CONNECTOR SETS

APPENDIX 8 LIST OF CONNECTOR SETS

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APPENDIX 7 LIST OF CONNECTOR SETS 8

APPENDIX 9 EMC INSTALLATION GUIDELINES Appendix 9.1 Introduction

I - 104

APPENDIX 9 EMC INSTALLATION GUIDELINES Appendix 9.1 Introduction

EMC Directives became mandatory as of January 1, 1996. The target products must have a CE mark attached indicating that the product complies with the Directives. As the NC unit is a component designed to control machine tools, it is believed that it is not a direct EMC Directive subject. However, we would like to introduce the following measure plans to back up EMC Directive compliance of the machine tool as the NC unit is a major component of the machine tools.

(1) Methods of installation in control/operation panel (2) Methods of wiring cables to outside of panel (3) Introduction of members for measures

Mitsubishi is carrying out tests to confirm the compliance to the EMC Directives under the environment described in this manual. However, the level of the noise will differ according to the equipment type and layout, control panel structure and wiring lead-in, etc. Thus, we ask that the final noise level be confirmed by the machine manufacturer.

The pages related to the C6/C64 excerpted from the "EMC Installation Guidelines BNP-B2230" are provided in this section. Refer to the "EMC Installation Guidelines [BNP-B8582-45]" for details on the drive section (servo drive unit/spindle drive unit).

APPENDIX 9 EMC INSTALLATION GUIDELINES Appendix 9.2 EMC Directives

I - 105

Appendix 9.2 EMC Directives

The EMC Directives largely regulate the following two items.

Emission ..... Capacity to prevent output of obstructive noise that adversely affects external devices. Immunity ..... Capacity not to malfunction due to obstructive noise from external source.

The details of each level are classified below in Table 1. It is assumed that the Standards and test details required for a machine tool are the same as these.

Class Name Details EMC Standard

Radiated noise Restriction of electromagnetic noise radiated through the air

Emission Conductive noise Restriction of electromagnetic noise

discharged from power supply line

EN50081-2 EN61800-3 (Industrial environment)

EN55011 (CLASS:A)

Static electricity electrical discharge

Example) Regulation of withstand level of static electricity accumulated in human body

IEC61000-4-2

Radiation immunity Simulation of immunity from digital wireless telephones IEC61000-4-3

Burst immunity Example)

Regulation of withstand level of noise from relay or live wire being inserted or removed

IEC61000-4-4

Conductive immunity

Example) Regulation of withstand level of noise flowed from power supply wires, etc.

IEC61000-4-6

Power supply frequency magnetic field

Example) Regulation of electromagnetic noise of 50/60Hz power supply frequency

IEC61000-4-8

Power supply dip (fluctuation)

Example) Regulation of power voltage drop withstand level

IEC61000-4-11

Immunity

Surge Example)

Regulation of withstand level of noise caused by lightning

EN50082-2 EN61800-3 (Industrial environment)

IEC61000-4-5

APPENDIX 9 EMC INSTALLATION GUIDELINES Appendix 9.3 EMC Countermeasures

I - 106

Appendix 9.3 EMC Countermeasures

The main items relating to EMC countermeasures include the following. (1) Store the device in a sealed metal panel. (2) Ground all conductors that are floating electrically. Decrease the impedance. (3) Increase the distance between the drive line and signal wire. (4) Shield the cables wired outside of the panel. (5) Install a noise filter.

Take care the following items to suppress the noise radiated outside of the panel. (1) Accurately ground the devices. (2) Use shielded cables. (3) Increase the electrical seal of the panel. Reduce the gaps and holes.

APPENDIX 9 EMC INSTALLATION GUIDELINES Appendix 9.4 Panel Structure

I - 107

Appendix 9.4 Panel Structure

The design of the panel is a very important factor for the EMC countermeasures, so take the following countermeasures into consideration.

Appendix 9.4.1 Countermeasures for control panel body

(1) Use metal for all members configuring the panel.

(2) When joining the top plate and side plates, etc., treat the welded or contacting sections so that the impedance is reduced, and then fix with screws.

[CAUTION]

Using screws to fix the plates that have been painted is the same as an insulated state. Peel off the paint and fix the screws.

Plating mask

Joining clearance : Approx. 20cm

(3) Note that if the plate warps due to the screw fixing, etc., by that creating a clearance, noise could leak from that place.

(4) Plate (nickel, tin) the metal plate surface at the grounding plate, and connect the connections with

a low impedance.

(5) If there is a large opening, such as ventilation holes, make sure to close the hole.

Opening

Mesh cover (conductive sponge)

Control panel

APPENDIX 9 EMC INSTALLATION GUIDELINES Appendix 9.4 Panel Structure

I - 108

Appendix 9.4.2 Countermeasures for door

(1) Use metal for all members configuring the door.

(2) When joining the door, use a gasket to lower the impedance of the contacting sections, or use a structure with a large contact area as shown below.

a) Use of gasket

b) Large contact area

EMI gasket

Control panel

Door

Door

Contact area

Cross-section drawing

Control panel

(3) The EMI gasket or conductive packing must contact the metal surface uniformly and at the correct position.

[CAUTION] When not using a gasket, ground the control panel grounding with a grounding wire to

lower the door's impedance. Using screws to fix the plates that have been painted (attachment of packing) is the same

as an insulated state. Peel off the paint and fix the screws.

APPENDIX 9 EMC INSTALLATION GUIDELINES Appendix 9.4 Panel Structure

I - 109

Appendix 9.4.3 Countermeasures for power supply

(1) Shield the power supply section and insert a filter to prevent the noise from flowing in or out. Selection of the noise filter capacity will differ according to the drive amplifier and devices being used. Refer to the "EMC Installation Guidelines" NC Servo Amplifier Section [BNP-B8582-45].

Device

Radiated noise Flow out

(Fig.1)

NF Partition plate AC input

(Fig.2)

AC inputConductive noise

NF

Noise filter

Noise filter

Device

Radiated noise

Conductive noise

[CAUTION] The conductive noise can be suppressed just by inserting a noise filter, but the radiated

noise will flow out. (Fig. 1) The conductive and radiated noise can both be suppressed by adding a partition plate to

the noise filter. (Fig. 2)

APPENDIX 9 EMC INSTALLATION GUIDELINES Appendix 9.5 Countermeasures for Wiring in Panel

I - 110

Appendix 9.5 Countermeasures for Wiring in Panel

Cables act as antennas to propagate unnecessary noise, and thus must be appropriately shielded and treated. The following countermeasures must be sufficiently considered for the cables (FCUA-R000 /FCUA-R211) that carry out high-speed communication.

Appendix 9.5.1 Precautions for wiring in panel

(1) If the cables are led unnecessary in the panel, they will pick up noise. Thus, keep the wiring length as short as possible.

Device Device Device Device Device Device

Noise

(2) Always connect the grounding wire to the FG terminal indicated on the device.

(3) Keep the distance between the drive line and encoder cable to the drive section motor as far apart as possible when wiring.

(4) Do not lead the drive line around the panel without using a filter.

Noise filter

Noise

Noise Radiation

AC inputNF Partition

plate

Device

APPENDIX 9 EMC INSTALLATION GUIDELINES Appendix 9.5 Countermeasures for Wiring in Panel

I - 111

Appendix 9.5.2 NC Unit grounding wire Operation panel

Control panel

Control unit

FG cable FG cable 200VAC input

R220 cable

R000 cable

R220 cable (24VDC cable)

NC K/B

Keyboard unit FCUA-KB

R000 cable (for NC AMP)

Electric cabinets main grounding plate

BZ CR06

CR01

CR02

CNZ24

CR03

CNZ22

CR05 FG

FG cable FG cable

FG cable

Display unit FCU6-DU

24V D

C (+) 0V FG

FG cable

Short bar

MITSUBISHI

MELDAS C64

Stabilized power supply

APPENDIX 9 EMC INSTALLATION GUIDELINES Appendix 9.5 Countermeasures for Wiring in Panel

I - 112

Appendix 9.5.3 Shield treatment of cables

Use shielded cables for the cables wired outside the panel in the C6/C64 Series. Use a shield clamp (refer to 9.6.1) within 10cm of the lead-out port from the panel.

(1) DC power supply cable [FCUA-R220 cable]

Use a shield clamp within 10cm from the panel's inlet/outlet. Install a ferrite core on both ends of the connected units. Always install a ferrite core (refer to 9.6.2) on the stabilized power supply. (The ferrite core may not be required depending on the selected power supply.)

Operation panel Operation board unit Keyboard unit

Shield clamp

FCUA-R220 cable

Ferrite core

OUT

IN

General-purpose Stabilized power supply

Control panel

(2) Remote I/O cable [FCUA-R211 cable] Use a shield clamp within 10cm from the panel's inlet/outlet. Install a ferrite core on both ends of the connected units. The shield clamp and ferrite core are not required if the control unit and base I/O unit are wired

in the same panel.

Control panel

Control unit

Shield clamp

FCUA-R211 cable

Ferrite core

Remote I/O unit

Control panel

APPENDIX 9 EMC INSTALLATION GUIDELINES Appendix 9.5 Countermeasures for Wiring in Panel

I - 113

(3) Servo communication cable [FCUA-R000 cable] Use a shield clamp within 10cm from the panel's inlet/outlet. Install a ferrite core on both ends of the connected units. The shield clamp and ferrite core are not required if the control unit and drive section unit are

wired in the same panel.

Control panel

Drive section unit

Shield clamp

FCUA-R000 cable

Ferrite core

Control panel

Control unit

(4) Ethernet cable Use a shield clamp within 10cm from the panel's inlet/outlet. Install a ferrite core on both ends of the connected units. The shield clamp and ferrite core may not be required depending on the peripheral device.

Control panel

Control unit

Shield clamp

Ethernet cable

Ferrite core

Peripheral device

Control panel

APPENDIX 9 EMC INSTALLATION GUIDELINES Appendix 9.6 Parts for EMC Countermeasures

I - 114

Appendix 9.6 Parts for EMC Countermeasures Appendix 9.6.1 Shield clamp fitting

The effect can be enhanced by directly connecting the outer sheath of the cable to the grounding plate as shown below. Install the grounding plate near the outlet (within 10cm) of each panel, and press against the grounding plate with the clamp fitting. If the cables are thin, several can be bundled and clamped together. To provide sufficient frame grounding, install the grounding plate directly on the cabinet or connect with a grounding wire. If the grounding plate and clamp fitting set AERSBAN- SET is required, please contact Mitsubishi.

Clamp section drawing

Outline drawing

Peel off the cable sheath at the clamp section.

Grounding plate

Cable

Shield sheath

Clamp fitting (Fitting A,B)

2-5 hole Installation hole

17.5

M4 screw Note 1)

6 22 35

10 MAX L

Clamp fitting

Unit: mm

A

35

C

24 -0

.2

0

B 0

.3

6 3 7

11

30

24

0 +0

.3

Cable

40

Grounding plate

Note 1) Screw hole for wiring to cabinet's grounding plate. Note 2) The grounding plate thickness is 1.6mm.

A B C Enclosed fitting L

AERSBAN-DSET 100 86 30 Two A clamp fittings A clamp fitting 70 AERSBAN-ESET 70 56 One B clamp fitting B clamp fitting 45

APPENDIX 9 EMC INSTALLATION GUIDELINES Appendix 9.6 Parts for EMC Countermeasures

I - 115

Appendix 9.6.2 Ferrite core

The ferrite core is mounted integrally with the plastic case. This can be installed with one touch without cutting the interface cable or power supply cable. This ferrite core is effective against common mode noise, allowing countermeasures against noise without affecting the quality of the signal.

Recommended ferrite core

TDK ZCAT Series ZCAT3035-1330 (-BK)

D C

A B

D

TDK

E

D

C

C

D B

A

TDK

D

CB

A

TDK

A B

TDK

ZCAT type ZCAT-A,ZCAT-AP type

ZCAT-C type ZCAT-D type

Applicable cable thickness: 1.3mm max.

E

C

TDK

A B

ZCAT-B type

Part Name A B c d E Applicable cable

outer diameter Weight (g)

ZCAT1518-0730-M (-BK) *1 221 181 71 151 7max. 6 ZCAT1518-0730 (BK) *2 221 181 71 151 7max. 6 ZCAT2017-0930-M (-BK) 211 171 91 201 9max. 11 ZCAT2032-0930-M (-BK) *1 361 321 91 19.51 9max. 22 ZCAT2032-0930 (-BK) *2 361 321 91 19.51 9max. 22 ZCAT2132-1130-M (-BK) *1 361 321 111 20.51 11max. 22 ZCAT2132-1130 (-BK) *2 361 321 111 20.51 11max. 22 ZCAT3035-1330-M (-BK) *1 391 341 131 301 13max. 63 ZCAT3035-1330 (-BK) *2 391 341 131 301 13max. 63 ZCAT1525-0430AP-M (-BK) 251 201 41 151 11.51 2.5 to 4 (USB) 7 ZCAT1325-0530A-M (-BK) *1 251 201 51 12.81 11.21 3~5 (USB) 7 ZCAT1325-0530A (-BK) 251 201 51 12.81 11.21 3~5 (USB) 7 ZCAT1730-0730A-M (-BK) 301 231 71 16.51 151 4~7 (USB/IEE1394) 12 ZCAT2035-0930A-M (-BK) *1 351 281 91 19.51 17.41 6~9 22 ZCAT2035-0930A (-BK) 351 281 91 19.51 17.41 6~9 22 ZCAT2235-1030A-M (-BK) 351 281 101 21.51 201 8~10 27 ZCAT2436-1330A-M (-BK) 361 291 131 23.51 221 10~13 29 ZCAT2017-0930B-M (-BK) 211 171 91 201 28.51 9max. 12 ZCAT2749-0430-M (-BK) 491 271 4.51 19.51 4.5max. 26 ZCAT4625-3430D (-BK) 45.51 24.51 341 121 For 26-core flat cable 32 ZCAT4625-3430DT (-BK)*3 45.51 24.51 341 121 For 26-core flat cable 32 ZCAT6819-5230D (-BK) 67.51 18.51 521 161 For 40-core flat cable 58 ZCAT6819-5230DT (-BK)*3 67.51 18.51 521 171 For 40-core flat cable 58

ZCAT-C type, ZCAT-D type *1. The M stamp is attached. *2. A fixing band is attached at shipment. *3. Specifications for fixing with double-sided tape. (Tape attached when shipped from factory.)

ZCAT-B type: Cabinet fixing type installation hole 4.8 to 4.9mm, plate thickness 0.5 to 2mm ZCAT-AP, ZCAT-C types: Structure that prevents easy opening after case is closed.

APPENDIX 9 EMC INSTALLATION GUIDELINES Appendix 9.6 Parts for EMC Countermeasures

I - 116

Appendix 9.6.3 Surge protector

(1) Surge absorber Make sure that surge does not directly enter the AC line of the general-purpose stabilized power supply (prepared by user) supplied to the control unit and DIO. The following product or equivalent is recommended for the surge killer.

(1) Part name : RAV-781BYZ-2

Manufacturer : Okatani Denki Sangyo

Circuit voltage 50/60Hz Vrms

Max. tolerable circuit voltage

Clamp voltage V 10%

Surge resistance

level 8/20s

Surge withstand

voltage 1.2/50s

Static capacity

Working temperature

range

250V 3 300V 783V 2500A 20kV 75pF 20C to +70C

20 0

30 0

Outline drawing

UL-1015 AWG16

4. 5

0. 5

Unit: mm

(1) Black (2) Black (3) Black

Circuit drawing

28 1

11 1

5. 5

1

28 .5 1

411

* Refer to the manufacturer's catalog for detailed characteristics, outline and connection methods

of the surge absorber.

APPENDIX 9 EMC INSTALLATION GUIDELINES Appendix 9.6 Parts for EMC Countermeasures

I - 117

(2) Part name : RAV-781BYZ-4 Manufacturer : Okatani Denki Sangyo

Circuit voltage 50/60Hz Vrms

Max. tolerable circuit voltage

Clamp voltage V 10%

Surge resistance

level 8/20s

Surge withstand

voltage 1.2/50s

Static capacity

Working temperature

range

250V 3 300V 700V 2500A 2kV 75pF 20C to +70C

Green

UL-1015 AWG16

4. 5

0. 5

Unit: mm

(1) Black (2) Black (3) Black

Circuit drawing

11 1

5. 5

1

28 .5 1

28

1

20 0

30 0

411

Outline drawing

* Refer to the manufacturer's catalog for detailed characteristics, outline and connection methods

of the surge absorber.

APPENDIX 9 EMC INSTALLATION GUIDELINES Appendix 9.6 Parts for EMC Countermeasures

I - 118

(2) Example of surge absorber installation

Example of surge absorber installation

Control panel (Relay panel, etc.)

Surge absorber (2) Surge absorber (1)

Earth leakage breaker for panel

Input 200V/ 230VAC

No-fuse breaker

No-fuse breaker MC Reactor

Transformer

Circuit protector

Grounding Grounding

From power supply

C

BA

NC drive section

Other devices (power supply for panel, etc.)

Other devices (panel power supply, etc.)

NC control section

Precautions (1) Thick wiring enhances the lightning surge absorption effect, so make the wiring se as thick and

short as possible. Wire material : Wire diameter 2mm2 or more Wire length : Connection to surge absorber (1): Wire length (A) is 2m or less Connection to surge absorber (2): Wire length (B) is 2m or less Grounding to surge absorber (2) : Wire length (C) is 2m or less

(2) When carrying out a withstand voltage test by applying an overvoltage on the power line, remove surge absorber (2) as it will activate with the applied voltage.

(3) A short-circuit fault will occur if a surge exceeding the tolerance is applied on the surge absorber. Thus, always insert a circuit protector to protect the power supply line.

A current does not flow to surge absorber (1) and (2) during normal use, so the circuit protector can be shared with other devices.

APPENDIX 9 EMC INSTALLATION GUIDELINES Appendix 9.6 Parts for EMC Countermeasures

I - 119

Appendix 9.6.4 Selection of stabilized power supply

Consider the following characteristics when selecting the stabilized power supply (prepared by user). Use a power supply that complies with CE Marking or that follows the Safety Standards given below.

Stabilized power supply selection items

Item Conditions

Voltage fluctuation 5% 5% or less of 24VDC output

Ripple noise Max. 120mV 5% or less of 24VDC output Output

Spike noise Max. 500mV

Output current Refer to the Connection Manual and calculate.

Output holding time Min. 20ms Instantaneous OFF time

Standards Safety Standards : UL1950, CSA C22.2 No. 234 approved, IEC950 compliant Noise Terminal Voltage : FCC Class A, VCCI-1 Class High Harmonics Current Restrictions : IEC1000-3-2

II. Maintenance Manual

1. OUTLINE 1.1 Table of Configuration Lists

II - 1

1. OUTLINE 1.1 Table of Configuration Lists

The C6/C64 control unit is configured of the following modules.

Module configuration table

No. Type Configuration module type Function Remarks

HR851 card Main CPU card HR899 card IC Card interface card HR891 card Back panel

109P0424H702 DC fan Mounted on main CPU card

ER6 BKO-NC2157H01 Battery Mounted on main CPU card

F300 cable DC24VIN-HR851 F400 cable HR899-HR851 Base Aluminum die-cast Frame Molded resin part Front panel Molded resin part Clear cover Molded resin part Card installation fitting FG fitting

1 Control unit FCU6-MU042

(C64) FCU6-MU043

(C6)

Insulation sheet

FCU6-HR881 Extension DIO card (Sink type) HR881 card

FCU6-HR882 Extension DIO card (Sink type, with AO) HR882 card

FCU6-HR883 Extension DIO card (Source type) HR883 card

FCU6-HR884 Extension DIO card (Source type, with AO) HR884 card

FCU6-EX875 Ethernet HR875/876 card FCU6-EX878 MELSECNET/10 (Coaxial) HR877/878 card FCU6-EX879 MELSECNET/10 (Optical) HR877/879 card FCU6-HR865 CC-Link HR865 card

2 Extension unit (option)

FCU6-EX871-40 DeviceNet HR871 card

1. OUTLINE 1.2 Control Section Module Configuration

II - 2

1.2 Control Section Module Configuration

Front panel Clear cover

F300 cable

HR899 card

R400 cable

Card installation fitting

Fan

Frame

FG fitting

Base

Extension card

Extension panel

Card Puller

Insulation sheet

HR891 card

HR851 card

2. EXPLANATION OF MODULE FUNCTIONS 2.1 HR851 Card

II - 3

2. EXPLANATION OF MODULE FUNCTIONS 2.1 HR851 Card

[Block diagram]

RISC DRAM

SRAMFLROM RTC

Cassette memory (For maintenance)

External power supply 24VDC/3A

External I/O interface

RTBUS

CPU peripheral control PLC operation

Power supply circuit (DC/DC)

Battery 3.6V

TERMINAL HANDLE ENC

SV2 RIO-M/SRIO-M DIOSKIP SIO SV1

B AT

D

C IN

+5V

+3.3V

+12V

ICCARD CBUS

[Explanation of functions] The HR851 card functions as the main CPU.

CPU 64-bit RISC chip ASIC CPU peripheral control & PLC operation External I/O interface Memory DRAM For system working FLROM For system ROM & BootROM SRAM For processing program and parameter backup Cassette I/F CBUS connector For cassette memory (for maintenance) RT bus RTBUS connector For back panel connection I/O interface SV1, SV2 connector Servo amplifier connection : 2 systems ENC connector Encoder connection : 2ch HANDLE connector Handle connection : 3ch SIO connector RS-232C: 1ch, RS422: 1ch TERMINAL connector Operation board connection SKIP connector Skip signal connection : 4 points DIO connector Input: 16 points, output: 1 point RIO-M connector Remote IO master station RIO-M/S connector Remote IO master/slave station Power supply DC24IN connector Input : 24VDC5%: 3A Output : 3.3VDC, 5VDC, 12VDC BAT connector For lithium battery connection

2. EXPLANATION OF MODULE FUNCTIONS 2.1 HR851 Card

II - 4

[Connector layout diagram]

FAN

CS1

ICCARD RTBUS DC24IN

TEST

RIO-M/S

ISP

RIO-M

CBUS

SW2 DIO NCRST

LED3 SKIP

U:TERMINAL L:SIO

U:HANDLE L:ENC

U:SV2 L:SV1

LED4

TEST : Connector for maintenance and service NCRST : NC reset (do not press during normal system operation)

[Explanation of settings] CS1: System mode selection rotary switch

Switch Mode Details 0 Standard mode Operation of system 1 1 PLC stop The system is started while the PLC is stopped. 2 3 4 5 6 7

Maintenance mode

8 9 A B C D E F

Maintenance mode (The cassette memory must be connected to the CBUS connector.)

[Explanation of LEDs] LED3 : (Green) DC power being output (Red) Battery low warning LED4 : (Green) SA (servo READY) being output (Red) Watch dog error

2. EXPLANATION OF MODULE FUNCTIONS 2.2 HR899 Card

II - 5

2.2 HR899 Card

[Block diagram]

ICCARD SLOT

[Explanation of functions]

The HR899 card functions as the IC Card interface.

[Connector layout diagram]

SLOT ICCARD

HR851 card

2. EXPLANATION OF MODULE FUNCTIONS 2.3 HR891 Card

II - 6

2.3 HR891 Card

[Block diagram]

RTBUS

For HR851 card connection

For extension card connection

For extension card connection

For extension back panel connection

RT2 RT1 EXRT

[Explanation of functions]

The HR891 card functions as the control unit's back panel.

[Connector layout diagram]

RTBUS RT2

RT1 EXRT

2. EXPLANATION OF MODULE FUNCTIONS 2.4 HR881/882/883/884 Card

II - 7

2.4 HR881/882/883/884 Card

[Block diagram]

RTBUS

DI

DO

MAC303

DI I/F

DO I/F

Connect to control units back panel

MAC303 AO I/F

Machine input 32 points

Machine output 32 points

[Explanation of functions]

The HR881/882/883/884 card functions as the control unit built-in extension DIO. MAC303 Remote I/O controller Machine input interface DI connector Insulation type 32 points Machine output interface DO connector Non-insulated type 32 points HR881/882 Sink specifications HR883/884 Source specifications Analog output interface DO connector 1 point (HR882/884)

[Connector layout diagram]

LED1

U: DI L: DO

LED2 RTBUS

[Explanation of LEDs] LED1 : (Green) 15VDC being output (Red) RIO 1st station communication alarm LED2 : (Green) 15VDC being output (Red) RIO 2nd station communication alarm

2. EXPLANATION OF MODULE FUNCTIONS 2.5 HR875/876 Card

II - 8

2.5 HR875/876 Card

[Block diagram]

RTBUS

Connect to control units back panel

Ethernet Controller

EEPROM

PLD

Trans- former

P C

IE X

T

E XT

PC I2

ETHERNET

Add-on connector

Modular jack

HR875

S R A M AM

HR876

SRAM

Physical layer Transceiver

Twisted pair cable

[Explanation of functions] The HR875/876 card functions as the 10Base-T Ethernet. Bus conversion section (Base PCB ... HR875)

Memory SRAM Add-on connector

Ethernet interface section (Add-on PCB ... HR876) Ethernet Controller Physical Layer Transceiver Transformer Modular jack Add-on connector Memory SRAM EEPROM Monitor LED

[Connector layout diagram]

C O

L S

P E

E D

LI N

K

RTBUS

FD P

O L

ISP

PCIEXT/EXTPCI2

HR875

RX TX

ETHERNET HR876

[Explanation of LEDs] RX : (Green) ON when receiving packet TX : (Green) ON when transmitting packet COL : (Green) ON when collision occurs SPEED : (Green) ON during 100Base-T communication (always OFF) LINK : (Green) ON when mutual communication is possible FDPOL : (Green) ON during full-duplex communication

2. EXPLANATION OF MODULE FUNCTIONS 2.6 HR877/878 Card

II - 9

2.6 HR877/878 Card

[Block diagram]

RTBUS

Buff

PLD

HR877 HR878

Rotary switch, setting, etc.

System ROM Work RAM

16-bit bus Add-on connectorGate array for

bus I/F

2-port RAM

MDP:Mitsubishi DataLink Processer

MPU MDP1*

Gate array for transmission I/F

LED

ENCO/DECO

Tr/Re

Medium I/F Coaxial cable

[Explanation of functions] The HR877/878 card functions as the MELSECNET/10 (coaxial bus interface).

Sections common for coaxial and optical use (Base PCB ... HR877) ASIC Gate array for bus interface Memory 2-port RAM Work RAM System ROM Add-on connector Various setting switches

Sections dedicated for coaxial bus interface (Add-on PCB ... HR878)

MPU ASIC Gate array for transmission I/F ENCO/DECO Tr/Re Coaxial medium interface Monitor LED

2. EXPLANATION OF MODULE FUNCTIONS 2.6 HR877/878 Card

II - 10

[Connector layout diagram]

NETWORK x 100 x 10 x 10 x 1x 1

GROUP STATION DIPSW

MODE

ISP

[Explanation of settings]

NETWORK : Network No. setting switch Set the network number between 1 and 239 with the three rotary switches. The I/F board group No. is the number used when setting the local station network number if connecting to MELSECNET/10.

100 switch : Set the 100th place of the network number. 10 switch : Set the 10th place of the network number. 1 switch : Set the 1st place of the network number.

Set within the range of 1 to 239. (Default setting 100: 0 10: 0 1: 1)

GROUP : Group No. setting switch Set the group number with the rotary switch. The I/F board group No. is the number used when setting the local stations' group No. if connecting to MELSECNET/10. Set within the range of 1 to 9. 0 means that no group is designated. (Default setting: 0)

STATION : Station number setting switch Set the station numbers between 01 and 64 with the two rotary switches. The I/F board group No. is the number used when setting the local station number (normal station) if connecting to MELSECNET/10.

10 switch : Set the 10th place of the station number. 1 switch : Set the 1st place of the station number.

Set within the range of 1 to 64. (Default setting 10: 0 1: 1)

MODE : Mode setting switch 0: Online (automatic parallel-off valid) 1: Online (automatic parallel-off invalid) OFF ON 2: Offline SW1 : PC-PC network Remote I/O network 3 to 9: Test mode SW2 : Normal station Control station D: Network No. confirmation SW3 : Common parameter Default parameter E: Group No. confirmation SW4, 5 : Number of stations F: Station No. confirmation off, off on, off off, on on, on 8 stations 16 stations 32 stations 64 stations SW6, 7 : Size off, off on, off off, on on, on 2K point 4K point 6K point 8K point

(Default setting: 0) DIPSW : Network condition setting

This switch is used to set the MELSECNET/10 operation conditions. This switch is not used currently. (Always OFF) (Default setting: All OFF)

[Explanation of LEDs]

RUN : (Green) ON when normal ERR. : (Red) ON when hardware error occurs SD : (Green) ON during transmission RD : (Green) ON during reception

2. EXPLANATION OF MODULE FUNCTIONS 2.7 HR877/879 Card

II - 11

2.7 HR877/879 Card

[Block diagram]

RTBUS

Buff

PLD

HR877 HR879

Rotary switch, setting, etc.

System ROM Work RAM

16-bit bus Add-on connectorGate array for

bus I/F

2-port RAM

MDP:Mitsubishi DataLink Processer

MPU MDP2*

Optical fiber cable

Gate array for transmission I/F

HR879: SI type (500m between stations)

Medium I/F

Medium I/F

LED

[Explanation of functions] HR877/879 functions as MELSECNET/10 (optical loop interface).

Sections common for coaxial and optical use (Base PCB ... HR877) ASIC Gate array for bus interface Memory 2-port RAM Work RAM System ROM Add-on connector Various setting switches

Section dedicated for optical loop interface (Add-on PCB ... HR879)

MPU ASIC Gate array for transmission I/F Optic medium I/F SI type (500m between stations) Monitor LED

2. EXPLANATION OF MODULE FUNCTIONS 2.7 HR877/879 Card

II - 12

[Connector layout diagram]

OUT

IN

T

R

T

R

NETWORK x 100 x 10 x 10 x 1x 1

GROUP STATION DIPSW

MODE

ISP

[Explanation of settings]

NETWORK : Network No. setting switch Set the network number between 1 and 239 with the three rotary switches. The I/F board group No. is the number used when setting the local station network number if connecting to MELSECNET/10.

100 switch : Set the 100th place of the network number. 10 switch : Set the 10th place of the network number. 1 switch : Set the 1st place of the network number.

Set within the range of 1 to 239. (Default setting 100: 0 10: 0 1: 1)

GROUP : Group No. setting switch Set the group number with the rotary switch. The I/F board group No. is the number used when setting the local stations' group No. if connecting to MELSECNET/10. Set within the range of 1 to 9. 0 means that no group is designated. (Default setting: 0)

STATION : Station number setting switch Set the station numbers between 01 and 64 with the two rotary switches. The I/F board group No. is the number used when setting the local station number (normal station) if connecting to MELSECNET/10.

10 switch : Set the 10th place of the station number. 1 switch : Set the 1st place of the station number.

Set within the range of 1 to 64. (Default setting 10: 0 1: 1)

MODE : Mode setting switch 0: Online (automatic parallel-off valid) 1: Online (automatic parallel-off invalid) OFF ON 2: Offline SW1 : PC-PC network Remote I/O network 3 to 9: Test mode SW2 : Normal station Control station D: Network No. confirmation SW3 : Common parameter Default parameter E: Group No. confirmation SW4, 5 : Number of stations F: Station No. confirmation off, off on, off off, on on, on 8 stations 16 stations 32 stations 64 stations SW6, 7 : Size off, off on, off off, on on, on 2K point 4K point 6K point 8K point

(Default setting: 0) DIPSW : Network condition setting

This switch is used to set the MELSECNET/10 operation conditions. This switch is not used currently. (Always OFF) (Default setting: All OFF)

[Explanation of LEDs] RUN : (Green) ON when normal F.ERR : (Red) ON when main (forward) loop hardware error occurs R.ERR : (Red) ON when sub (reverse) loop hardware error occurs F.SD : (Green) ON during main (forward) loop transmission F.RD : (Green) ON during main (forward) loop reception R.SD : (Green) ON during sub (reverse) loop transmission R.RD : (Green) ON during sub (reveres) loop reception

2. EXPLANATION OF MODULE FUNCTIONS 2.8 HR865 Card

II - 13

2.8 HR865 Card

[Block diagram]

Rotary switch, setting, etc.

EEPROM

SRAM

CPU CC-Link master gate array

RTBUS

2-port RAM

OI

Gate array for bus I/F

DC/DC

Terminal block

PLD

PROM

[Explanation of functions] The HR865 card functions as the CC-Link's master/local station. CPU 16bitCPU ASIC Gate array for bus interface CC-Link master gate array Memory 2-port RAM SRAM System ROM PROM Work RAM SRAM EEPROM Various setting switches LED

[Connector layout diagram]

RTBUS

STATION NO. B_RATE

10 1

TE 1

M O

D E

LE D

1

2. EXPLANATION OF MODULE FUNCTIONS 2.8 HR865 Card

II - 14

[Explanation of settings] MODE : Mode setting switch

Set the unit's operation state (Default setting: 0) Master station Local station 0 : Online (remote net mode) Possible Possible 1 : Online (remote I/O net mode) Possible Not possible 2 : Offline Possible Possible 3 : Line test 1 Possible Not possible 4 : Line test 2 Possible Not possible 5 : Parameter confirmation test Possible Not possible 6 : Hardware test Possible Possible 7 to F: Not usable

STATION NO. : Station number setting switch

Set the unit's station No. (Default setting: 0)

During remote net mode Master station: 0 Local station: 1 to 64 Standby master station: 1 to 64 (If a value other than 0 to 64 is set, the "SW" and "L ERR." LEDs will light.) During remote I/O net mode Master station: 1 to 64 (set station number of final remote I/O station) (If 0 is set, the "PLM" LED will light.)

B RATE : Transmission speed setting switch

Set the unit's transmission speed. (Default setting: 0)

0 : 156kbps 1 : 625kbps 2 : 2.5Mbps 3 : 5Mbps 4 : 10Mbps 5 to 9 : Setting error ("SW" and "L ERR." LEDs light)

DIPSW (SW5) : Condition setting switch

Set the operation conditions (Default setting: All OFF)

SW1 Station type OFF: Master station/local station ON: Standby master station SW2 Use not possible Always OFF SW3 Use not possible Always OFF SW4 State of input data in OFF: Clear data link error station ON: Hold SW5, 6 Number of occupied stations SW5 SW6 OFF OFF : Station 1 OFF ON : Station 2 ON ON : Station 3 ON OFF : Station 4 SW7 Use not possible Always OFF SW8 Use not possible Always OFF

2. EXPLANATION OF MODULE FUNCTIONS 2.8 HR865 Card

II - 15

[Explanation of LEDs]

L1 L2 L3 L4 L5 L6 L7 L8

R1 R2 R3 R4 R5 R6 R7 R8

LED display status Master station

(Standby master station)

Local station (Standby master

station) LED name Details

When normal

When abnormal

When normal

When abnormal

L1 RUN ON : Unit is normal OFF : Watch dog timer error has occurred.

ON OFF ON OFF

L2 ERR.

Indicates the state of communication with station set in parameters. ON : Error in communication with all

stations Flicker : Station with communication error

round

OFF ON/flicker OFF ON/flicker

L3 MST ON : Set as master station ON OFF

L4 S MST ON : Set as standby master station ON ON

L5 LOCAL ON : Set as local station OFF ON

L6 CPU R/W ON : Communicating with NC CPU (FROM/TO) ON OFF ON OFF

L7 L RUN ON : Executing data link (local station) ON OFF ON OFF

L8 L ERR.

ON : Communication error (local station)

Flicker : Switch setting was changed while power is ON

OFF ON/flicker OFF ON/flicker

R1 SW ON : Switch setting is incorrect OFF ON OFF ON

R2 M/S ON : A master station already exists on same line OFF ON

R3 PRM ON : Error found in parameter details OFF ON

R4 TIME ON : Data link monitor timer functioned (all-station error) OFF ON

R5

E R R O R

LINE ON : Cable is broken or transmission path is being affected by noise, etc. OFF ON OFF ON

R6

R7 SD ON : Sending data ON OFF ON OFF

R8 RD ON : Receiving data ON OFF ON OFF

2. EXPLANATION OF MODULE FUNCTIONS 2.9 HR871 Card

II - 16

2.9 HR871 Card

[Block diagram]

R S 2 3 2 C

RTBUS

PLD

EEPROM

DeviceNet master module

STA1,STA2

LED

DPORT DNET SIO

R S2

32 C

D

N M

[Explanation of functions] The HR871 card functions as the DeviceNet master when the DeviceNet master module is added on. Memory EEPROM Add-on connector Communication connector RS-232C connector for configuration Monitor LED

[Connector layout diagram]

MS

NS

RTBUS

RUN RDY

DNET SIO

DPORT

STA2 STA1

D N

M

ISP

R S

23 2

[Explanation of LEDs] RUN : (Green) ON during communication RDY : (Green) ON when hardware is correct MS : (Green) ON during communication NS : (Green) ON during communication : (Red) ON when duplicate station No. setting occurs or bus off error occurs

3. TROUBLESHOOTING 3.1 List of Unit LEDs

II - 17

3. TROUBLESHOOTING 3.1 List of Unit LEDs

SKIP

D IO

E X

T2

SERVO1

E X

T1

M A

IN TE

N A

N C

E

LED1 LED2

ENC HANDLE

SIO TERMINAL

IC CARD

DC24V IN SERVO2

LED1

LED2

DCOUT (Green) BTAL (Red)

SRDY (Green) WDAL (Red)

[Explanation of LED functions]

Status Name Function Color When normal During error Correspondence for error

LED1 LED2

7-segment system status display Red Follows system status Refer to section 3.2.2 (2).

DCOUT During internal power output Green Lit Not lit Refer to section 3.2.2 (1).

BTAL Battery drop warning Red Not lit Lit Refer to section 3.2.2 (1). SRDY Servo READY (SA) Green Lit Not lit Refer to section 3.2.2 (2). WDAL Watch dog error Red Not lit Lit Refer to section 3.2.2 (2).

3. TROUBLESHOOTING 3.2 Troubleshooting

II - 18

3.2 Troubleshooting 3.2.1 Confirmation of trouble state

Confirm "when", "when doing what", and "what kind of" trouble occurred.

(1) When?

What time did the trouble occur?

(2) When doing what?

What was the NC operation mode?

During automatic operation ......... Program No., sequence No. and program details when the trouble occurred.

During manual operation ............. What was the manual operation mode? What was the operation procedure? What were the previous and next steps?

What was the setting and display unit screen? Did the trouble occur during input/output operations? What was the machine side state? Did the trouble occur while replacing the tools? Did hunting occur in the control axis?

(3) What kind of trouble?

What was displayed on the setting and display unit's Alarm Diagnosis screen? Display the Alarm Diagnosis screen, and check the alarm details. What was displayed for the machine sequence alarm? Is the LCD screen normal?

(4) How frequently?

When did the trouble occur? What was the frequency? (Does it occur when other machines are operating?) If the trouble occurs infrequently or if it occurs during the operation of another machine, there may be an error in the power voltage or the trouble may be caused by noise, etc. Check whether the power voltage is normal (does it drop momentarily when other machines are operating?), and whether noise measures have been taken.

Does the trouble occur during a specific mode? Does the trouble occur when the overhead crane is operating? What is the frequency in the same workpiece? Check whether the same trouble can be repeated during the same operation. Check whether the same trouble occurs when the conditions are changed. (Try changing the

override, program details, and operation procedures, etc.) What is the ambient temperature? (Was there a sudden change in the temperature? Was the fan at the top of the control unit

rotating?) Is there any contact defect or insulation defect in the cables? (Has any oil or cutting water splattered onto the cables?)

3. TROUBLESHOOTING 3.2 Troubleshooting

II - 19

3.2.2 When in trouble If the system does not operate as planned or if there is any trouble in the operation, confirm the following points and then contact the Mitsubishi Service Center.

Examples of trouble

The power does not turn ON. The power turns OFF suddenly. Nothing appears in the screen. The operation keys do not function. Machining operation is not possible.

3. TROUBLESHOOTING 3.2 Troubleshooting

II - 20

(1) Problems related to the power supply

The power does not turn ON.

Cause Remedy The door interlock is applied. If the control panel door is not completely closed, close it. If

the door interlock is applied even when the door is closed, the door interlock circuit is damaged.

The external power supply's input voltage is not as specified.

Check that the input voltage is within 200 to 230VAC +10 to 15%.

The external power supply is faulty.

Check that the power can be turned ON with the external power supply only. Note) Depending on the external power supply, the power

may not turn ON in the no-load state, so install a slight load and check.

The external power turns ON but the NC control power does not turn ON.

Cause Remedy The external power supply output

is not correct. Disconnect the cable between the NC unit and the external power supply, and check that the external power supply output is normal.

The power cable is disconnected or broken.

Check the cable connected between the NC unit and external power supply, and securely insert it. Check that the cable is not broken, and replace if broken.

The cable connected from the NC unit to the peripheral device is short-circuited.

Disconnect the cable connected to the peripheral device one at a time and check that the power turns ON. Check that there are no short-circuited cables.

There is a short circuit in the configuration card.

Remove the removable cards one at a time and check that the power turns ON. Check that there are no short-circuited cards.

CAUTION

Do not apply voltages other than those indicated in this manual on the connector. Doing so may lead to destruction or damage.

Incorrect connections may damage the devices, so connect the cables to the specified connectors.

Do not connect or disconnect the connection cables between each unit while the power is ON.

Do not connect or disconnect the PCBs while the power is ON.

3. TROUBLESHOOTING 3.2 Troubleshooting

II - 21

The power turns OFF.

Cause Remedy There is a problem in the power

supply. Check whether the voltage fluctuates at certain time zones. Check whether an instantaneous power failure has occurred.

A problem occurs when the peripheral device starts operating.

Check whether the voltage drops instantaneously when the peripheral device operation starts.

The BTAL (red) LED on the control unit lights.

Cause Remedy This lights when the voltage of

the battery connected to the BAT connector drops to 2.6V or less.

Replace the battery following the procedures given in section 4.3.2 (1).

(2) Problems when starting the system

The NC does not start up correctly.

Cause Remedy 8 is displayed on the control unit

7-segment display LED1 (left side).

Check that the rotary switch CS1 (left side) is set to 0.

E or F is displayed on the control unit 7-segment display LED1 (left side).

Contact the Mitsubishi Service Center.

The WDAL (red) LED on the control unit lights.

Contact the Mitsubishi Service Center.

Servo READY (SA) does not turn ON.

Cause Remedy The SRDY (green) LED on the

control unit is not lit. Check the emergency stop conditions.

The SRDY (green) LED on the control unit is lit.

Check that the wiring past the DIO connector is correct. (Check the relay coil's diode connection, etc.) If there is no output even when the wiring is corrected, the control unit may be faulty. Check the voltage with a tester. (The voltage is correct if it is approx. 24V across the relay coil end or connector DIO's 1B pin (+) and 1A pin () when the LED is lit.)

CAUTION

Do not apply voltages other than those indicated in this manual on the connector. Doing so may lead to destruction or damage.

Incorrect connections may damage the devices, so connect the cables to the specified connectors.

Do not connect or disconnect the connection cables between each unit while the power is ON.

Do not connect or disconnect the PCBs while the power is ON.

3. TROUBLESHOOTING 3.2 Troubleshooting

II - 22

(3) Problems related to remote I/O

The communication alarm LED ALM (red) lights.

Cause Remedy The remote connection cable is

not connected. The cable is disconnected or has a connector contact fault.

Check the connection of the R211 cable between the NC control section and remote I/O unit.

The remote I/O unit is faulty. Contact the Mitsubishi Service Center, and then replace the card.

The power system LED POWER (green) turns OFF.

Cause Remedy The input power is not being

supplied. Supply a +24V5% voltage to the Remote I/O unit.

(The input power is not within the tolerable range, or the internal power is faulty.)

Check that the input voltage is not +20V or less. If it is being supplied correctly, contact the Mitsubishi Service Center.

(4) Problems related to Ethernet

A communication error message is appeared on the display, and the communication LEDs RX (green) and TX (green) turn OFF. In other cases, a communication error message is appeared on the display, and after the OK button is pressed, the communication error message appears again and the communication LEDs RX (green) and TX (green) turn OFF.

Cause Remedy The Ethernet cable is not

connected, is broken, or there is a contact fault at the connector.

Check the cable connected between the NC control unit and display.

A straight type Ethernet cable is in use.

Use a cross type Ethernet cable.

The Ethernet unit is not inserted to the very back.

Insert the Ethernet unit so that the plate is flush with the front panel.

The Ethernet unit is faulty. Contact the Mitsubishi Service Center and replace the unit.

CAUTION

Do not apply voltages other than those indicated in this manual on the connector. Doing so may lead to destruction or damage.

Incorrect connections may damage the devices, so connect the cables to the specified connectors.

Do not connect or disconnect the connection cables between each unit while the power is ON.

Do not connect or disconnect the PCBs while the power is ON.

4. DAILY MAINTENANCE AND PERIODIC INSPECTION AND MAINTENANCE 4.1 Maintenance Tools

II - 23

4. DAILY MAINTENANCE AND PERIODIC INSPECTION AND MAINTENANCE

4.1 Maintenance Tools (1) Measuring instruments

The following measuring instruments are used to confirm that the voltage is being supplied correctly to the NC unit, to confirm that the wiring to the NC unit is correct, and to carry out simple troubleshooting.

Table 2.1 Maintenance tools Tool Condition Application

Tester To check that the wiring to the NC unit is correct before turning the power ON.

AC voltmeter Measure the AC power voltage. The tolerable error is 2% or less.

To measure the AC power voltage being supplied to the external 24VDC power supply unit.

DC voltmeter Max. scale 30V. The tolerable error is 2% or less.

To measure the DC power voltage. External power supply 24V (control section, machine input/output interface) Battery voltage HR851 SA output

Synchroscope General measurement and simple troubleshooting

Note 1) Currently, a high precision digital multi-meter is commonly used as a tester. This digital multi-meter can be used as both an AC voltmeter and a DC voltmeter.

(2) Tools

Screwdriver (large, medium, small) Radio pliers

4.2 Maintenance Items

Maintenance is categorized into daily maintenance items (items to be carried at set intervals) and periodic maintenance (replacement of parts when life is reached). Some parts will not function in a hardware manner when the life is reached, so these should be replaced before the life is reached.

Table 2.2 List of maintenance items

Class Name Life Inspection/replacement Remarks Daily maintenance

Escutcheon (when using communication terminal)

Once/two months (Accordingly when dirty)

Refer to section 4.2.1.

Periodic maintenance

Battery (lithium battery)

Cumulative data holding time 45,000h

When battery drop caution alarm occurs (Guideline: approx. 5 years)

Refer to section 4.3.2 (1).

Cooling fan (control section)

30,000h Refer to left. Refer to section 4.3.2 (2).

LCD display unit (when using communication terminal)

10,000h (Specified by the power ON time that the brightness drops to less than 50%.)

Replace when backlight darkens.

Refer to section 4.2.2.

4. DAILY MAINTENANCE AND PERIODIC INSPECTION AND MAINTENANCE 4.2 Maintenance Items

II - 24

4.2.1 Escutcheon (1) Cleaning the escutcheon

1) Keep the rear side of the escutcheon as clean as possible. 2) Wipe the escutcheon with a soft, clean, dry cloth. If cleaning is still required, put some neutral

detergent on a cloth and wipe. Do not use alcohol, thinner, etc. 4.2.2 LCD Panel

(1) Handling the LCD panel (a) Precautions for use

1) The polarizing plate (display surface) of the LCD panel surface can be easily scratched, so be careful during handling.

2) Glass is used in the LCD panel. Be careful not to drop the LCD panel or allow it to hit hard objects, as the glass may chip or break.

3) The polarizing plate may be stained or discolored if drops of water, etc., adhere to it for long periods, so be sure to wipe off any moisture immediately.

4) Wipe off any dirt, dust, etc., on the polarizing plate using absorbent cotton or other soft cloth. 5) A CMOS LSI is used in the LCD panel, so be careful of static electricity when handling. 6) Never disassemble the LCD panel. Doing so will damage the panel.

(b) Precautions for storage 1) Do not store the LCD panel in locations having a high temperature or humidity. (Store within

the storage temperature range.) 2) When storing the LCD panel as an individual unit, be sure that other objects do not touch or

hit the polarizing plate (display surface). 3) When storing the LCD panel for extended periods, be sure to store in a dark place away from

exposure to direct sunlight or fluorescent light. (2) Other precautions for use (a) Backlight life

The life of the backlight is 25,000 hours/25C. (Time for luminance to drop to 50% of the initial value.) The backlight life is dependent on the temperature. The life tends to be shorter when used continuously at lower temperatures.

(b) Luminance start Due to the characteristics of the backlight, the luminance could drop slightly at lower temperatures. It will take approx.10 to 15 minutes for the luminance to reach the rated value after the power is turned ON.

(c) Unevenness, luminescent spots and irregularities Uneven brightness, small luminescent spots or small dark spots may appear on LCD, but this is not a fault.

(d) Contrast The contrast of STN method LCD panels changes with temperature fluctuation. If this happens and the panel is difficult to see, open the operation box door and adjust the contrast with the contrast adjustment potentiometer on the LCD signal interface PCB. When using the 10.4 LCD, the brightness can be adjusted with the parameter settings.

4.2.3 IC Card (1) Handling the IC card

The general handling methods for the IC card are described below. Refer to the instruction manual of the IC card used for details.

(a) Precautions for use 1) Insert the card in the correct direction. 2) Do not touch the connector area with the hands or metal. 3) Do not apply excessive force to the connector area. 4) Do not subject the card to bending or strong impacts. 5) Do not open the cover or disassemble the card. 6) Do not use the card in dusty locations.

(b) Precautions for storage 1) Do not store the card in locations having a high temperature or humidity. 2) Do not store the card in dusty locations.

4. DAILY MAINTENANCE AND PERIODIC INSPECTION AND MAINTENANCE 4.3 Replacement Methods

II - 25

4.3 Replacement Methods 4.3.1 Cable

If the cable is replaced without turning the power OFF, the normal unit or peripheral devices could be damaged, and risks could be imposed. Disconnect each cable with the following procedures.

(1) For the following type of connector, press the tabs with a thumb and forefinger in the direction of

the arrow, and pull the connector off.

(2) Pull

(1) Press

(2) Pull

Y

(1) Press

(2) Pull

(2) Pull

(1) Press

(1) Press

View from above

CAUTION

Do not connect or disconnect the connection cables between each unit while the power is ON.

Do not pull the cables when connecting/disconnecting it.

4. DAILY MAINTENANCE AND PERIODIC INSPECTION AND MAINTENANCE 4.3 Replacement Methods

II - 26

(2) For a flat cable type connector with latches, open the latches in the directions of the arrows, and pull the connector off.

(2) Pull

(1) Open

(3) For a flat cable type connector without latches, hold the connector with a thumb and forefinger, and pull the connector off.

(2) Pull

(1) Hold with thumb and forefinger.

(4) For the screw fixed type connector, loosen the two fixing screws, and pull the connector off.

(2) Pull (2) Pull

(1) Loosen

(1) Loosen

CAUTION

Do not connect or disconnect the connection cables between each unit while the power is ON.

Do not pull the cables when connecting/disconnecting it.

4. DAILY MAINTENANCE AND PERIODIC INSPECTION AND MAINTENANCE 4.3 Replacement Methods

II - 27

4.3.2 Durable parts (1) Battery

All data, such as the parameters and machining programs that need to be backed up when the power is turned OFF, are saved by a lithium battery installed in the control unit battery holder.

Battery ................................ With ER6 connector (Toshiba with Mitsubishi specifications) Initial battery voltage .......... 3.6V Voltage at which voltage .... 2.8V (Battery voltage drop caution alarm) drop is detected 2.6V (Battery voltage drop warning alarm) Battery cumulative data ...... 45,000 hours (At room temperature. The life will be shorter if the hold time temperature is high.) Battery life .......................... Approx. 5 years (from date of battery manufacture) Discharge current ............... 40A or less

(Replace the battery when the battery voltage drop warning alarm appears in the NC screen. The internal data could be damaged if the battery voltage drop warning alarm appears.) Always replace the battery with the control unit power turned OFF. Complete the replacement within 30 minutes after turning the power OFF. (If the battery is not connected within 30 minutes, the data being backed up will be destroyed.) (1) Confirm that the control unit power is OFF. (If the power is not OFF, turn it OFF.) (2) Open the upper front cover of the control unit. (3) Remove the battery from the battery holder. (4) Pullout the connector connected from the battery from the BAT connector. (5) Replace with a new battery, and connect the connection connector from the battery to the

BAT connector. (6) Fit the battery into the battery holder. (7) Close the front cover of the control unit.

SERVO1

LED1 LED2

ENC HANDLE

SIO TERMINAL

IC CARD

DC24V IN SERVO2

Control unit Front cover

BAT connector

Connection connector

Battery holder

Battery

Precautions for handling battery

Always replace the battery with the same type. Do not disassemble the battery. Do not place the battery in flames or water. Do not pressurize and deform the battery. This is a primary battery so do not charge it. Dispose of the spent battery as industrial waste.

CAUTION

If the battery voltage low warning alarm occurs, the program, tool data and parameters, etc., could be damaged. After replacing the battery, reload all data with the input/output device.

Do not replace the battery while the power is ON.

Do not short-circuit, charge, overheat, incinerate or disassemble the battery.

Dispose of the spent battery according to local laws.

4. DAILY MAINTENANCE AND PERIODIC INSPECTION AND MAINTENANCE 4.3 Replacement Methods

II - 28

(2) Cooling fan A fan is mounted on the control unit to cool the inside of the control unit. Applicable cooling fan ........... 109P0424H702 (Sanyo Denki) or MMF-04C24DS-ROF (Melco Technolex) Cooling fan life....................... 30,000 hours

Always turn the control section power OFF before replacing the control unit's cooling fan. (1) Confirm that the control unit power is OFF. (If the power is not OFF, turn it OFF.) (2) Disconnect all cables connected to the control unit's connectors. (3) Remove all cards mounted in the control unit's extension slots. (4) Press the latches at the top and bottom of the control unit's front panel, and pull the front

panel with the main card. (5) Remove the two fan fixing screws installed on the main card.

Take care at this time, as if the main card is contacted against metal sections, the data backed up in the memory will be damaged.

(6) Disconnect the fan's connection connector. (7) Replace with the new fan, and connect the fan's connection connector to the main card. (8) Fix the fan with the two fan fixing screws.

Make sure that the fan faces the blowoff direction at this time. (9) Align the main card with the rails on the control unit frame, and press in until the latches lock. (10) Mount the cards in the control unit's extension slots. (11) Correctly connect all cables that were connected.

Fan fixing screw

Fan Fan connection connector

Main card

Latch

Front panel

Latch

Control unit frame

Wind

CAUTION

Do not replace the cooling fan while the power is ON.

Dispose of the spent fan according to local laws.

4. DAILY MAINTENANCE AND PERIODIC INSPECTION AND MAINTENANCE 4.3 Replacement Methods

II - 29

4.3.3 Control Unit (1) Control unit

Always turn the machine power OFF before replacing the control unit. (1) Disconnect all cables connected to the control unit. (2) Remove all cards mounted in the control unit's extension slots. (3) Loosen screw A. (There is no need to remove the screw.) (4) While supporting the control unit with a hand, remove screw B. (5) Lift up and remove the control unit. (6) Replace with a new control unit, and fix the control unit with the fixing screws. (7) Mount the cards into the extension slots. (8) Correctly connect all cables that were connected.

(Connect the cables to the designated connectors.)

Screw B

Lift up Screw A

CAUTION

Incorrect connections could cause device damage, so always connect the cables to the designated connectors.

Do not replace the control unit while the power is ON.

Do not connect or disconnect the cables connected between each unit while the power is ON.

4. DAILY MAINTENANCE AND PERIODIC INSPECTION AND MAINTENANCE 4.3 Replacement Methods

II - 30

(2) Remote I/O unit

Always turn the machine power OFF before replacing the remote I/O control unit. (1) Disconnect all cables connected to the remote I/O unit. (2) Loosen screw A. (There is no need to remove the screw.) (3) While supporting the unit with the left hand, remove screw B. (4) Lift up and remove the remote I/O unit. (5) Replace with a new remote I/O unit, and fix the remote I/O unit with the fixing screws. (6) Correctly connect all cables that were connected.

(Connect the cables to the designated connectors.)

Screw B

Screw A Lift up

CAUTION

Incorrect connections could cause device damage, so always connect the cables to the designated connectors.

Do not replace the control unit while the power is ON.

Do not connect or disconnect the cables connected between each unit while the power is ON.

4. DAILY MAINTENANCE AND PERIODIC INSPECTION AND MAINTENANCE 4.3 Replacement Methods

II - 31

4.3.4 Control PCB (1) Main card

Always turn the control unit power OFF before replacing the main card. (1) Confirm that the control unit power is OFF. (If the power is not OFF, turn it OFF.) (2) Disconnect all cables connected to the control unit's connectors. (3) Remove all cards mounted in the control unit's extension slots. (4) Press the latches at the top and bottom of the control unit's front panel, and pull the front

panel with the main card. Hold the front panel section with a hand, and take care not to touch the PCB. Take care hereafter, as if the main card is contacted against metal sections, the data backed up in the memory will be damaged.

(5) Replace with the new card. Align the main card with the rails on the control unit frame, and press in until the latches lock.

(6) Mount the cards in the control unit's extension slots. (7) Correctly connect all cables that were connected.

Main card

Latch

Front panel

Latch

Control unit frame

CAUTION

Incorrect connections could cause device damage, so always connect the cables to the designated connectors.

Do not replace the control section power PCB while the power is ON.

Do not connect or disconnect the cables connected between each unit while the power is ON.

4. DAILY MAINTENANCE AND PERIODIC INSPECTION AND MAINTENANCE 4.3 Replacement Methods

II - 32

(2) Extension card Always turn the control unit power OFF before replacing the extension card.

(1) Confirm that the control unit power is OFF. (If the power is not OFF, turn it OFF.) (2) Disconnect all cables connected to the extension card's connectors. (3) Open the card puller on the extension card outward, and pull the card out. Hold the card puller section, and take care not to touch the PCB. (4) Replace with a new card. Align the card with the extension slot rails, and press into the back. (5) Correctly connect all cables that were connected.

Extension card

Card puller Control unit

CAUTION

Incorrect connections could cause device damage, so always connect the cables to the designated connectors.

Do not replace the extension PCB while the power is ON.

Do not connect or disconnect the cables connected between each unit while the power is ON.

Revision History

Date of revision Manual No. Revision details

Nov. 1999

BNP-B2255A Correction of mistakes; Addition of Appendix 9 EMC Installation Guidelines

Nov. 2000 BNP-B2255B Details related to generation of smoke added to "Safety Precautions". Caution regarding installation of ferrite core added to "I-5.13

Connecting the Display Unit with Ethernet". Details related to SA output to "II-3.2 Troubleshooting". Other mistakes corrected.

Nov. 2001 BNP-B2255C Drawings changed and cautions added to "I-3.4 Installation". Explanations related to "I-5.14 Connecting the Network with

MELSECNET/10", "I-5.15 Connecting the IO Device with CC-Link", and "I-5.16 Connecting the IO Device with DeviceNet" added.

Details listed in "I-Appendix 7 List of connector sets" reviewed. "II-4.6 HR877/878 Card", "II-4.7 HR877/879 Card", "II-4.8 HR865

Card" and "II-4.9 HR871 Card" added. Other mistakes corrected.

Dec. 2003

BNP-B2255D Rearranged orders of chapters. Reviewed and revised details related to I-3.1 General Specification. Reviewed and revised details related to I-4.8 Connecting the Machine

Control Signal. Reviewed and revised details related to I-6.5 Outline of Digital Signal

Input Circuit. Reviewed and revised details related to I-Appendix 7.2 F311 Cable

Manufacturing Drawing. Corrected other mistakes.

Mar. 2004

BNP-B2255E Added Introduction. Added Precautions for Safety. Reviewed and revised details related to I-4.11 Connecting Other

Peripheral Devices. Added I-Appendix 1.2 Outline and Installation Dimensions for Control

Unit with Extension Unit. Corrected other mistakes.

Notice

Every effort has been made to keep up with software and hardware revisions in the contents described in this manual. However, please understand that in some unavoidable cases simultaneous revision is not possible. Please contact your Mitsubishi Electric dealer with any questions or comments regarding the use of this product.

Duplication Prohibited This instruction manual may not be reproduced in any form, in part or in whole, without written permission from Mitsubishi Electric Corporation.

1999 2004 MITSUBISHI ELECTRIC CORPORATION ALL RIGHTS RESERVED

BNP-B2255E(ENG)

MC6/C64

008-107

(0403) MEE

Specifications subject to change without notice. Printed in Japan on recycled paper.

MITSUBISHI ELECTRIC CORPORATION HEAD OFFICE : MITSUBISHI DENKI BLDG., 2-2-3, MARUNOUCHI, CHIYODA-KU, TOKYO 100-8

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