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Agilent InfinityLab LC Series Variable Wavelength Detector User Manual PDF

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Summary of Content for Agilent InfinityLab LC Series Variable Wavelength Detector User Manual PDF

Variable Wavelength Detectors Agilent InfinityLab LC Series

User Manual

Agilent InfinityLab LC Series VWD User Manual

Agilent InfinityLab LC Series VWD User Manual

Notices Document Information Document No: SD-29000240 Rev. D

EDITION 09/2020

Copyright Agilent Technologies, Inc. 2014-2020

No part of this manual may be repro- duced in any form or by any means (including electronic storage and retrieval or translation into a foreign language) without prior agreement and written con- sent from Agilent Technologies, Inc. as governed by United States and interna- tional copyright laws.

Agilent Technologies Hewlett-Packard-Strasse 8 76337 Waldbronn

Warranty The material contained in this document is provided as is, and is subject to being changed, without notice, in future edi- tions. Further, to the maximum extent permitted by applicable law, Agilent dis- claims all warranties, either express or implied, with regard to this manual and any information contained herein, includ- ing but not limited to the implied warran- ties of merchantability and fitness for a particular purpose. Agilent shall not be lia- ble for errors or for incidental or conse- quential damages in connection with the furnishing, use, or performance of this document or of any information con- tained herein. Should Agilent and the user have a separate written agreement with warranty terms covering the material in this document that conflict with these terms, the warranty terms in the separate agreement shall control.

Technology Licenses The hardware and/or software described in this document are furnished under a license and may be used or copied only in accordance with the terms of such license.

Restricted Rights Legend U.S. Government Restricted Rights. Soft- ware and technical data rights granted to the federal government include only those rights customarily provided to end user customers. Agilent provides this customary commercial license in Soft- ware and technical data pursuant to FAR 12.211 (Technical Data) and 12.212 (Computer Software) and, for the Depart- ment of Defense, DFARS 252.227-7015 (Technical Data - Commercial Items) and DFARS 227.7202-3 (Rights in Commer- cial Computer Software or Computer Software Documentation).

Safety Notices

CAUTION A CAUTION notice denotes a hazard. It calls attention to an operating procedure, practice, or the like that, if not correctly per- formed or adhered to, could result in damage to the product or loss of important data. Do not proceed beyond a CAUTION notice until the indicated conditions are fully understood and met.

WARNING A WARNING notice denotes a hazard. It calls attention to an operating procedure, practice, or the like that, if not correctly per- formed or adhered to, could result in personal injury or death. Do not proceed beyond a WARN- ING notice until the indicated conditions are fully understood and met.

Agilent InfinityLab LC Series VWD User Manual 3

In This Book

This manual covers: the Agilent 1290 Infinity II Variable Wavelength Detector (G7114B) and the Agilent 1260 Infinity II Variable Wavelength Detector (G7114A).

Find information on other Agilent Variable Wavelength Detectors in separate manuals.

1 Introduction to the Variable Wavelength Detector

This chapter gives an introduction to the detector, instrument overview and internal connectors.

2 Site Requirements and Specifications

This chapter gives information on environmental requirements, physical and performance specifications.

3 Using the Module

This chapter explains the essential operational parameters of the module.

4 Preparing the Module

This chapter provides information on how to set up the detector for an analysis and explains the basic settings.

5 Optimizing the Detector

This chapter provides information on how to optimize the detector.

6 Troubleshooting and Diagnostics

Overview about the troubleshooting and diagnostic features.

Agilent InfinityLab LC Series VWD User Manual 4

7 Error Information

This chapter describes the meaning of detector error messages, and provides information on probable causes and suggested actions how to recover from error conditions.

8 Test Functions

This chapter describes the detectors built in test functions.

9 Maintenance

This chapter provides general information on maintenance of the detector.

10 Parts and Materials for Maintenance

This chapter provides information on parts for maintenance.

11 Identifying Cables

This chapter provides information on cables used with the Agilent 1200 Infinity Series modules.

12 Hardware Information

This chapter describes the detector in more detail on hardware and electronics.

13 LAN Configuration

This chapter provides information on connecting the module to the Agilent ChemStation PC.

14 Appendix

This chapter provides addition information on safety, legal and web.

Agilent InfinityLab LC Series VWD User Manual 5

Contents

1 Introduction to the Variable Wavelength Detector 9

Introduction to the Detector 10 Product Description 11 Optical System Overview 13 Dual-Wavelength Mode 18 Leak and Waste Handling 19 Operating Principle 24

2 Site Requirements and Specifications 25

Site Requirements 26 Physical Specifications 29 Performance Specifications 30

3 Using the Module 35

Magnets 36 Turn on/off 37 Status Indicators 39 Instrument Configuration 40 Set up the Detector with Agilent Open Lab ChemStation 42 The Detector User Interface 43 Detector Control Settings 45 Method Parameter Settings 46 Scanning with the VWD 50 Agilent Local Control Modules 52

Agilent InfinityLab LC Series VWD User Manual 6

4 Preparing the Module 53

Leak and Waste Handling 54 Setting up an Analysis 56 Solvent Information 63 Capillary Coding Guide 69 Installing Capillaries 72

5 Optimizing the Detector 77

Introduction 78 Match the Flow Cell to the Column 79 Set the Detector Parameters 82 Warm up of the Detector 83

6 Troubleshooting and Diagnostics 85

Available Tests versus Interfaces 86 Agilent Lab Advisor Software 87

7 Error Information 88

What Are Error Messages 89 General Error Messages 90 Detector Error Messages 97

8 Test Functions 107

Introduction 108 Intensity Test 113 Cell Test 116 Wavelength Verification-Calibration 118 ASTM Drift and Noise Test 120 Quick Noise Test 121 Dark Current Test 123 Holmium Oxide Test 125 D/A Converter (DAC) Test 128 Other Lab Advisor Functions 131

Agilent InfinityLab LC Series VWD User Manual 7

9 Maintenance 132

Introduction to Maintenance 133 Warnings and Cautions 134 Overview of Maintenance 136 Cleaning the Module 137 Remove and Install the Doors 138 Replace the Deuterium Lamp 140 Replace the Flow Cell / Cuvette Holder 143 Repair the Flow Cells 145 Using the Cuvette Holder 149 Correcting Leaks 151 Replace Leak Handling System Parts 153 Replace the Module Firmware 154

10 Parts and Materials for Maintenance 155

Overview of Maintenance Parts 156 Standard Flow Cell 10 mm / 14 l 158 Micro Flow Cell 3 mm / 2 L 160 Semi-micro Flow Cell (Parts) 162 High Pressure Flow Cell (Parts) 164 Bio Standard Flow Cell 166 Bio Micro Flow Cell 168 Cuvette Holder (Parts) 170 Accessory Kit 171

11 Identifying Cables 172

Cable Overview 173 Analog Cables 175 Remote Cables 177 CAN Cable 181 RS-232 Cables 182 USB Cables 183

Agilent InfinityLab LC Series VWD User Manual 8

12 Hardware Information 184

Firmware Description 185 Electrical Connections 188 Interfaces 191 Setting the 6-bit Configuration Switch 199 Instrument Layout 203 Early Maintenance Feedback (EMF) 204

13 LAN Configuration 206

What You Have to Do First 207 TCP/IP parameter configuration 208 Configuration Switch 209 Initialization Mode Selection 210 Dynamic Host Configuration Protocol (DHCP) 212 Manual Configuration 215

14 Appendix 219

General Safety Information 220 Waste Electrical and Electronic Equipment (WEEE) Directive 229 Radio Interference 230 Sound Emission 231 Solvent Information 232 Declaration of Conformity for HOX2 Filter 233 Agilent Technologies on Internet 234

Agilent InfinityLab LC Series VWD User Manual 9

1 Introduction to the Variable Wavelength Detector

Introduction to the Detector 10 Product Description 11 Product Description G7114A 11 Product Description G7114B 12

Optical System Overview 13 Flow Cell 14 Lamp 15 Source Lens Assembly 15 Entrance Slit Assembly 15 Filter Assembly 16 Mirror Assemblies M1 and M2 17 Grating Assembly 17 Beam Splitter Assembly 17 Photo Diodes Assemblies 17 Photo Diode ADC (analog-to-digital converter) 17

Dual-Wavelength Mode 18 Leak and Waste Handling 19 Leak Sensor 23 Waste Concept 23

Operating Principle 24

This chapter gives an introduction to the detector, instrument overview and internal connectors.

Agilent InfinityLab LC Series VWD User Manual 10

1 Introduction to the Variable Wavelength Detector Introduction to the Detector

Introduction to the Detector

The Agilent variable wavelength detectors described in this manual are designed for highest optical performance, GLP compliance and easy maintenance with: higher data rate up to 120 Hz (G7114A) or 240 Hz for ultra-fast-HPLC

(G7114B), deuterium lamp for highest intensity and lowest detection limit over a

wavelength range of 190 to 600 nm, optional flow-cell cartridges (standard 10 mm, 14 L; high pressure 10 mm,

14 L; micro 3 mm, 2 L; semi-micro 6 mm, 5 L), Bio, and Prep Cells are available and can be used depending on the application needs (other types may be introduced later),

Dual wavelength mode, see Dual-Wavelength Mode on page 18. easy front access to lamp and flow cell for fast replacement, electronic identification of flow cell and lamp with RFID (Radio Frequency

Identification) tag for unambiguous identification, lamp information: part number, serial number, production date, ignitions,

burn time cell information: part number, serial number, production date, nominal

path length, volume, maximum pressure built-in electronic temperature control (ETC) for improved baseline stability,

and built-in holmium oxide filter for fast wavelength accuracy verification.

Agilent InfinityLab LC Series VWD User Manual 11

1 Introduction to the Variable Wavelength Detector Product Description

Product Description

Product Description G7114A The Agilent 1260 Infinity II Variable Wavelength Detector (VWD) is the most sensitive and fastest detector in its class.

Time-programmable wavelength switching provides sensitivity and selectivity for your applications.

More sample information can be acquired in the dual wavelength mode.

Low detector noise (<1.5 AU) and baseline drift (< 1 x 10-4 AU/h) facilitates precise quantification of trace levels components.

High productivity can be achieved with fast analysis at up to 120 Hz data rates.

Figure 1 Overview of the detector

Status indicator

Flow cell

Lamp housing window

and air inlet

Power switch

Leak drain

Agilent InfinityLab LC Series VWD User Manual 12

1 Introduction to the Variable Wavelength Detector Product Description

Product Description G7114B The Agilent 1290 Infinity II Variable Wavelength Detector (VWD) is the most sensitive and fastest detector in its class.

Time-programmable wavelength switching provides sensitivity and selectivity for your applications.

More sample information can be acquired in the dual wavelength mode.

Low detector noise (<1.5 AU) and baseline drift (<110-4 AU/h) facilitates precise quantification of trace levels components.

High productivity can be achieved with fast analysis at up to 240 Hz data rates.

Figure 2 Overview of the detector

Status indicator

Flow cell

Lamp housing window

and air inlet

Power switch

Leak drain

Agilent InfinityLab LC Series VWD User Manual 13

1 Introduction to the Variable Wavelength Detector Optical System Overview

Optical System Overview

The optical system of the detector is shown in the figure below. Its radiation source is a deuterium-arc discharge lamp for the ultraviolet (UV) wavelength range from 190 to 600 nm. The light beam from the deuterium lamp passes through a lens, a filter assembly, an entrance slit, a spherical mirror (M1), a grating, a second spherical mirror (M2), a beam splitter, and finally through a flow cell to the sample diode. The beam through the flow cell is absorbed depending on the solutions in the cell, in which UV absorption takes place, and the intensity is converted to an electrical signal by means of the sample photodiode. Part of the light is directed to the reference photodiode by the beam splitter to obtain a reference signal for compensation of intensity fluctuation of the light source. A slit in front of the reference photodiode cuts out light of the sample bandwidth. Wavelength selection is made by rotating the grating, which is driven directly by a stepper motor. This configuration allows fast change of the wavelength. The cutoff filter is moved into the lightpath above 370 nm to reduce higher order light.

Figure 3 Optical Path of the Variable Wavelength Detector

Deuterium lamp

Filter assembly

Lens

Entrance slit

Mirror M1

Mirror M2

Grating

Reference diode

Sample diode

Flow cell

Beam splitter

Agilent InfinityLab LC Series VWD User Manual 14

1 Introduction to the Variable Wavelength Detector Optical System Overview

Flow Cell A variety of flow-cell cartridges can be inserted using the same quick and simple mounting system.

The flow cells have an integrated RFID tag that contains the flow cell specific information (e.g. part number, cell volume, path length, ...). A RFID tag reader reads out this information and transfers it to the user interface.

Figure 4 Flow Cell with RFID tag

RFID tag

Table 1 Flow cell data

Standard Semi-micro Micro High Pressure Bio Standard Bio Micro

Maximum pressure (bar (MPa))

40 (4) 40 (4) 120 (12) 400 (40)

Path length (mm) 10 (conical) 6 (conical) 3 (conical) 10 (conical) 10 (conical) 3 (conical)

Volume (L) 14 5 2 14 14 2

Inlet i.d. (mm) 0.25 0.17 0.12 0.25 14 0.12

Inlet length (mm) 750 250 310 750 750 310

Outlet i.d. (mm) 0.30 0.17 0.17 0.17 0.30 310

Outlet length (mm) 120 120 120 120 120 310

Total volume (L) 60.77 14.49 14.00 60.77 60.77 310

Materials in contact with solvent

SST, quartz, PTFE, PEEK

SST, quartz, PTFE

SST, quartz, PTFE

SST, quartz, Kapton

MP35N, sap- phire

MP35N, sap- phire

Agilent InfinityLab LC Series VWD User Manual 15

1 Introduction to the Variable Wavelength Detector Optical System Overview

Lamp The light source for the UV wavelength range is a deuterium lamp. As a result of plasma discharge in a low pressure deuterium gas, the lamp emits light over the 190 600 nm wavelength range.

The lamp has an integrated RFID tag that contains the lamp specific information (e.g. part number, burn time, ...). An RFID tag reader reads out this information and transfers it to the user interface.

Source Lens Assembly The source lens receives the light from the deuterium lamp and focuses it onto the entrance slit.

Entrance Slit Assembly The entrance slit assembly has an exchangeable slit. The standard one has a 1-mm slit. For replacement and calibration purposes to optimize the alignment, a slit with a hole is needed.

Agilent InfinityLab LC Series VWD User Manual 16

1 Introduction to the Variable Wavelength Detector Optical System Overview

Filter Assembly The filter assembly is electromechanically actuated. During wavelength calibrations it moves into the light path.

Figure 5 Filter Assemby

The filter assembly has two filters installed and is processor-controlled.

A photo sensor determines the correct position.

OPEN nothing in light path at < 370 nm

CUTOFF cut off filter in light path at > 370 nm

HOLMIUM holmium oxide filter for wavelength check

SHUTTER for measurement of dark current of photo diodes

Cutoff Filter

Shutter

Cutoff Filter plus Holmium Oxide Filter

Agilent InfinityLab LC Series VWD User Manual 17

1 Introduction to the Variable Wavelength Detector Optical System Overview

Mirror Assemblies M1 and M2 The instrument contains two spherical mirrors (M1 and M2). The beam adjustable is vertically and horizontally. Both mirrors are identical.

Grating Assembly The grating separates the light beam into all its component wavelengths and reflects the light onto mirror #2.

The stepper motor reference position is determined by a plate fitted onto the motor shaft, interrupting the beam of a photo sensor. The wavelength calibration of the grating is done at the zero order light position and at 656 nm, which is the emission line of the deuterium lamp.

Beam Splitter Assembly The beam splitter splits the light beam. One part goes directly to the sample diode. The other part of the light beam goes to the reference diode.

Photo Diodes Assemblies Two photo diode assemblies are installed in the optical unit. The sample diode assembly is located on the left side of the optical unit. The reference diode assembly is located in the front of the optical unit.

Photo Diode ADC (analog-to-digital converter) The photo diode current is directly converted to digital data direct photo current digitalization. The data is transferred to the detector main board. The photo diode ADC boards are located close to the photo diodes.

Agilent InfinityLab LC Series VWD User Manual 18

1 Introduction to the Variable Wavelength Detector Dual-Wavelength Mode

Dual-Wavelength Mode

The detector provides a Dual-Wavelength mode that offers additional operation functions. Features: 200 ms acquisition time per data point

5 Hz data rate distributed to two channels 2.5 Hz data rate for each channel,

delta wavelength max. 150 nm, scans during Dual-Wavelength mode are possible, the second order filter is disabled when one wavelength is < 370 nm. Timetable: Wavelength settings are timetable programmable (depends if enough time for

implementation is available), switching from Single-Wavelength mode to Dual-Wavelength mode is NOT

timetable programmable, filter settings are not timetable programmable.

Agilent InfinityLab LC Series VWD User Manual 19

1 Introduction to the Variable Wavelength Detector Leak and Waste Handling

Leak and Waste Handling

The Agilent InfinityLab LC Series has been designed for safe leak and waste handling. It is important that all security concepts are understood and instructions are carefully followed.

The solvent cabinet is designed to store a maximum volume of 8 L solvent. The maximum volume for an individual bottle stored in the solvent cabinet should not exceed 2 L. For details, see the usage guideline for the Agilent Infinity II Solvent Cabinets (a printed copy of the guideline has been shipped with the solvent cabinet, electronic copies are available on the Internet).

All leak plane outlets are situated in a consistent position so that all Infinity and Infinity II modules can be stacked on top of each other. Waste tubes are guided through a channel on the right hand side of the instrument, keeping the front access clear from tubes.

The leak plane provides leak management by catching all internal liquid leaks, guiding them to the leak sensor for leak detection, and passing them on to the next module below, if the leak sensor fails. The leak sensor in the leak plane stops the running system as soon as the leak detection level is reached. Solvent and condensate is guided through the waste channel into the waste container: from the detector's flow cell outlet from the Multisampler needle wash port from the Sample Cooler or Sample Thermostat (condensate) from the pump's Seal Wash Sensor (if applicable) from the pump's Purge Valve or Multipurpose Valve

Agilent InfinityLab LC Series VWD User Manual 20

1 Introduction to the Variable Wavelength Detector Leak and Waste Handling

Figure 6 Infinity II Leak Waste Concept (Flex Bench installation)

Agilent InfinityLab LC Series VWD User Manual 21

1 Introduction to the Variable Wavelength Detector Leak and Waste Handling

Figure 7 Infinity II Single Stack Leak Waste Concept (bench installation)

Agilent InfinityLab LC Series VWD User Manual 22

1 Introduction to the Variable Wavelength Detector Leak and Waste Handling

Figure 8 Infinity II Two Stack Leak Waste Concept (bench installation)

The waste tube connected to the leak plane outlet on each of the bottom instruments guides the solvent to a suitable waste container.

Agilent InfinityLab LC Series VWD User Manual 23

1 Introduction to the Variable Wavelength Detector Leak and Waste Handling

Leak Sensor

Waste Concept 1 Agilent recommends using the 6 L waste can with 1 Stay Safe cap GL45 with

4 ports (5043-1221) for optimal and safe waste disposal. If you decide to use your own waste solution, make sure that the tubes don't immerse in the liquid.

CAUTION Solvent incompatibility

The solvent DMF (dimethylformamide) leads to corrosion of the leak sensor. The material of the leak sensor, PVDF (polyvinylidene fluoride), is incompatible with DMF.

Do not use DMF as mobile phase.

Check the leak sensor regularly for corrosion.

Agilent InfinityLab LC Series VWD User Manual 24

1 Introduction to the Variable Wavelength Detector Operating Principle

Operating Principle

Figure 9 Hydraulic path

Column

In Out

Waste

Flow cell

Agilent InfinityLab LC Series VWD User Manual 25

2 Site Requirements and Specifications

Site Requirements 26 Physical Specifications 29 Performance Specifications 30 Specifications 30 Specification Conditions 34

This chapter gives information on environmental requirements, physical and performance specifications.

Agilent InfinityLab LC Series VWD User Manual 26

2 Site Requirements and Specifications Site Requirements

Site Requirements

A suitable environment is important to ensure optimal performance of the instrument.

Power Considerations The module power supply has wide ranging capability. It accepts any line voltage in the range described in Table 2 on page 29. Consequently there is no voltage selector in the rear of the module. There are also no externally accessible fuses, because automatic electronic fuses are implemented in the power supply.

WARNING Hazard of electrical shock or damage of your instrumentation can result, if the devices are connected to a line voltage higher than specified.

Connect your instrument to the specified line voltage only.

WARNING Electrical shock hazard The module is partially energized when switched off, as long as the power cord is plugged in. The cover protects users from personal injuries, for example electrical shock.

Do not open the cover.

Do not operate the instrument and disconnect the power cable in case the cover has any signs of damage.

Contact Agilent for support and request an instrument repair service.

WARNING Inaccessible power plug. In case of emergency it must be possible to disconnect the instrument from the power line at any time.

Make sure the power connector of the instrument can be easily reached and unplugged.

Provide sufficient space behind the power socket of the instrument to unplug the cable.

Agilent InfinityLab LC Series VWD User Manual 27

2 Site Requirements and Specifications Site Requirements

Power Cords Country-specific power cords are available for the module. The female end of all power cords is identical. It plugs into the power-input socket at the rear. The male end of each power cord is different and designed to match the wall socket of a particular country or region.

Agilent makes sure that your instrument is shipped with the power cord that is suitable for your particular country or region.

WARNING Unintended use of power cords

Using power cords for unintended purposes can lead to personal injury or damage of electronic equipment.

Never use a power cord other than the one that Agilent shipped with this instrument.

Never use the power cords that Agilent Technologies supplies with this instrument for any other equipment.

Never use cables other than the ones supplied by Agilent Technologies to ensure proper functionality and compliance with safety or EMC regulations.

WARNING Absence of ground connection

The absence of ground connection can lead to electric shock or short circuit.

Never operate your instrumentation from a power outlet that has no ground connection.

WARNING Electrical shock hazard

Solvents may damage electrical cables.

Prevent electrical cables from getting in contact with solvents.

Exchange electrical cables after contact with solvents.

Agilent InfinityLab LC Series VWD User Manual 28

2 Site Requirements and Specifications Site Requirements

Bench Space The detector dimensions and weight (see Physical Specifications on page 29) allows you to place the detector on almost any desk or laboratory bench. It needs an additional 2.5 cm (1.0 inch) of space on either side and approximately 8 cm (3.1 inch) in the rear for air circulation and electric connections.

If the bench should carry an Agilent 1200 Infinity Series system, make sure that the bench is designed to bear the weight of all modules.

The detector should be operated in a horizontal position.

Environment Your detector will work within specifications at ambient temperatures and relative humidity as described in Physical Specifications on page 29.

Better drift performance depends on better control of the temperature fluctuations. To realize the highest performance, minimize the frequency and the amplitude of the temperature changes to below 1 C/hour (1.8 F/hour). Turbulences around one minute or less can be ignored.

CAUTION Condensation within the module

Condensation can damage the system electronics.

Do not store, ship or use your module under conditions where temperature fluctuations could cause condensation within the module.

If your module was shipped in cold weather, leave it in its box and allow it to warm slowly to room temperature to avoid condensation.

Agilent InfinityLab LC Series VWD User Manual 29

2 Site Requirements and Specifications Physical Specifications

Physical Specifications

Table 2 Physical Specifications

Type Specification Comments

Weight 11 kg (24.3 lbs)

Dimensions (height width depth)

140 x 396 x 436 mm (5.5 x 15.6 x 17.2 inches)

Line voltage 100 240 V~, 10 % Wide-ranging capability

Line frequency 50 or 60 Hz, 5 %

Power consumption 80 VA, 70 W

Ambient operating tempera- ture

4 - 55 C (39 - 131 F)

Ambient non-operating tem- perature

-40 70 C (-40 158 F)

Humidity < 95 % r.h. at 40 C (104 F) Non-condensing

Operating altitude Up to 3000 m (9842 ft)

Safety standards: IEC, EN, CSA, UL

Overvoltage category II, Pollution degree 2 For indoor use only.

ISM Classification ISM Group 1 Class B According to CISPR 11

Agilent InfinityLab LC Series VWD User Manual 30

2 Site Requirements and Specifications Performance Specifications

Performance Specifications

Specifications

Performance Specifications G7114A

Table 3 Performance Specifications G7114A

Type Specification

Detection type Double-beam photometer

Light source Deuterium lamp

Number of signals Single and dual wavelength detection

Maximum data rate 120 Hz (single wavelength detection) 2.5 Hz (dual wavelength detection)

Short term signal noise (ASTM)

<0.2510-5 AU, at 230 nm (single wavelength detection) <0.8010-5 AU, at 230 nm and 254 nm (dual wavelength detection)

Drift <110-4 AU/h, at 230 nm

Linear absorbance range

>2.5 AU upper limit

Wavelength range 190 600 nm

Wavelength accuracy 1 nm, self-calibration with deuterium lines, verification with holmium oxide filter

Wavelength precision <0.1 nm

Slit width 6.5 nm typical over whole wavelength range

Time programmable Wavelength, polarity, peak width, lamp on/off

Agilent InfinityLab LC Series VWD User Manual 31

2 Site Requirements and Specifications Performance Specifications

Flow cells Standard:14 L volume, 10 mm cell path length and 40 bar (580 psi) pres- sure maximum Micro:2 L volume, 3 mm cell path length and 120 bar (1760 psi) pressure maximum Semi-micro:5 L volume, 6 mm cell path length and 40 bar (588 psi) pres- sure maximum Standard Bio:14 L volume, 10 mm cell path length and 40 bar (580 psi) pressure maximum Micro Bio:2 L volume, 3 mm cell path length and 120 bar (1760 psi) pres- sure maximum Preparative SST:4 L volume, 3 mm cell path length and 120 bar (1760 psi) pressure maximum Preparative Quartz:0.3 mm cell path length and 50 bar (725 psi) pressure maximum Preparative Quartz:0.06 mm cell path length and 50 bar (725 psi) pressure maximum High pressure:14 L volume, 10 mm cell path length and 400 bar (5800 psi) pressure maximum

Spectral tools Stop-flow wavelength scan

Analog output Recorder/Integrator 100 mV or 1 V, 1 output

Instrument Control Lab Advisor B.02.08 or above LC and CE Drivers A.02.14 or above For details about supported software versions refer to the compatibility matrix of your version of the LC and CE Drivers

Local Control Agilent Instant Pilot (G4208A) B.02.19 or above

Communication LAN, Controller Area Network (CAN), USB Extended Remote Interface: ready, start, stop and shut-down signals

GLP Early maintenance feedback (EMF) for continuous tracking of instrument usage in terms of lamp burn time with user settable limits and feedback messages. Electronic records of maintenance and errors. RFID for elec- tronic records of flow cell and UV lamp conditions (path length, volume, product number, serial number, test passed, and usage). Verification of wavelength accuracy with built-in holmium oxide filter.

Safety and mainte- nance

Extensive diagnostics, error detection and display through Agilent Instant Pilot and Agilent Lab Advisor software. Leak detection, safe leak handling, leak output signal for shutdown of pumping system. Low voltages in major maintenance areas. Tracking of flow cells and lamps with RFID (radio fre- quency identification) tags.

Housing All materials recyclable.

Others Second generation of Electronic temperature control (ETC) for the complete optical unit.

Table 3 Performance Specifications G7114A

Type Specification

Agilent InfinityLab LC Series VWD User Manual 32

2 Site Requirements and Specifications Performance Specifications

Performance Specifications G7114B

Table 4 Performance Specifications G7114B

Type Specification

Detection type Double-beam photometer

Light source Deuterium lamp

Number of signals Single and dual wavelength detection

Maximum data rate 240 Hz (single wavelength detection) 2.5 Hz (dual wavelength detection)

Short term signal noise (ASTM)

<0.1510-5 AU, at 230 nm (single wavelength detection) <0.8010-5 AU, at 230 nm and 254 nm (dual wavelength detection)

Drift <110-4 AU/h, at 230 nm

Linear absorbance range

>2.5 AU upper limit

Wavelength range 190 600 nm

Wavelength accuracy 1 nm, self-calibration with deuterium lines, verification with holmium oxide filter

Wavelength precision <0.1 nm

Slit width 6.5 nm typical over whole wavelength range

Time programmable Wavelength, polarity, peak width, lamp on/off

Flow cells Standard:14 L volume, 10 mm cell path length and 40 bar (580 psi) pres- sure maximum Micro:2 L volume, 3 mm cell path length and 120 bar (1760 psi) pressure maximum Semi-micro:5 L volume, 6 mm cell path length and 40 bar (580 psi) pres- sure maximum Standard Bio:14 L volume, 10 mm cell path length and 40 bar (580 psi) pressure maximum Micro Bio:2 L volume, 3 mm cell path length and 120 bar (1760 psi) pres- sure maximum Preparative SST:4 L volume, 3 mm cell path length and 120 bar (1760 psi) pressure maximum Preparative Quartz:0.3 mm cell path length and 50 bar (725 psi) pressure maximum Preparative Quartz:0.06 mm cell path length and 50 bar (725 psi) pressure maximum High pressure:14 L volume, 10 mm cell path length and 400 bar (5800 psi) pressure maximum

Agilent InfinityLab LC Series VWD User Manual 33

2 Site Requirements and Specifications Performance Specifications

Spectral tools Stop-flow wavelength scan

Analog output Recorder/Integrator 100 mV or 1 V, 1 output

Instrument Control Lab Advisor B.02.06 or above LC and CE Drivers A.02.11 or above For details about supported software versions refer to the compatibility matrix of your version of the LC and CE Drivers

Local Control Agilent Instant Pilot (G4208A) B.02.19 or above

Communication LAN, Controller Area Network (CAN), USB Extended Remote Interface: ready, start, stop and shut-down signals

GLP Early maintenance feedback (EMF) for continuous tracking of instrument usage in terms of lamp burn time with user settable limits and feedback messages. Electronic records of maintenance and errors. RFID for electron- ics records of flow cell and UV lamp conditions (path length, volume, prod- uct number, serial number, test passed, and usage). Verification of wavelength accuracy with built-in holmium oxide filter.

Safety and mainte- nance

Extensive diagnostics, error detection and display through Agilent Instant Pilot and Agilent Lab Advisor software. Leak detection, safe leak handling, leak output signal for shutdown of pumping system. Low voltages in major maintenance areas. Tracking of flow cells and lamps with RFID (radio fre- quency identification) tags.

Housing All materials recyclable.

Others Second generation of Electronic temperature control (ETC) for the complete optical unit.

Table 4 Performance Specifications G7114B

Type Specification

Agilent InfinityLab LC Series VWD User Manual 34

2 Site Requirements and Specifications Performance Specifications

Specification Conditions ASTM: Standard Practice for Variable Wavelength Photometric Detectors Used in Liquid Chromatography.

Reference conditions: Standard flow cell, path length 10 mm, flow 1 mL/min LC-grade methanol.

Noise:

1.510-6 AU at 230 nm, TC 2 s

RT = 2.2 * TC

Linearity:

Linearity is measured with caffeine at 265 nm.

ASTM drift tests require a temperature change below 2C/hour (3.6F/hour) over one hour period. Our published drift specification is based on these conditions. Larger ambient temperature changes will result in larger drift.

Better drift performance depends on better control of the temperature fluctuations. To realize the highest performance, minimize the frequency and the amplitude of the temperature changes to below 1C/hour (1.8F/hour). Turbulences around one minute or less can be ignored.

Performance tests should be done with a completely warmed up optical unit (> one hour). ASTM measurements require that the detector should be turned on at least 24 hours before start of testing.

NOTE The specification are based on the the standard RFID tag lamp (G1314-60101) and may be not achieved when other lamp types or aged lamps are used.

Agilent InfinityLab LC Series VWD User Manual 35

3 Using the Module

Magnets 36 Turn on/off 37 Status Indicators 39 Instrument Configuration 40 Set up the Detector with Agilent Open Lab ChemStation 42 The Detector User Interface 43 Detector Control Settings 45 Method Parameter Settings 46 Scanning with the VWD 50 Agilent Local Control Modules 52

This chapter explains the essential operational parameters of the module.

Agilent InfinityLab LC Series VWD User Manual 36

3 Using the Module Magnets

Magnets

1 Magnets in doors of pumps, autosamplers, detectors, and fraction collectors.

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3 Using the Module Turn on/off

Turn on/off

This procedure exemplarily shows an arbitrary LC stack configuration.

1 2

Power switch: On

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3 Using the Module Turn on/off

3 Turn instrument On/Off with the control software. 4

Power switch: Off

5

Agilent InfinityLab LC Series VWD User Manual 39

3 Using the Module Status Indicators

Status Indicators

This procedure exemplarily shows an arbitrary LC stack configuration. 1 The module status indicator indicates one of six possible module conditions:

Status indicators 1. Idle 2. Run mode 3. Not-ready. Waiting for a specific pre-run condition to be reached or completed. 4. Error mode - interrupts the analysis and requires attention (for example, a leak or defective internal components). 5. Resident mode (blinking) - for example, during update of main firmware. 6. Bootloader mode (fast blinking). Try to re-boot the module or try a cold-start. Then try a firmware update.

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3 Using the Module Instrument Configuration

Instrument Configuration

1 Set the switches of the Configuration switch at the rear of the module: a All switches DOWN: module uses the default IP address 192.168.254.11.

b Switch 4 UP and others DOWN: module uses DHCP. c Switch 5 UP and others DOWN: modules uses STORED address.

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3 Using the Module Instrument Configuration

2 Enter the setup information (MAC / IP address and/or Instrument Name). a Agilent OpenLab ChemStation (Configure Instrument):

b Lab Advisor (Instrument Overview - Add Instrument):

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3 Using the Module Set up the Detector with Agilent Open Lab ChemStation

Set up the Detector with Agilent Open Lab ChemStation

The setup of the detector is shown with the Agilent OpenLab ChemStation C.01.07 and Driver A.02.14.

Figure 10 ChemStation Method and Run Control (just detector is shown)

After successful load of the OpenLab ChemStation, you should see the module as an active item in the graphical user interface (GUI).

NOTE This section describes the detector settings only. For information on the Agilent OpenLab ChemStation or other 1200 Infinity modules refer to the corresponding documentation.

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3 Using the Module The Detector User Interface

The Detector User Interface

Within the detector GUI, there are active areas. If you move the mouse cursor across the icons the cursor will change. 1 Lamp: turn on and off of UV-lamp 2 EMF status 3 Detector status 4 Lamp status (on/off) and information (RFID tag) 5 Flow Cell information (RFID tag)

RFID tag information is displayed when moving with the mouse cursor on to the tag attached to the flow cell or lamp. The information provides flow cell and lamp related informa- tion like Part number Production date Serial number and other details.

EMF Status shows Run / Ready / Error state and Not Ready text or Error text Offline (gray) Ok. No Maintenance required (green) EMF warning. Maintenance might be required (yellow) EMF warning. Maintenance required (red) Important: The EMF settings can be accessed via Agilent Lab Advisor. The limit(s) can be changed. Based on the limit, the User Interface displays the above status.

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3 Using the Module The Detector User Interface

Module Status shows Run / Ready / Error state and Not Ready text or Error text Error (red) Not ready (yellow) Ready (green) Pre run, Post run (purple) Run (blue) Idle (green) Offline (dark gray) Standby (light gray)

A right-click into the Active Area will open a menu to Show the Control Interface (special module settings) Show the Method interface (similar as via menu

Instrument > Setup Instrument Method) Set Error Method Identify Module (Status LED will blink) Perform a Balance Switch the UV-lamp on/off (same as click on button

Make Device Ready/Turn device off (standby)) Take / Abort Scans (during flow off)

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3 Using the Module Detector Control Settings

Detector Control Settings

The figure shows the default settings. Lamps: can be turned ON/OFF. Analog Output Range: can be set to either 100 mV or

1 Vfull scale, for additional settings see Analog (under Table 5 on page 47).

Temperature Control: The optical unit is kept on constant temperature (some degrees above ambient) and improves the baseline stability in unstable environments, see also Environment on page 28.

If the flow cell temperature is critical for your chromatog- raphy or your environment is stable, you may set the Tem- perature Control to off. This will lower the optical unit and flow cell temperature by some degree.

UV Lamp Tag Automatic detects a lamp with RFID tag. If no RFID

tag lamp is used, UV lamp not ready is displayed and it cannot be ignited. A compatible mode has to be selected based on the used lamp; see Non-RFID-tag lamp information below.

Manual (by PN) uses the selected heating mode. This mode can also be used when the RFID tag of the standard lamp (Deuterium lamp (with RFID tag) (G1314-60101)) is not recognized (defect RFID tag or reader).

Non-RFID-tag lamp: In case a non-RFID-tag lamp is used, the user interface will show this when selecting a compatible mode. You may operate the detector outside of the guaranteed specification. The correct selection is important for optimal performance and lifetime.

Cell Tag: Automatic mode for Agilent flow cells with RFID tags. If no RFID tag cell is used, detector icon will become gray (cell tag not ready) and analysis is disabled.

At Power On: automatic lamp-on at power on. Automatic Turn On: automatic detector power on.

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3 Using the Module Method Parameter Settings

Method Parameter Settings

These settings are available via Menu > Instrument > Set up Instrument Method or via right click into the modules active area (does not show the Instrument Curves tab).

Figure 11 Method parameter settings

NOTE For additional help and support: Highlight the desired cell and press F1. A help screen will open with additional information and documentation about the topic.

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3 Using the Module Method Parameter Settings

Table 5 Method Parameter Settings

Figure 12 G7114B Peakwidth settings up to 240 Hz

Figure 13 G7114A Peakwidth settings up to 120 Hz

Figure 14 G7114B Dual Wavelength Settings

Signal Wavelength Single Wavelength (190 600 nm, step 1) Dual Wavelength Mode enables the multi-wavelength mode with two wavelengths. Peakwidth (Responsetime, Data Rate) Peakwidth enables you to select the peak width (response time) for your analysis. The peak width is defined as the width of a peak, in minutes, at half the peak height. Set the peak width to the narrowest expected peak in your chromatogram. The peak width sets the optimum response time for your detector. The peak detector ignores any peaks that are consid- erably narrower, or wider, than the peak width setting. The response time is the time between 10 % and 90 % of the out- put signal in response to an input step function. When the All spectrum storage option is selected, then spectra are acquired continuously depending on the setting of the peak width. The time specified by the peak width is used as a factor in the acquisition of spectra. The acquisition time for one spectrum is slightly less than the peak width divided by 8, which is the acquisition time. Limits: When you set the peak width (in minutes), the corre- sponding response time is set automatically and the appropri- ate data rate for signal and spectra acquisition is selected.

NOTE The G7114A VWD has a data rate of up to 120 Hz. The G7114B VWD has a data rate of up to 240 Hz.

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3 Using the Module Method Parameter Settings

Stoptime/Posttime The stoptime is the time where either the complete system stops (As Pump/Injector) or the module (if different from sys- tem stop time). The data collection is stopped at this time. A posttime period can be used to allow modules items to equili- brate (e.g. after gradient change or temperature change).

Analog Output The range can be set to either 100 mV or 1 V full scale, see Table on page 45. Zero Offset: 1 99 % in steps of 1 % (5 % equal to 50 mV). Attenuation: 0.98 4000 mAU at discrete values for either

100 mV or 1 V full scale.

Signal Polarity Can be switched to negative (if required). Autobalance Defines, whether a balance is performed prior to a run and/or after a run has finished.

Miscellaneous Lamp on required for acquisition: If unchecked, the lamp will be turned off after the analysis has finished. Note that the lamp on requires at least one hour warm-up time, see Warm up of the Detector on page 83. Scan Range / Step: Stop-Flow scan range / step. Access to the scan feature is only possible during run. See Scanning with the VWD on page 50.

Table 5 Method Parameter Settings

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3 Using the Module Method Parameter Settings

Timetable You may set up time events to change functions with their parameters over the run time. Add lines as required. Time Limits: 0.00 to 99999.00 min in steps of 0.01 min. Via the buttons in the bottom area, time table lines can be added, removed, cut copied, pasted or completely cleared. Based on the chosen function, a certain parameter can be selected.

Instrument Curves The detector has several signals (internal temperatures, volt- ages of lamps) that can be used for diagnosing problems. These can be baseline problems deriving from deuterium lamps wander / drift problems due to temperature changes. These signals can be used in addition to the normal baseline signal to determine whether correlation to temperature or volt- age/current of the lamp. These signals are available via the Agilent ChemStation Online Plot/Data Signal and/or Agilent Lab Advisor Software.

Table 5 Method Parameter Settings

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3 Using the Module Scanning with the VWD

Scanning with the VWD

1 Set up a run. 2 Start a run. 3 While running on the baseline, take a Blank Scan. A background scan is stored

in the memory.

4 When the peak of interest enters the flow cell, stop the flow (set flow rate to zero or open the purge valve) and wait a few moments to stabilize the concentration.

NOTE Access to the scan feature is only possible during run with stopped flow. The spectrum is taken during a stop-flow condition only while the peak is kept in the flow cell.

Table 6 Blank scan

Step 1: Blank Scan: scan of the background (solvent) is stored in the memory.

Step 2: Sample Scan: scan of the peak of interest is taken while the peak stays in the flow cell (stop-flow condition).

Online Spectrum: Sample Scan minus Blank Scan. Here the functions are inactive (grayed out). Will be active in run mode.

NOTE Turning off the pump would stop the run and no access to the sample scan is possible.

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3 Using the Module Scanning with the VWD

5 Open the Online Spectra window (View > Online Spectra > VWD) and change the absorbance and wavelength range according your needs.

Figure 15 Online Spectra Window

6 Select Sample Scan. A sample scan is taken in the range defined under Miscellaneous in Table 5 on page 47 and displays the result (Sample Scan minus Blank Scan).

Agilent InfinityLab LC Series VWD User Manual 52

3 Using the Module Agilent Local Control Modules

Agilent Local Control Modules

Agilent InfinityLab Companion G7108AA

The Agilent InfinityLab Companion gives you complete control, system monitoring, signal plotting, and diagnostic capabilities for a wide range of LC system modules.

The instrument control solution is available as full package including all hardware and accessories, but can also be used on your own mobile devices like tablets, mobile phones and other electronic equipment.

Combining the conveniences of the Agilent Instant Pilot features with state-of-the-art mobile technology, the Agilent InfinityLab Companion gives you maximum flexibility and ease of use to control and monitor your LC system modules. Features: Complete local control and monitoring of Agilent Infinity II LC modules Excellent usability and ease of use through a user interface specifically

tailored for mobile devices - simple, intuitive touch-enabled, and visual controllable.

High flexibility through a modern Bring your own device approach. Connection between LC module and mobile device either wireless via Wi-Fi or wired over USB cable (with full package).

Convenient, ergonomic operation either handheld or attached to a module at the stack with newly developed, secure tablet holder (included in the full package).

Preconfigured tablet with all required software already installed (included in the full package).

Centerpiece of the solution is a USB dongle that activates the complete intelligence of the InfinityLab Companion on the instrument stack.

The InfinityLab Companion provides: fast and direct control in front of the instrument a clear overview of the system status control functionalities access to method parameters and sequences a logbook showing events from the modules diagnostic tests

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4 Preparing the Module

Leak and Waste Handling 54 Waste Concept 55

Setting up an Analysis 56 Before Using the System 56 Requirements and Conditions 58 Preparing the Detector 60 Preparing the HPLC System 60 Running the Sample and Verifying the Results 62

Solvent Information 63 Capillary Coding Guide 69 Syntax for Capillary Description 69 At-a-Glance Color-Coding Keys 71

Installing Capillaries 72

This chapter provides information on how to set up the detector for an analysis and explains the basic settings.

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4 Preparing the Module Leak and Waste Handling

Leak and Waste Handling

For details on correct installation, see separate installation documentation.

WARNING Toxic, flammable and hazardous solvents, samples and reagents The handling of solvents, samples and reagents can hold health and safety risks. When working with these substances observe appropriate safety

procedures (for example by wearing goggles, safety gloves and protective clothing) as described in the material handling and safety data sheet supplied by the vendor, and follow good laboratory practice.

Do not use solvents with an auto-ignition temperature below 200 C (392 F). Do not use solvents with a boiling point below 56 C (133 F).

Avoid high vapor concentrations. Keep the solvent temperature at least 40 C (72 F) below the boiling point of the solvent used. This includes the solvent temperature in the sample compartment. For the solvents methanol and ethanol keep the solvent temperature at least 25 C (45 F) below the boiling point.

Do not operate the instrument in an explosive atmosphere. Do not use solvents of ignition Class IIC according IEC 60079-20-1 (for

example, carbon disulfide). Reduce the volume of substances to the minimum required for the

analysis. Never exceed the maximum permissible volume of solvents (8 L) in the

solvent cabinet. Do not use bottles that exceed the maximum permissible volume as specified in the usage guideline for solvent cabinet.

Ground the waste container. Regularly check the filling level of the waste container. The residual free

volume in the waste container must be large enough to collect the waste liquid.

To achieve maximal safety, regularly check the tubing for correct installation.

NOTE For details, see the usage guideline for the solvent cabinet. A printed copy of the guideline has been shipped with the solvent cabinet, electronic copies are available in the Agilent Information Center or via the Internet.

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4 Preparing the Module Leak and Waste Handling

Waste Concept 1 Agilent recommends using the 6 L waste can with 1 Stay Safe cap GL45 with

4 ports (5043-1221) for optimal and safe waste disposal. If you decide to use your own waste solution, make sure that the tubes don't immerse in the liquid.

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4 Preparing the Module Setting up an Analysis

Setting up an Analysis

This chapter can be used for preparing the system, to learn the set up of an HPLC analysis and to use it as an instrument check to demonstrate that all modules of the

system are correctly installed and connected. It is not a test of the instrument performance.

Learn about special settings

Before Using the System

Solvent Information

Observe recommendations on the use of solvents in chapter Solvents in the pumps reference manual.

Priming and Purging the System

When the solvents have been exchanged or the pumping system has been turned off for a certain time (for example, overnight) oxygen will re-diffuse into the solvent channel between the solvent reservoir, vacuum degasser (when available in the system) and the pump. Solvents containing volatile ingredients will slightly lose these. Therefore priming of the pumping system is required before starting an application.

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4 Preparing the Module Setting up an Analysis

1 Open the purge valve of your pump (by turning it counterclockwise) and set flow rate to 3 5 mL/min.

2 Flush all tubes with at least 30 mL of solvent. 3 Set flow to required value of your application and close the purge valve.

Table 7 Choice of Priming Solvents for Different Purposes

Activity Solvent Comments

After an installation

When switching between reverse phase and normal phase (both times)

Isopropanol

Isopropanol

Best solvent to flush air out of the sys- tem

Best solvent to flush air out of the sys- tem

After an installation Ethanol or Methanol Alternative to Isopropanol (second choice) if no Isopropanol is available

To clean the system when using buf- fers

After a solvent change

Bidistilled water

Bidistilled water

Best solvent to re-dissolve buffer crys- tals

Best solvent to re-dissolve buffer crys- tals

After the installation of normal phase seals (P/N 0905-1420)

Hexane + 5% Isopropanol Good wetting properties

NOTE The pump should never be used for priming empty tubings (never let the pump run dry). Use a syringe to draw enough solvent for completely filling the tubings to the pump inlet before continuing to prime with the pump.

NOTE Pump for approximately 10minutes before starting your application.

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4 Preparing the Module Setting up an Analysis

Requirements and Conditions

What You Will Need

The table below lists the items you need to have for the set up of the analysis. Some of these are optional (not required for the basic system).

Conditions

A single injection of the isocratic test standard is made under the conditions given in Table 9 on page 58:

Table 8 What you will need

Agilent 1200 Infinity Series system Pump (plus degassing)

Autosampler

Detector, standard flow cell installed

Degasser (optional)

Column Compartment (optional)

Agilent CDS

System should be correctly set up for LAN com- munication with the Agilent ChemStation

Column: Zorbax Eclipse XDB-C18, 4.6 x 150 mm, 5 m (993967-902) or an equivalent column

Standard: Agilent isocratic checkout sample (01080-68704)

Table 9 Conditions

Flow 1.5 mL/min

Stoptime 8 min

Solvent 100% (30% water/70% Acetonitrile)

Temperature Ambient

Wavelength sample 254 nm

Injection Volume 1 L

Column Temperature (optional): 25 C or ambient

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4 Preparing the Module Setting up an Analysis

Typical Chromatogram

A typical chromatogram for this analysis is shown in Figure 16 on page 59. The exact profile of the chromatogram will depend on the chromatographic conditions. Variations in solvent quality, column packing, standard concentration and column temperature will all have a potential effect on peak retention and response.

Figure 16 Typical Chromatogram with UV-detector

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4 Preparing the Module Setting up an Analysis

Preparing the Detector For best performance of the detector Let the lamp warm-up and stabilize for at least one hour (initial turn on of the

module requires a longer time depending on the environment and the application needs); refer to Specification Conditions on page 34.

For high sensitivity measurements, a stable environment is required; refer to Environment on page 28. Prevent drafts from air condition systems.

Do not work with removed/open front panels/doors. When the system includes a G1316 TCC (typically located below the detector) and its front panel is removed while the TCC is set to high temperatures, the up-streaming air could influence the stability of the detector baseline.

Preparing the HPLC System 1 Turn on the control software and the monitor. 2 Turn on the modules. 3 Start the control software. The screen should show all modules and the

system status is Not Ready. 4 Turn on the modules that require conditioning:

a Detector lamp (warm-up for at least 60 min to get a stable baseline). b Column compartment (set temperature as required). c Pump (purge). d Sampler (prepare the standard isocratic sample into a vial). e Solvents (fill water and Acetontrile into the solvent bottles).

5 Load the default method. 6 Pump the water/acetonitrile (30/70 %) mobile phase through the column for

10 min for equilibration.

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4 Preparing the Module Setting up an Analysis

7 Select the menu item Run Control > Sample Info and enter information about this application. Click OK to leave this screen.

Figure 17 Sample Info

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4 Preparing the Module Setting up an Analysis

Running the Sample and Verifying the Results 1 To start a run select the menu item RunControl > Run Method. 2 This will start the modules and the online plot on the Agilent ChemStation will

show the resulting chromatogram.

Figure 18 Chromatogram with Isocratic Test Sample

NOTE Information about using the Data Analysis functions can be obtained from the Using your ChemStation manual supplied with your system.

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4 Preparing the Module Solvent Information

Solvent Information

Observe the following recommendations on the use of solvents. Follow the recommendations for avoiding the growth of algae, see the pump

manuals. Small particles can permanently block capillaries and valves. Therefore,

always filter solvents through 0.22 m filters. Avoid or minimize the use of solvents that may corrode parts in the flow path.

Consider specifications for the pH range given for different materials such as flow cells, valve materials etc. and recommendations in subsequent sections.

General Information about Solvent/Material Compatibility Materials in the flow path are carefully selected based on Agilents experiences in developing highest-quality instruments for HPLC analysis over several decades. These materials exhibit excellent robustness under typical HPLC conditions. For any special condition, please consult the material information section or contact Agilent.

Disclaimer

Subsequent data was collected from external resources and is meant as a reference. Agilent cannot guarantee the correctness and completeness of such information. Data is based on compatibility libraries, which are not specific for estimating the long-term life time under specific but highly variable conditions of UHPLC systems, solvents, solvent mixtures and samples. Information can also not be generalized due to catalytic effects of impurities like metal ions, complexing agents, oxygen etc. Apart from pure chemical corrosion, other effects like electro corrosion, electrostatic charging (especially for non-conductive organic solvents), swelling of polymer parts etc. need to be considered. Most data available refers to room temperature (typically 20 25 C, 68 77 F). If corrosion is possible, it usually accelerates at higher temperatures. If in doubt, please consult technical literature on chemical compatibility of materials.

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4 Preparing the Module Solvent Information

MP35N

MP35N is a nonmagnetic, nickel-cobalt-chromium-molybdenum alloy demonstrating excellent corrosion resistance (for example, against nitric and sulfuric acids, sodium hydroxide, and seawater) over a wide range of concentrations and temperatures. In addition, this alloy shows exceptional resistance to high-temperature oxidation. Due to excellent chemical resistance and toughness, the alloy is used in diverse applications: dental products, medical devices, nonmagnetic electrical components, chemical and food processing equipment, marine equipment. Treatment of MP35N alloy samples with 10 % NaCl in HCl (pH 2.0) does not reveal any detectable corrosion. MP35N also demonstrates excellent corrosion resistance in a humid environment. Although the influence of a broad variety of solvents and conditions has been tested, users should keep in mind that multiple factors can affect corrosion rates, such as temperature, concentration, pH, impurities, stress, surface finish, and dissimilar metal contacts.

Polyphenylene Sulfide (PPS)

Polyphenylene sulfide has outstanding stability even at elevated temperatures. It is resistant to dilute solutions of most inorganic acids, but it can be attacked by some organic compounds and oxidizing reagents. Nonoxidizing inorganic acids, such as sulfuric acid and phosphoric acid, have little effect on polyphenylene sulfide, but at high concentrations and temperatures, they can still cause material damage. Nonoxidizing organic chemicals generally have little effect on polyphenylene sulfide stability, but amines, aromatic compounds, and halogenated compounds may cause some swelling and softening over extended periods of time at elevated temperatures. Strong oxidizing acids, such as nitric acid (> 0.1 %), hydrogen halides (> 0.1 %), peroxy acids (> 1 %), or chlorosulfuric acid degrade polyphenylene sulfide. It is not recommended to use polyphenylene sulfide with oxidizing material, such as sodium hypochlorite and hydrogen peroxide. However, under mild environmental conditions, at low concentrations and for short exposure times, polyphenylene sulfide can withstand these chemicals, for example, as ingredients of common disinfectant solutions.

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4 Preparing the Module Solvent Information

PEEK

PEEK (Polyether-Ether Ketones) combines excellent properties regarding biocompatibility, chemical resistance, mechanical and thermal stability. PEEK is therefore the material of choice for UHPLC and biochemical instrumentation.

It is stable in the specified pH range (for the Bio-Inert LC system: pH 1 13, see bio-inert module manuals for details), and inert to many common solvents.

There is still a number of known incompatibilities with chemicals such as chloroform, methylene chloride, THF, DMSO, strong acids (nitric acid > 10 %, sulfuric acid > 10 %, sulfonic acids, trichloroacetic acid), halogens or aqueous halogen solutions, phenol and derivatives (cresols, salicylic acid, and so on).

When used above room temperature, PEEK is sensitive to bases and various organic solvents, which can cause it to swell. Under such conditions, normal PEEK capillaries are sensitive to high pressure. Therefore, Agilent uses stainless steel cladded PEEK capillaries in bio-inert systems. The use of stainless steel cladded PEEK capillaries keeps the flow path free of steel and ensures pressure stability up to 600 bar. If in doubt, consult the available literature about the chemical compatibility of PEEK.

Polyimide

Agilent uses semi-crystalline polyimide for rotor seals in valves and needle seats in autosamplers. One supplier of polyimide is DuPont, which brands polyimide as Vespel, which is also used by Agilent.

Polyimide is stable in a pH range between 1 and 10 and in most organic solvents. It is incompatible with concentrated mineral acids (e.g. sulphuric acid), glacial acetic acid, DMSO and THF. It is also degraded by nucleophilic substances like ammonia (e.g. ammonium salts in basic conditions) or acetates.

Polyethylene (PE)

Agilent uses UHMW (ultra-high molecular weight)-PE/PTFE blends for yellow piston and wash seals, which are used in 1290 Infinity pumps, 1290 Infinity II pumps, the G7104C and for normal phase applications in 1260 Infinity pumps.

Polyethylene has a good stability for most common inorganic solvents including acids and bases in a pH range of 1 to 12.5. It is compatible with many organic solvents used in chromatographic systems like methanol, acetonitrile and isopropanol. It has limited stability with aliphatic, aromatic and halogenated hydrocarbons, THF, phenol and derivatives, concentrated acids and bases. For normal phase applications, the maximum pressure should be limited to 200 bar.

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4 Preparing the Module Solvent Information

Tantalum (Ta)

Tantalum is inert to most common HPLC solvents and almost all acids except fluoric acid and acids with free sulfur trioxide. It can be corroded by strong bases (e.g. hydroxide solutions > 10 %, diethylamine). It is not recommended for the use with fluoric acid and fluorides.

Stainless Steel (SST) Stainless steel is inert against many common solvents. It is stable in the presence of acids and bases in a pH range of 1 to 12.5. It can be corroded by acids below pH 2.3. It can also corrode in following solvents: Solutions of alkali halides, their respective acids (for example, lithium iodide,

potassium chloride, and so on) and aqueous solutions of halogens. High concentrations of inorganic acids like nitric acid, sulfuric acid and

organic solvents especially at higher temperatures (replace, if your chromatography method allows, by phosphoric acid or phosphate buffer which are less corrosive against stainless steel).

Halogenated solvents or mixtures which form radicals and/or acids, for example: 2 CHCl3 + O2 2 COCl2 + 2 HCl

This reaction, in which stainless steel probably acts as a catalyst, occurs quickly with dried chloroform if the drying process removes the stabilizing alcohol.

Chromatographic grade ethers, which can contain peroxides (for example, THF, dioxane, diisopropylether). Such ethers should be filtered through dry aluminium oxide which adsorbs the peroxides.

Solutions of organic acids (acetic acid, formic acid, and so on) in organic solvents. For example, a 1 % solution of acetic acid in methanol will attack steel.

Solutions containing strong complexing agents (for example, EDTA, ethylene diamine tetra-acetic acid).

Mixtures of carbon tetrachloride with isopropanol or THF.

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4 Preparing the Module Solvent Information

Titanium (Ti)

Titanium is highly resistant to oxidizing acids (for example, nitric, perchloric and hypochlorous acid) over a wide range of concentrations and temperatures. This is due to a thin oxide layer on the surface, which is stabilized by oxidizing compounds. Non-oxidizing acids (for example, hydrochloric, sulfuric and phosphoric acid) can cause slight corrosion, which increases with acid concentration and temperature. For example, the corrosion rate with 3 % HCl (about pH 0.1) at room temperature is about 13 m/year. At room temperature, titanium is resistant to concentrations of about 5 % sulfuric acid (about pH 0.3). Addition of nitric acid to hydrochloric or sulfuric acids significantly reduces corrosion rates. Titanium is sensitive to acidic metal chlorides like FeCl3 or CuCl2. Titanium is subject to corrosion in anhydrous methanol, which can be avoided by adding a small amount of water (about 3 %). Slight corrosion is possible with ammonia > 10 %.

Diamond-Like Carbon (DLC)

Diamond-Like Carbon is inert to almost all common acids, bases and solvents. There are no documented incompatibilities for HPLC applications.

Fused silica and Quartz (SiO2)

Fused silica is used in Max Light Cartridges. Quartz is used for classical flow cell windows. It is inert against all common solvents and acids except hydrofluoric acid and acidic solvents containing fluorides. It is corroded by strong bases and should not be used above pH 12 at room temperature. The corrosion of flow cell windows can negatively affect measurement results. For a pH greater than 12, the use of flow cells with sapphire windows is recommended.

Gold

Gold is inert to all common HPLC solvents, acids and bases within the specified pH range. It can be corroded by complexing cyanides and concentrated acids like aqua regia.

Zirconium Oxide (ZrO2)

Zirconium Oxide is inert to almost all common acids, bases and solvents. There are no documented incompatibilities for HPLC applications.

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4 Preparing the Module Solvent Information

Platinum/Iridium

Platinum/Iridium is inert to almost all common acids, bases and solvents. There are no documented incompatibilities for HPLC applications.

Fluorinated polymers (PTFE, PFA, FEP, FFKM, PVDF)

Fluorinated polymers like PTFE (polytetrafluorethylene), PFA (perfluoroalkoxy), and FEP (fluorinated ethylene propylene) are inert to almost all common acids, bases, and solvents. FFKM is perfluorinated rubber, which is also resistant to most chemicals. As an elastomer, it may swell in some organic solvents like halogenated hydrocarbons.

TFE/PDD copolymer tubings, which are used in all Agilent degassers except 1322A/G7122A, are not compatible with fluorinated solvents like Freon, Fluorinert, or Vertrel. They have limited life time in the presence of hexafluoroisopropanol (HFIP). To ensure the longest possible life with HFIP, it is best to dedicate a particular chamber to this solvent, not to switch solvents, and not to let dry out the chamber. For optimizing the life of the pressure sensor, do not leave HFIP in the chamber when the unit is off.

The tubing of the leak sensor is made of PVDF (polyvinylidene fluoride), which is incompatible with the solvent DMF (dimethyl formamide).

Sapphire, Ruby and Al2O3-based ceramics

Sapphire, ruby and ceramics based on aluminum oxide Al2O3 are inert to almost all common acids, bases and solvents. There are no documented incompatibilities for HPLC applications.

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4 Preparing the Module Capillary Coding Guide

Capillary Coding Guide

Syntax for Capillary Description The tables below are your guide to identifying the proper specifications for your capillary. On all capillaries, dimensions are noted in id (mm), length (mm) and, where applicable, volume (L). When you receive your capillary, these abbreviations are printed on the packaging.

Using the guide: This fitting is coded as SPF, for Swagelok, PEEK, Fingertight.

Table 10 Capillary coding guide

Type The type gives some indication on the pri- mary function, like a loop or a connection capillary.

Material The material indicates which raw material is used.

Fitting left/fitting right The fitting left/right indicate which fitting is used on both ends of the capillary.

Key Descrip- tion

Key Descrip- tion

Key Descrip- tion

Capillary Connec- tion capil- laries

SS Stainless steel

W Swagelok + 0.8 mm Port id

Loop Loop cap- illaries

Ti Titanium S Swagelok + 1.6 mm Port id

Seat Autosam- pler needle seats

PK PEEK M Metric M4 + 0.8 mm Port id

Tube Tubing FS/PK PEEK-coat ed fused silica1

E Metric M3 + 1.6 mm Port id

Heat exchanger

Heat exchanger

PK/SS Stainless steel-coat ed PEEK2

U Swagelok union

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4 Preparing the Module Capillary Coding Guide

PFFE PTFE L Long

FS Fused sil- ica

X Extra long

MP35N Nickel-cob alt-chro- mium-mol ybdenium alloy

H Long head

G Small head SW 4

N Small head SW 5

F Fin- ger-tight

V 1200 bar

B Bio

P PEEK

I Intermedi- ate

1 Fused silica in contact with solvent

2 Stainless steel-coated PEEK

Table 10 Capillary coding guide

Type The type gives some indication on the pri- mary function, like a loop or a connection capillary.

Material The material indicates which raw material is used.

Fitting left/fitting right The fitting left/right indicate which fitting is used on both ends of the capillary.

Key Descrip- tion

Key Descrip- tion

Key Descrip- tion

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4 Preparing the Module Capillary Coding Guide

At-a-Glance Color-Coding Keys The color of your capillary will help you quickly identify the capillary id.

Table 11 Color-coding key for Agilent capillary tubing

Internal diameter in mm

Color code

0.015 Orange

0.025 Yellow

0.05 Beige

0.075 Black

0.075 MP35N Black with orange stripe

0.1 Purple

0.12 Red

0.12 MP35N Red with orange stripe

0.17 Green

0.17 MP35N Green with orange stripe

0.20/0.25 Blue

0.20/0.25 MP35N Blue with orange stripe

0.3 Grey

0.50 Bone White

HINT As you move to smaller-volume, high efficiency columns, youll want to use narrow id tubing, as opposed to the wider id tubing used for conventional HPLC instruments

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4 Preparing the Module Installing Capillaries

Installing Capillaries

Capillaries and connections depend on which system is installed.

Table 12 Capillary connections for 1260 Infinity II systems

p/n From To

Bottle Head Assembly (G7120-60007) Solvent Bottle Infinity II Pump

Capillary ST 0.17 mm x 500 mm SI/SI (5500-1246) Pump Sampler

Capillary, ST, 0.17 mm x 900 mm SI/SX (5500-1217) Pump Vialsampler with ICC

Capillary ST 0.17 mm x 500 mm SI/SI (5500-1246) Multisampler MCT Valve/Heat Exchanger

Capillary, ST, 0.17 mm x 400 mm SL/SL (5500-1252) Vialsampler MCT Valve/Heat Exchanger

Capillary ST 0.17 mm x 105 mm SL/SL (5500-1240) Vialsampler ICC Heat Exchanger

Capillary, ST, 0.17 mm x 120 mm SL/SL, long socket (5500-1250)

ICC Heat Exchanger Column

InfinityLab Quick Turn Capillary ST 0.17 mm x 105 mm, long socket (5500-1193)

MCT Heat Exchanger Column

InfinityLab Quick Turn Capillary ST 0.12 mm x 280 mm, long socket (5500-1191)

Column/MCT Valve Detector

Waste accessory kit (5062-8535) VWD Waste

Tube PTFE 0.7 mm x 5 m, 1.6 mm od (5062-2462) DAD/FLD Waste

Analytical tubing kit 0.25 mm i.d. PTFE-ESD (G5664-68712) Detector Fraction Collector

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4 Preparing the Module Installing Capillaries

Table 13 Capillary connections for 1290 Infinity II systems

p/n From To

Bottle Head Assembly (G7120-60007) Solvent Bottle Infinity II Pump

Capillary ST 0.17 mm x 400 mm SI/SI (5500-1245) Pump Sampler

Capillary, ST, 0.17 mm x 900 mm SI/SX (5500-1217) Pump Vialsampler with ICC

Capillary ST, 0.12 mm x 500 mm SL/S (5500-1157) Multisampler MCT Valve/Heat Exchanger

Capillary ST 0.12 mmX 400 mm SL/SL (5500-1251) Vialsampler MCT Valve/Heat Exchanger

Capillary ST 0.12 mm x 105 mm SL/SL (5500-1238) Vialsampler ICC Heat Exchanger

Capillary ST 0.12 mm x 120 mm SL/SL, long socket (5500-1249)

ICC Heat Exchanger Column

Capillary ST 0.12 mm x 105 mm SL/ (5500-1201) MCT Heat Exchanger Column

InfinityLab Quick Turn Capillary ST 0.12 mm x 280 mm, long socket (5500-1191)

Column/MCT Valve Detector

Waste accessory kit (5062-8535) VWD Waste

Tube PTFE 0.7 mm x 5 m, 1.6 mm od (5062-2462) DAD/FLD Waste

Analytical tubing kit 0.25 mm i.d. PTFE-ESD (G5664-68712) Detector Fraction Collector

Table 14 Capillary connections for 1260 Infinity II Bio-inert LC

p/n From To

Bottle Head Assembly (G7120-60007) Solvent Bottle Infinity II Pump

Capillary Ti 0.17 mm x 500 mm, SL/SLV (5500-1264) Pump Multisampler

Capillary PK/ST 0.17 mm x 500 mm, RLO/RLO (Bio-inert) (G5667-81005)

Multisampler MCT

ZDV union (Bio-inert) (5067-4741) Capillary Bio-inert Heat Exchanger

Quick Connect Heat Exchanger Bio-inert (G7116-60041)

Capillary Kit Flow Cells BIO includes Capillary PK 0.18 mm x 1.5 m and PEEK Fittings 10/PK (p/n 5063-6591) (G5615-68755)

Column/MCT Valve Detector

Waste accessory kit (5062-8535) VWD Waste

Tube PTFE 0.7 mm x 5 m, 1.6 mm od (5062-2462) DAD/FLD Waste

Analytical tubing kit 0.25 mm i.d. PTFE-ESD (G5664-68712) Detector Fraction Collector

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4 Preparing the Module Installing Capillaries

For correct installation of capillary connections it's important to choose the correct fittings, see Syntax for Capillary Description on page 69.

Table 15 Capillary connections for 1290 Infinity II Bio LC

p/n From To

Bottle Head Assembly (G7120-60007) Solvent Bottle Infinity II Pump

Capillary MP35N 0.17 mm x 500 mm, SI/SI (5500-1419) Pump Multisampler

Capillary MP35N 0.12 mm x 500 mm SI/SI (5500-1279) Multisampler MCT

Quick Connect Capillary MP35N 0.12 mm x 105 mm (5500-1578)

MCT Heat Exchanger Column

Quick Turn Capillary MP35N 0.12 mm x 280 mm (5500-1596) Column/MCT Valve Detector

Waste accessory kit (5062-8535) VWD Waste

Tube PTFE 0.7 mm x 5 m, 1.6 mm od (5062-2462) DAD/FLD Waste

Analytical tubing kit 0.25 mm i.d. PTFE-ESD (G5664-68712) Detector Fraction Collector

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4 Preparing the Module Installing Capillaries

1 Select a nut that is long enough for the fitting you'll be using.

2 Slide the nut over the end of the tubing or capillary.

3 Carefully slide the ferrule components on after the nut and then finger-tighten the assembly while ensuring that the tubing is completely seated in the bottom of the end fitting.

4 Use a column or injection valve to gently tighten the fit- ting which forces the ferrule to seat onto the tubing or capillary.

NOTE Don't overtighten. Overtightening will shorten the lifetime of the fitting.

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4 Preparing the Module Installing Capillaries

5 Loosen the nut and verify that the ferrule is correctly positioned on the tubing or capillary.

NOTE The first time that the swagelock fitting is used on a column or an injection valve, the position of the ferrule is permanently set. If changing from a column or an injection valve to another, the fitting may leak or decrease the quality of the separation by contributing to band broadening.

Agilent InfinityLab LC Series VWD User Manual 77

5 Optimizing the Detector

Introduction 78 Match the Flow Cell to the Column 79 Set the Detector Parameters 82 Warm up of the Detector 83

This chapter provides information on how to optimize the detector.

Agilent InfinityLab LC Series VWD User Manual 78

5 Optimizing the Detector Introduction

Introduction

The detector has a variety of parameters that can be used to optimize performance.

The information below will guide you on how to get the best detector performance. Follow these rules as a start for new applications. It gives a rule-of-thumb for optimizing the detector parameters.

Agilent InfinityLab LC Series VWD User Manual 79

5 Optimizing the Detector Match the Flow Cell to the Column

Match the Flow Cell to the Column

The tables below recommend the flow cell that matches the column used. If more than one selection is appropriate, use the larger flow cell to get the best detection limit. Use the smaller flow cell for best peak resolution.

Standard HPLC Applications

Figure 19 Choosing a Flow Cell (Standard HPLC Applications)

Ultra fast separation with RRLC systems

Figure 20 Choosing a Flow Cell for G7114B (for ultra fast separation with RRLC systems)

(+) For ultra fast analysis with step gradients the micro flow cell (2 L, 3 mm) gives the best performance

(++) In high resolution analysis time is not the highest priority. Higher delay volumes are accepted. Therefore we recommend to use the damper plus mixer for a highest signal to noise.

If longer columns (> 50 mm) for higher resolution are used, then the next larger flow cell is the preferred choice for higher sensitivity.

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5 Optimizing the Detector Match the Flow Cell to the Column

Flow Cell Path Length

Lambert-Beers law shows a linear relationship between the flow cell path length and absorbance.

where

Therefore, flow cells with longer path lengths yield higher signals. Although noise usually increases little with increasing path length, there is a gain in the signal-to-noise ratio. For example, in Figure 21 on page 81 the noise increased by less than 10 % but a 70 % increase in signal intensity was achieved by increasing the path length from 6 mm to 10 mm.

When increasing the path length, the cell volume usually increases in the example from 5 14 L. Typically, this causes more peak dispersion. As demonstrated, this did not affect the resolution in the gradient separation in the example that is shown below.

As a rule-of-thumb, the flow cell volume should be about 1/3 of the peak volume at half height. To determine the volume of your peaks, take the peak width as reported in the integration results multiply it by the flow rate and divide it by 3).

T is the transmission, defined as the quotient of the intensity of the transmitted light I divided by the intensity of the incident light, I0,

e is the extinction coefficient, which is a characteristic of a given substance under a pre- cisely-defined set of conditions of wavelength, solvent, temperature and other parame- ters,

C [mol/L] is the concentration of the absorbing species,

d [m] is the path length of the cell used for the measurement.

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5 Optimizing the Detector Match the Flow Cell to the Column

Figure 21 Influence of Cell Path Length on Signal Height

Traditionally LC analysis with UV detectors is based on comparing measurements with internal or external standards. To check photometric accuracy of the detector, it is necessary to have more precise information on path lengths of the flow cells.

The correct response is:

expected response * correction factor

Please find below the details of the flow cells:

A bs

o rb

an ce

Time (min)

Analysis of pesticide standard

10-mm optical path length

6-mm optical path length

Table 16 Correction factors for Agilent VWD flow cells

Part number Path length (actual) Correction factor

Standard flow cell 10 mm, 14 L, 40 bar (G1314-60186) 10.15 0.19 mm 10/10.15

Semi-micro flow cell 6 mm, 5 L (G1314-60183) 6.10 0.19 mm 6/6.10

Micro flow cell 3 mm, 2 L, 120 bar (G1314-60187) 2.80 0.19 mm 3/2.8

High pressure flow cell 10 mm, 14 L, 400 bar (G1314-60182) 10.00 0.19 mm 10/10

Bio standard flow cell VWD, 10 mm 14 l, RFID (G1314-60188) 10.15 0.19 mm 10/10.15

Bio micro flow cell VWD, 3 mm, 2 l, RFID (G1314-60189) 2.80 0.19 mm 3/2.8

NOTE However you have to be aware that there is additional tolerance of gasket thickness and its compression ratio which is supposed to be very small in comparison with the machining tolerance.

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5 Optimizing the Detector Set the Detector Parameters

Set the Detector Parameters

1 Set peakwidth as close as possible to the width (at half height) of a narrow peak of interest.

2 Choose the sample wavelength. at a longer wavelength than the cut-off wavelength of the mobile phase, at a wavelength where the analytes have strong absorptivity if you want to

get the lowest possible detection limit, at a wavelength with moderate absorptivity if you work with high

concentrations, and preferably where the spectrum is flat for better linearity.

3 Consider to use time-programming to further optimization.

Agilent InfinityLab LC Series VWD User Manual 83

5 Optimizing the Detector Warm up of the Detector

Warm up of the Detector

Give the optical unit enough time to warm-up and stabilize (> 60 minutes). The detector is temperature controlled. After turn-on of the detector, it goes through a cycle of different states: 0 to 0.5 minutes the heater control is OFF and the heater element runs at 0 %

duty cycle. 0.5 to 1 minutes the heater control is OFF and the heater element runs at 66%

duty cycle. This first minute is used as self-test of the heater functionality. 1 to 30 minutes the heater control is OFF and the heater element runs at 40%

duty cycle. After 30 minutes the heater control is ON and is working with optimized

parameters to get the optical unit into the optimal temperature window stabilized.

This cycle starts when the detector is turned off/on when the lamp is turned off/on

to ensure that the temperature control operates in a defined control range.

The figures below show the first two hours of a detector warm-up phase. The lamp was turned on immediately after turn on of the detector.

NOTE The times to stabilize the baseline may vary from instrument to instrument and depends on the environment. The example below was done under stable environmental conditions.

Agilent InfinityLab LC Series VWD User Manual 84

5 Optimizing the Detector Warm up of the Detector

Figure 22 Detector Warm-up 1st hour

Figure 23 Detector Warm-up 2nd hour

Agilent InfinityLab LC Series VWD User Manual 85

6 Troubleshooting and Diagnostics

Available Tests versus Interfaces 86 Agilent Lab Advisor Software 87

Overview about the troubleshooting and diagnostic features.

Agilent InfinityLab LC Series VWD User Manual 86

6 Troubleshooting and Diagnostics Available Tests versus Interfaces

Available Tests versus Interfaces

Preferred tool should be the Agilent Lab Advisor software, see Agilent Lab Advisor Software on page 87

Screenshots used within these procedures are based on the Agilent Lab Advisor software.

Figure 24 The Lab Advisor shows the available test

NOTE Depending on the used interface, the available tests and the screens/reports may vary.

Preferred tool should be the Agilent Lab Advisor, see Agilent Lab Advisor Software on page 87.

Agilent Lab Advisor B.02.08 or later is required.

The Instant Pilot (G4208A) supports the G7114B with B.02.19 and the G7114A with B.02.20 or later.

Agilent InfinityLab LC Series VWD User Manual 87

6 Troubleshooting and Diagnostics Agilent Lab Advisor Software

Agilent Lab Advisor Software

The Agilent Lab Advisor Software (basic license, shipped with an Agilent LC pump) is a standalone product that can be used with or without a chromatographic data system. Agilent Lab Advisor helps to manage the lab for high-quality chromatographic results by providing a detailed system overview of all connected analytical instruments with instrument status, Early Maintenance Feedback counters (EMF), instrument configuration information, and diagnostic tests. With the push of a button, a detailed diagnostic report can be generated. Upon request, the user can send this report to Agilent for a significantly improved troubleshooting and repair process. The Agilent Lab Advisor software is available in two versions: Lab Advisor Basic Lab Advisor Advanced

Lab Advisor Basic is included with every Agilent 1200 Infinity Series and Agilent InfinityLab LC Series instrument.

The Lab Advisor Advanced features can be unlocked by purchasing a license key, and include real-time monitoring of instrument actuals, all various instrument signals, and state machines. In addition, all diagnostic test results, calibration results, and acquired signal data can be uploaded to a shared network folder. The Review Client included in Lab Advisor Advanced allows to load and examine the uploaded data no matter on which instrument it was generated. This makes Data Sharing an ideal tool for internal support groups and users who want to track the instrument history of their analytical systems.

The optional Agilent Maintenance Wizard Add-on provides an easy-to-use, step-by-step multimedia guide for performing preventive maintenance on Agilent 1200 Infinity LC Series instrument.

The tests and diagnostic features that are provided by the Agilent Lab Advisor software may differ from the descriptions in this manual. For details, refer to the Agilent Lab Advisor software help files.

Agilent InfinityLab LC Series VWD User Manual 88

7 Error Information

What Are Error Messages 89 General Error Messages 90 Timeout 90 Shutdown 91 Remote Timeout 92 Lost CAN Partner 92 Leak 93 Leak Sensor Open 93 Leak Sensor Short 94 Compensation Sensor Open 94 Compensation Sensor Short 95 Fan Failed 95 Open Cover 96 ERI Messages 96

Detector Error Messages 97 UV lamp: no current 97 UV lamp: no voltage 98 Ignition Failed 98 No heater current 99 Wavelength calibration setting failed 100 Wavelength holmium check failed 101 Grating or Filter Motor Errors 102 Wavelength test failed 102 Cutoff filter doesn't decrease the light intensity at 250 nm 103 ADC Hardware Error 103 Illegal Temperature Value from Sensor on Main Board 104 Illegal Temperature Value from Sensor at Air Inlet 104 Heater at fan assembly failed 105 Heater Power At Limit 105 Cover Violation 106

This chapter describes the meaning of detector error messages, and provides information on probable causes and suggested actions how to recover from error conditions.

Agilent InfinityLab LC Series VWD User Manual 89

7 Error Information What Are Error Messages

What Are Error Messages

Error messages are displayed in the user interface when an electronic, mechanical, or hydraulic (flow path) failure occurs which requires attention before the analysis can be continued (for example, repair, or exchange of consumables is necessary). In the event of such a failure, the red status indicator at the front of the module is switched on, and an entry is written into the module logbook.

If an error occurs outside a method run, other modules will not be informed about this error. If it occurs within a method run, all connected modules will get a notification, all LEDs get red and the run will be stopped. Depending on the module type, this stop is implemented differently. For example, for a pump the flow will be stopped for safety reasons. For a detector, the lamp will stay on in order to avoid equilibration time. Depending on the error type, the next run can only be started, if the error has been resolved, for example liquid from a leak has been dried. Errors for presumably single time events can be recovered by switching on the system in the user interface.

Special handling is done in case of a leak. As a leak is a potential safety issue and may have occurred at a different module from where it has been observed, a leak always causes a shutdown of all modules, even outside a method run.

In all cases, error propagation is done via the CAN bus or via an APG/ERI remote cable (see documentation for the APG/ERI interface).

Agilent InfinityLab LC Series VWD User Manual 90

7 Error Information General Error Messages

General Error Messages

General error messages are generic to all Agilent series HPLC modules and may show up on other modules as well.

Timeout Error ID: 0062

The timeout threshold was exceeded.

Probable cause Suggested actions

1 The analysis was completed successfully, and the timeout function switched off the module as requested.

Check the logbook for the occurrence and source of a not-ready condition. Restart the analysis where required.

2 A not-ready condition was present during a sequence or multiple-injection run for a period longer than the timeout threshold.

Check the logbook for the occurrence and source of a not-ready condition. Restart the analysis where required.

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7 Error Information General Error Messages

Shutdown Error ID: 0063

An external instrument has generated a shutdown signal on the remote line.

The module continually monitors the remote input connectors for status signals. A LOW signal input on pin 4 of the remote connector generates the error message.

Probable cause Suggested actions

1 Leak detected in another module with a CAN connection to the system.

Fix the leak in the external instrument before restarting the module.

2 Leak detected in an external instrument with a remote connection to the system.

Fix the leak in the external instrument before restarting the module.

3 Shut-down in an external instrument with a remote connection to the system.

Check external instruments for a shut-down con- dition.

4 The degasser failed to generate sufficient vacuum for solvent degassing.

Check the vacuum degasser for an error condi- tion. Refer to the Service Manual for the degasser or the pump that has the degasser built-in.

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7 Error Information General Error Messages

Remote Timeout Error ID: 0070

A not-ready condition is still present on the remote input. When an analysis is started, the system expects all not-ready conditions (for example, a not-ready condition during detector balance) to switch to run conditions within one minute of starting the analysis. If a not-ready condition is still present on the remote line after one minute the error message is generated.

Lost CAN Partner Error ID: 0071

During an analysis, the internal synchronization or communication between one or more of the modules in the system has failed.

The system processors continually monitor the system configuration. If one or more of the modules is no longer recognized as being connected to the system, the error message is generated.

Probable cause Suggested actions

1 Not-ready condition in one of the instru- ments connected to the remote line.

Ensure the instrument showing the not-ready condition is installed correctly, and is set up cor- rectly for analysis.

2 Defective remote cable. Exchange the remote cable.

3 Defective components in the instrument showing the not-ready condition.

Check the instrument for defects (refer to the instruments documentation).

Probable cause Suggested actions

1 CAN cable disconnected. Ensure all the CAN cables are connected cor- rectly.

Ensure all CAN cables are installed correctly.

2 Defective CAN cable. Exchange the CAN cable.

3 Defective mainboard in another module. Switch off the system. Restart the system, and determine which module or modules are not rec- ognized by the system.

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7 Error Information General Error Messages

Leak Error ID: 0064

A leak was detected in the module.

The signals from the two temperature sensors (leak sensor and board-mounted temperature-compensation sensor) are used by the leak algorithm to determine whether a leak is present. When a leak occurs, the leak sensor is cooled by the solvent. This changes the resistance of the leak sensor which is sensed by the leak sensor circuit on the main board.

Leak Sensor Open Error ID: 0083

The leak sensor in the module has failed (open circuit).

The current through the leak sensor is dependent on temperature. A leak is detected when solvent cools the leak sensor, causing the leak sensor current to change within defined limits. If the current falls outside the lower limit, the error message is generated.

Probable cause Suggested actions

1 Loose fittings. Ensure all fittings are tight.

2 Broken capillary. Exchange defective capillaries.

3 Leaking flow cell. Exchange flow cell components.

Probable cause Suggested actions

1 Leak sensor not connected to the power switch board.

Please contact your Agilent service representa- tive.

2 Defective leak sensor. Please contact your Agilent service representa- tive.

3 Leak sensor incorrectly routed, being pinched by a metal component.

Please contact your Agilent service representa- tive.

4 Power switch assembly defective Please contact your Agilent service representa- tive.

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7 Error Information General Error Messages

Leak Sensor Short Error ID: 0082

The leak sensor in the module has failed (short circuit).

The current through the leak sensor is dependent on temperature. A leak is detected when solvent cools the leak sensor, causing the leak sensor current to change within defined limits. If the current increases above the upper limit, the error message is generated.

Compensation Sensor Open Error ID: 0081

The ambient-compensation sensor (NTC) on the power switch board in the module has failed (open circuit).

The resistance across the temperature compensation sensor (NTC) on the power switch board is dependent on ambient temperature. The change in resistance is used by the leak circuit to compensate for ambient temperature changes. If the resistance across the sensor increases above the upper limit, the error message is generated.

Probable cause Suggested actions

1 Defective leak sensor. Please contact your Agilent service representa- tive.

2 Leak sensor incorrectly routed, being pinched by a metal component.

Please contact your Agilent service representa- tive.

3 Power switch assembly defective Please contact your Agilent service representa- tive.

4 Cable or contact problem. Please contact your Agilent service representa- tive.

Probable cause Suggested actions

1 Loose connection between the power switch board and the mainboard

Please contact your Agilent service representa- tive.

2 Defective power switch assembly Please contact your Agilent service representa- tive.

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7 Error Information General Error Messages

Compensation Sensor Short Error ID: 0080

The ambient-compensation sensor (NTC) on the power switch board in the module has failed (open circuit).

The resistance across the temperature compensation sensor (NTC) on the power switch board is dependent on ambient temperature. The change in resistance is used by the leak circuit to compensate for ambient temperature changes. If the resistance across the sensor falls below the lower limit, the error message is generated.

Fan Failed Error ID: 0068

The cooling fan in the module has failed.

The hall sensor on the fan shaft is used by the mainboard to monitor the fan speed. If the fan speed falls below a certain limit for a certain length of time, the error message is generated.

This limit is given by 2 revolutions/second for longer than 5 seconds.

Depending on the module, assemblies (e.g. the lamp in the detector) are turned off to assure that the module does not overheat inside.

Probable cause Suggested actions

1 Defective power switch assembly Please contact your Agilent service representa- tive.

2 Loose connection between the power switch board and the mainboard

Please contact your Agilent service representa- tive.

Probable cause Suggested actions

1 Fan cable disconnected. Please contact your Agilent service representa- tive.

2 Defective fan. Please contact your Agilent service representa- tive.

3 Defective mainboard. Please contact your Agilent service representa- tive.

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7 Error Information General Error Messages

Open Cover Error ID: 0205

The top foam has been removed.

The sensor on the main board detects when the top foam is in place. If the foam is removed, the fan is switched off, and the error message is generated.

ERI Messages Error ID: 11120 (+5 V) , 11121 (+25 V)

The ERI (Enhanced Remote Interface) provides two error events related to over current situations on the +5 V and +24 V lines.

Probable cause Suggested actions

1 The top foam was removed during operation. Please contact your Agilent service representa- tive.

2 Foam not activating the sensor. Please contact your Agilent service representa- tive.

3 Defective sensor or main board. Please contact your Agilent service representa- tive.

Probable cause Suggested actions

1 The load on the ERI is too high. Reduce the load.

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7 Error Information Detector Error Messages

Detector Error Messages

These errors are detector specific.

UV lamp: no current Error ID: 7450

The lamp anode current is missing. The processor continually monitors the anode current drawn by the lamp during operation. If the anode current falls below the lower current limit, the error message is generated.

Probable cause Suggested actions

1 Lamp disconnected. Ensure the lamp connector is seated firmly.

2 Top foam removed while lamp is on. Please contact your Agilent service representa- tive.

3 Defective or non-Agilent lamp. Exchange the lamp.

4 Defective mainboard. Please contact your Agilent service representa- tive.

5 Defective power supply. Please contact your Agilent service representa- tive.

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7 Error Information Detector Error Messages

UV lamp: no voltage Error ID: 7451

The lamp anode voltage is missing. The processor continually monitors the anode voltage across the lamp during operation. If the anode voltage falls below the lower limit, the error message is generated.

Ignition Failed Error ID: 7452

The lamp failed to ignite. The processor monitors the lamp current during the ignition cycle. If the lamp current does not rise above the lower limit within 2 5 s, the error message is generated.

Probable cause Suggested actions

1 Defective or non-Agilent lamp. Exchange the lamp.

2 Defective power supply. Please contact your Agilent service representa- tive.

3 Defective mainboard. Please contact your Agilent service representa- tive.

Probable cause Suggested actions

1 Lamp disconnected. Ensure the lamp is connected.

2 Defective or non-Agilent lamp. Exchange the lamp.

3 Defective power supply. Please contact your Agilent service representa- tive.

4 Defective mainboard. Please contact your Agilent service representa- tive.

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7 Error Information Detector Error Messages

No heater current Error ID: 7453

The lamp heater current in the detector is missing. During lamp ignition, the processor monitors the heater current. If the current does not rise above the lower limit within 1, the error message is generated.

Probable cause Suggested actions

1 Lamp disconnected. Ensure the lamp is connected.

2 Ignition started without the top foam in place.

Please contact your Agilent service representa- tive.

3 Fan not running (permitting lamp on). Please contact your Agilent service representa- tive.

4 Defective mainboard. Please contact your Agilent service representa- tive.

5 Defective or non-Agilent lamp. Exchange the lamp.

6 Defective power supply. Please contact your Agilent service representa- tive.

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7 Error Information Detector Error Messages

Wavelength calibration setting failed Error ID: 7310

The intensity maximum was not found during wavelength calibration.

Calibration 0 Failed: Zero-order calibration failed.

Calibration 1 Failed: 656 nm calibration failed.

Probable cause Suggested actions

1 Lamp is OFF. Switch on the lamp.

2 Incorrect flow cell installation. Ensure the flow cell is installed correctly.

3 Flow cell contamination or air bubbles. Clean/replace flow cell windows or remove air bubbles.

4 Intensity too low. Replace lamp.

5 Current step value too far from maximum. Repeat the calibration.

Please contact your Agilent service represen- tative.

6 Misaligned/defective grating assembly. Please contact your Agilent service representa- tive.

7 Defective mainboard. Please contact your Agilent service representa- tive.

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7 Error Information Detector Error Messages

Wavelength holmium check failed Error ID: 7318

The holmium oxide test in the detector has failed. During the holmium test, the detector moves the holmium filter into the light path, and compares the measured absorbance maxima of the holmium oxide filter with expected maxima. If the measured maxima are outside the limits, the error message is generated.

Probable cause Suggested actions

1 Misaligned/defective grating assembly. Ensure the flow cell is inserted correctly, and is free from contamination (cell windows, buffers, and so on).

Run the filter-motor test to determine if the filter motor assembly is defective. If defec- tive, please contact your Agilent service rep- resentative.

Run the grating-motor test to determine if the grating assembly is defective. If defec- tive, please contact your Agilent service rep- resentative.

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7 Error Information Detector Error Messages

Grating or Filter Motor Errors Error ID: Grating: 7800, 7801, 7802, 7803, 7804, 7805, 7806, 7808, 7809; Filter: 7810, 7811, 7812, 7813, 7814, 7815, 7816

The motor test has failed.

During the motor tests, the detector moves the motor to the end position while monitoring the end-position sensor. If the end position is not found, the error message is generated.

Wavelength test failed Error ID: 7890

The automatic wavelength check after lamp ignition has failed. When the lamp is switched on, the detector waits 1 min to warm-up the lamp. Then a check of the deuterium emission line (656 nm) via the reference diode is performed. If the emission line is more than 3 nm away from 656 nm, the error message is generated.

Test 0 Failed: Filter motor.

Test 1 Failed: Grating motor.

Probable cause Suggested actions

1 Motor is not connected. Please contact your Agilent service representa- tive.

2 Defective motor. Please contact your Agilent service representa- tive.

3 Defective/missing grating or filter. Please contact your Agilent service representa- tive.

4 Cable/connector defective. Please contact your Agilent service representa- tive.

Probable cause Suggested actions

1 Calibration incorrect. Recalibrate the detector.

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7 Error Information Detector Error Messages

Cutoff filter doesn't decrease the light intensity at 250 nm Error ID: 7813

The automatic filter check after lamp ignition has failed. When the lamp is switched on, the detector moves the cutoff filter into the light path. If the filter is functioning correctly, a decrease in lamp intensity is seen. If the expected intensity decrease is not detected, the error message is generated.

ADC Hardware Error Error ID: 7830, 7831

A/D-Converter hardware is defective.

Probable cause Suggested actions

1 Motor is not connected. Please contact your Agilent service representa- tive.

2 Defective motor. Please contact your Agilent service representa- tive.

3 Defective/missing grating or filter. Please contact your Agilent service representa- tive.

4 Cable/connector defective. Please contact your Agilent service representa- tive.

Probable cause Suggested actions

1 A/D-Converter hardware is defective. Please contact your Agilent service representa- tive.

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7 Error Information Detector Error Messages

Illegal Temperature Value from Sensor on Main Board Error ID: 1071

This temperature sensor (located on the detector main board) delivered a value outside the allowed range. The parameter of this event equals the measured temperature in 1/100 centigrade. As a result the temperature control is switched off.

Illegal Temperature Value from Sensor at Air Inlet Error ID: 1072

This temperature sensor delivered a value outside the allowed range. The parameter of this event equals the measured temperature in 1/100 centigrade. As a result the temperature control is switched off.

Probable cause Suggested actions

1 Defective sensor or main board. Please contact your Agilent service representa- tive.

2 Detector is exposed to illegal ambient condi- tions.

Verify that the ambient conditions are within the allowed range.

Probable cause Suggested actions

1 The temperature sensor is defect. Replace the cable to the main board.

Please contact your Agilent service represen- tative.

2 Detector is exposed to illegal ambient condi- tions.

Verify that the ambient conditions are within the allowed range.

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7 Error Information Detector Error Messages

Heater at fan assembly failed Error ID: 1073

Every time the deuterium lamp or the tungsten lamp (DAD only) is switched on or off a heater self-test is performed. If the test fails an error event is created. As a result the temperature control is switched off.

Heater Power At Limit Error ID: 1074

The available power of the heater reached either the upper or lower limit. This event is sent only once per run. The parameter determines which limit has been hit:

0 means upper power limit hit (excessive ambient temperature drop).

1 means lower power limit hit (excessive ambient temperature increase).

Probable cause Suggested actions

1 Defective connector or cable. Please contact your Agilent service representa- tive.

2 Defective heater. Please contact your Agilent service representa- tive.

Probable cause Suggested actions

1 Excessive ambient temperature change. Wait until temperature control equilibrates.

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7 Error Information Detector Error Messages

Cover Violation Error ID: 7461

The top foam has been removed.

The sensor on the main board detects when the top foam is in place. If the foam is removed while the lamps are on (or if an attempt is made to switch on for example the lamps with the foam removed), the lamps are switched off, and the error message is generated.

Probable cause Suggested actions

1 The top foam was removed during operation. Please contact your Agilent service representa- tive.

2 Foam not activating the sensor. Please contact your Agilent service representa- tive.

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8 Test Functions

Introduction 108 Intensity Test 113 Intensity Test Evaluation 114 Intensity Test Failed 115

Cell Test 116 Cell Test Failed 117

Wavelength Verification-Calibration 118 When to Calibrate the Detector 118

ASTM Drift and Noise Test 120 Quick Noise Test 121 Dark Current Test 123 Dark Current Test Failed 124

Holmium Oxide Test 125 When to do the Test 125 Interpreting the Results 126 Holmium Oxide Test Failed 127

D/A Converter (DAC) Test 128 D/A Converter Test Evaluation 130

Other Lab Advisor Functions 131 EMFs - Early Maintenance Feature 131

This chapter describes the detectors built in test functions.

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8 Test Functions Introduction

Introduction

All tests are described based on the Agilent Lab Advisor Software B.02.08. Other user interfaces may not provide any test or just a few.

Table 17 Interfaces and available test functions

Interface Comment Available Function

Agilent Lab Advisor For functions, refer to Function Overview Lab Advisor G7114A/B(Table 18 on

page 109)

Available functions depend on Product Level (Basic Advanced FSE)

Agilent ChemStation No tests available Adding of temperature/lamp signals to chromatographic sig- nals possible

Temperature main board Temperature optical unit Lamp anode voltage

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8 Test Functions Introduction

Table 18 Function Overview Lab Advisor Basic/Advanced (G7114A/G7114B)

Function Product Level

Tests

- ASTM Drift and Noise Test

Basic Advanced

- Cell Test Basic Advanced

- D/A Converter Test Basic Advanced

- Dark Current Test Basic Advanced

- Filter/Grating Motor Test

Basic Advanced

- Holmium Oxide Test Basic Advanced

- Intensity Test Basic Advanced

- Quick Noise Test Basic Advanced

Calibrations

- Wavelength Calibra- tion

Basic Advanced

Tools

- Diagnostic Buffers Basic Advanced

- Board Check and Change

- Module Info Basic Advanced

- Firmware Decluster- ing

- Test Chromatogram Basic Advanced

- Spectral Scan Basic Advanced

Controls

- Advanced Method Parameters

- Analog Output 1 Attenuation

Advanced

- D2 lamp required Advanced

- Analog Output 1 Off- set [% Full Scale]

Advanced

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8 Test Functions Introduction

- Configuration

- Remote Pulse Dura- tion [s] *

Basic Advanced

- Analog Output 1 Range

Advanced

- Control

- Balance Detector Advanced

- UV Lamp Basic Advanced

- Conversions

- Transfer to Resident FW

- Transfer to Main FW *

- G7114B allows G1314E and G1314F

Basic Advanced

- G7114A allows NONE

Basic Advanced

- Method Parameters

- Set Data Rate [Hz] Advanced

- Set Wavelength [nm] Advanced

- Module Information

- Firmware Version

- Identify Module Basic Advanced

- Special Commands

- Lamp tag required Basic Advanced

- Cell tag required Basic Advanced

- Clear Error Basic Advanced

- Detector Reset Basic Advanced

- Forced Cold Start

Table 18 Function Overview Lab Advisor Basic/Advanced (G7114A/G7114B)

Function Product Level

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8 Test Functions Introduction

Actuals

- Signal A [mAU] Advanced

- Sample Signal

- Reference Signal

Statemachines

- UV Lamp Basic Advanced

Signals

- Signal A [mAU] Advanced

- Sample Signal [mAU] Advanced

- Reference Signal [mAU]

Advanced

- Board Temperature [C]

Advanced

- Lamp Voltage [V] Advanced

EMF Counters

- Accumulated UV Lamp On-Time

Basic Advanced

- Number of UV Lamp Ignitions

Basic Advanced

Table 18 Function Overview Lab Advisor Basic/Advanced (G7114A/G7114B)

Function Product Level

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8 Test Functions Introduction

Figure 25 The Lab Advisor shows the available test

Agilent InfinityLab LC Series VWD User Manual 113

8 Test Functions Intensity Test

Intensity Test

The intensity test measures the intensity of the deuterium lamp over the full VWD wavelength range (190 - 600 nm). The test can be used to determine the performance of the lamp, and to check for dirty or contaminated flow cell windows. When the test is started, the gain is set to zero. To eliminate effects due to absorbing solvents, the test should be done with water in the flow cell. The shape of the intensity spectrum is primarily dependent on the lamp, grating, and diode characteristics. Therefore, intensity spectra will differ slightly between instruments. The figure below shows a typical intensity test spectrum.

The Intensity Test is available in Agilent Lab Advisor (preferred tool).

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8 Test Functions Intensity Test

Intensity Test Evaluation The Agilent Lab Advisor and the Instant Pilot evaluate three values automatically and display the limits for each value, the average, the minimum and the maximum of all data points and passed or failed for each value. 1 Run the Intensity-Test with Agilent Lab Advisor (for further information see

Online-Help of user interface).

Figure 26 Intensity Test Results

Figure 27 Intensity Test Signal

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8 Test Functions Intensity Test

Intensity Test Failed

Intensity Test Failed

Probable cause Suggested actions

1 Empty flow cell Ensure the flow cell is filled with water.

2 Flow cell windows dirty Repeat the test with the flow cell window removed. If the test passes, exchange the flow cell windows.

3 Optics defect Please contact your Agilent service representa- tive.

4 Defective lamp or optics. Exchange the lamp.

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8 Test Functions Cell Test

Cell Test

The cell test compares the intensity of the deuterium lamp measured by the sample and reference diodes (unfiltered and not logarithmized) when the grating is in the zero-order position. The resulting intensity ratio (sample:reference) is a measure of the amount of light absorbed by the flow cell.

The test can be used to check for dirty or contaminated flow cell windows. When the test is started, the gain is set to -1. To eliminate effects due to absorbing solvents, the test should be done with water in the flow cell.

Limits: No real limit. The reason is that it depends on the position/alignment of the reference side (beam splitter reference slit reference diode). Therefore the reference side value can be higher/smaller than the sample side value.

With a clean cell the counts for sample and reference (photocurrent) are in the same range. If the sample side shows much lower values than the reference side the flow cell might have a problem.

Prerequisites Flush the flow cell with a flow of 1 mL/min for at least 10 minutes.

1 Run the Cell-Test with Agilent Lab Advisor (for further information see Online-Help of user interface).

Figure 28 Test Results

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8 Test Functions Cell Test

Cell Test Failed

Cell Test Failed

Probable cause Suggested actions

1 Cell contaminated Flush flow cell

2 Cell windows are contaminated Clean/replace cell windows

3 Mechanical problem Check cell position

Agilent InfinityLab LC Series VWD User Manual 118

8 Test Functions Wavelength Verification-Calibration

Wavelength Verification-Calibration

Wavelength calibration of the detector is done using the zero-order position and 656 nm emission line position of the deuterium lamp. The calibration procedure involves two steps. First the grating is calibrated on the zero-order position. The stepper-motor step position where the zero-order maximum is detected is stored in the detector. Next, the grating is calibrated against the deuterium emission-line at 656 nm, and the motor position at which the maximum occurs is stored in the detector.

In addition to the zero-order and 656 nm (alpha-emission line) calibration, the beta-emission line at 486 nm and the three holmium lines are used for the complete wavelength calibration process. These holmium lines are at 360.8 nm, 418.5 nm and 536.4 nm.

When the lamp is turned ON, the 656 nm emission line position of the deuterium lamp is checked automatically.

The Wavelength Verification/Calibration is available in Agilent Lab Advisor (preferred tool).

When to Calibrate the Detector The detector is calibrated at the factory, and under normal operating conditions should not require recalibration. However, it is advisable to recalibrate: after maintenance (flow cell or lamp), after repair of components in the optical unit, after exchange of the optical unit or VWM board, at a regular interval, at least once per year (for example, prior to an

Operational Qualification/Performance Verification procedure), and when chromatographic results indicate the detector may require recalibration.

NOTE The wavelength verification/calibration takes about 2.5 min and is disabled within the first 10 min after ignition of the lamp because initial drift may distort the measurement.

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8 Test Functions Wavelength Verification-Calibration

1 Run the Wavelength Calibration with the Agilent Lab Advisor (for further information see Online-Help of user interface).

Figure 29 Wavelength Calibration - Results

If you select No, the test is aborted. If you select Yes, the re-calibration is performed (the offset is corrected).

NOTE If the detector was repaired (opened covers), the wavelength calibration can be done 10 minutes after lamp on. A final wavelength calibration should be repeated after complete warm-up of the detector.

Agilent InfinityLab LC Series VWD User Manual 120

8 Test Functions ASTM Drift and Noise Test

ASTM Drift and Noise Test

The ASTM Drift and Noise test determines the detector noise over a period of 20 minutes. The test is done with HPLC-grade water flowing through the flow cell at 1 mL/min. On completion of the test, the noise result is displayed automatically. 1 Run the ASTM Drift and Noise Test with Agilent Lab Advisor (for further

information see Online- Help of user interface).

Figure 30 ASTM Drift and Noise Test Results

Figure 31 Drift and Noise Test Signal

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8 Test Functions Quick Noise Test

Quick Noise Test

The noise test measures the noise of the detector, with HPLC-grade water flowing through the flow cell at 1 mL/min, in one minute intervals over a total of 5 minutes.

The noise of the detector is calculated by using the maximum amplitude for all random variations of the detector signal of frequencies greater than one cycle per hour. The noise is determined for 5 one minute intervals and is based on the accumulated peak-to-peak noise for the intervals. At least seven data points per cycles are used in the calculation.

The cycles in the noise determination are not overlapping.

In order to obtain reliable results, the lamp should be turned on for at least 10 minutes prior to measurement. 1 Run the Quick Noise Test with Agilent Lab Advisor (for further information see

Online-Help of user interface).

Figure 32 Quick Noise Test Results

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8 Test Functions Quick Noise Test

Figure 33 Quick Noise Test Signal

Agilent InfinityLab LC Series VWD User Manual 123

8 Test Functions Dark Current Test

Dark Current Test

The dark-current test measures the leakage current from the sample and reference circuits. The test is used to check for defective sample or reference diodes or ADC circuits which may cause non-linearity or excessive baseline noise. During the test, the shutter is moved into the light path. Next, the leakage current from both diodes is measured. 1 Run the Dark Current Test with the Agilent Lab Advisor (for further information

see Online-Help of user interface).

Figure 34 Dark Current Test - Results

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8 Test Functions Dark Current Test

Figure 35 Dark Current Test - Signals

Dark Current Test Failed

Dark Current Test Failed

Probable cause Suggested actions

1 Defective sample or reference diode. Replace optical unit.

2 Defective sample or reference ADC board. Replace optical unit.

3 Defective main board. Exchange the main board.

Agilent InfinityLab LC Series VWD User Manual 125

8 Test Functions Holmium Oxide Test

Holmium Oxide Test

This test verifies the calibration of the detector against the three wavelength maxima of the built-in holmium oxide filter. The test displays the difference between the expected and measured maxima. The figure below shows a holmium test spectrum.

The Holmium Oxide Test is available in Agilent Lab Advisor (preferred tool). The test uses the following holmium maxima: 360.8 nm 418.5 nm 536.4 nm

When to do the Test after recalibration, as part of the Operational Qualification/Performance Verification procedure,

or after flow cell maintenance or repair.

NOTE See also Declaration of Conformity for HOX2 Filter on page 233.

Agilent InfinityLab LC Series VWD User Manual 126

8 Test Functions Holmium Oxide Test

Interpreting the Results The test is passed successfully when all three wavelengths are within 1 nm of the expected value. This indicates the detector is calibrated correctly. 1 Run the Holmium Oxide Test with the Agilent Lab Advisor (for further

information see Online- Help of user interface).

Figure 36 Holmium Oxide Test - Results

Figure 37 Holmium Oxide Test - Signals

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8 Test Functions Holmium Oxide Test

Holmium Oxide Test Failed

Holmium Oxide Test Failed

Probable cause Suggested actions

1 Detector not calibrated. Recalibrate the detector.

2 Dirty or defective flow cell. Repeat the test with the flow cell removed. If the test is OK, exchange the flow cell components.

3 Dirty or defective holmium oxide filter. Run the holmium oxide filter test. If the test fails, contact your Agilent service representative.

4 Optical misalignment. Please contact your Agilent service representa- tive.

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8 Test Functions D/A Converter (DAC) Test

D/A Converter (DAC) Test

The detector provides analog output of chromatographic signals for use with integrators, chart recorders or data systems. The analog signal is converted from the digital format by the digital-analog-converter (DAC).

The DAC test is used to verify correct operation of the digital-analog-converter by applying a digital test signal to the DAC.

The DAC outputs an analog signal of approximately 50 mV (if the zero offset of the analog output is set to the default value of 5 %) which can be plotted on an integrator. A continuous square wave with an amplitude of 10 V and a frequency of approximately 1 cycle/24 seconds is applied to the signal.

The amplitude of the square wave and the peak-to-peak noise are used to evaluate the DAC test.

When If the analog detector signal is noisy or missing.

Preparations Lamp must be on for at least 10 minutes. Connect integrator, chart recorder or data system to the detector analog output.

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8 Test Functions D/A Converter (DAC) Test

Running the test with Agilent Lab Advisor 1 Run the D/A Converter Test with the Agilent Lab Advisor (for further

information see Online- Help of user interface).

Figure 38 Converter Test - Results

Figure 39 D/A Converter (DAC) Test Example of Integrator Plot

Running the Test with Instant Pilot

The test can be started via the command line. 1 To start the test

TEST: DAC 1

Reply: RA 00000 TEST:DAC 1 2 To stop the test

TEST:DAC 0

Reply: RA 00000 TEST:DAC 0

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8 Test Functions D/A Converter (DAC) Test

D/A Converter Test Evaluation

Test Evaluation

The noise on the step should be less than 3 V.

Probable cause Suggested actions

1 Bad cable or grounding problem between detector and external device.

Check or replace the cable.

2 Defective detector main board. Please contact your Agilent service representa- tive.

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8 Test Functions Other Lab Advisor Functions

Other Lab Advisor Functions

EMFs - Early Maintenance Feature The EMFs screen allows you to view and manage the EMF counters for all modules in all systems.

Figure 40 EMFs

Agilent InfinityLab LC Series VWD User Manual 132

9 Maintenance

Introduction to Maintenance 133 Warnings and Cautions 134 Overview of Maintenance 136 Cleaning the Module 137 Remove and Install the Doors 138 Replace the Deuterium Lamp 140 Replace the Flow Cell / Cuvette Holder 143 Repair the Flow Cells 145 Using the Cuvette Holder 149 Correcting Leaks 151 Replace Leak Handling System Parts 153 Replace the Module Firmware 154

This chapter provides general information on maintenance of the detector.

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9 Maintenance Introduction to Maintenance

Introduction to Maintenance

The module is designed for easy maintenance. Maintenance can be done from the front with module in place in the system.

NOTE There are no serviceable parts inside.

Do not open the module.

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9 Maintenance Warnings and Cautions

Warnings and Cautions

WARNING Toxic, flammable and hazardous solvents, samples and reagents

The handling of solvents, samples and reagents can hold health and safety risks.

When working with these substances observe appropriate safety procedures (for example by wearing goggles, safety gloves and protective clothing) as described in the material handling and safety data sheet supplied by the vendor, and follow good laboratory practice.

The volume of substances should be reduced to the minimum required for the analysis.

Do not operate the instrument in an explosive atmosphere.

WARNING Eye damage by detector light

Eye damage may result from directly viewing the UV-light produced by the lamp of the optical system used in this product.

Always turn the lamp of the optical system off before removing it.

WARNING Electrical shock

Repair work at the module can lead to personal injuries, e.g. shock hazard, when the cover is opened.

Do not remove the cover of the module.

Only certified persons are authorized to carry out repairs inside the module.

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9 Maintenance Warnings and Cautions

WARNING Personal injury or damage to the product

Agilent is not responsible for any damages caused, in whole or in part, by improper use of the products, unauthorized alterations, adjustments or modifications to the products, failure to comply with procedures in Agilent product user guides, or use of the products in violation of applicable laws, rules or regulations.

Use your Agilent products only in the manner described in the Agilent product user guides.

CAUTION Safety standards for external equipment

If you connect external equipment to the instrument, make sure that you only use accessory units tested and approved according to the safety standards appropriate for the type of external equipment.

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9 Maintenance Overview of Maintenance

Overview of Maintenance

The following pages describe maintenance (simple repairs) of the detector that can be carried out without opening the main cover.

Table 19 Simple Repairs

Procedures Typical Frequency Notes

Deuterium lamp exchange

If noise and/or drift exceeds your application limits or lamp does not ignite.

A wavelength calibration test and an intensity test should be performed after replacement.

Flow cell exchange If application requires a different flow cell type. A wavelength calibration test should be performed after replacement.

Cleaning flow cell parts cleaning or exchange

If leaking or if intensity drops due to contaminated flow cell windows.

A pressure tightness test should be done after repair.

Leak sensor drying If leak has occurred. Check for leaks.

Leak handling system replacement

If broken or corroded. Check for leaks.

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9 Maintenance Cleaning the Module

Cleaning the Module

To keep the module case clean, use a soft cloth slightly dampened with water, or a solution of water and mild detergent. Avoid using organic solvents for cleaning purposes. They can cause damage to plastic parts.

WARNING Liquid dripping into the electronic compartment of your module can cause shock hazard and damage the module

Do not use an excessively damp cloth during cleaning.

Drain all solvent lines before opening any connections in the flow path.

NOTE A solution of 70 % isopropanol and 30 % water might be used if the surface of the module needs to be disinfected.

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9 Maintenance Remove and Install the Doors

Remove and Install the Doors

Parts required p/n Description 5067-5737 Door left 5067-5736 Door right

NOTE The figures shown in this procedure exemplarily show the Infinity II Multisampler module.

The principle of how to remove and/or install doors works in the same way for all Infinity II modules.

Agilent InfinityLab LC Series VWD User Manual 139

9 Maintenance Remove and Install the Doors

1 Press the release buttons and pull the front door out. 2 For the Installation of the front door. Insert the hinges into their guides and move the door in until the release buttons click into their final position.

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9 Maintenance Replace the Deuterium Lamp

Replace the Deuterium Lamp

When If noise or drift exceeds application limits or lamp does not ignite.

Tools required Description Screwdriver, Pozidriv #1 PT3

Parts required # p/n Description 1 G1314-60101 Deuterium lamp (with RFID tag)

Preparations Turn the lamp OFF.

WARNING Injury by touching hot lamp

If the detector has been in use, the lamp may be hot.

If so, wait for lamp to cool down.

WARNING Injury by sharp metal edges

Be careful when touching the RFI sheet metal at the rear of the fan. There are sharp edges.

CAUTION Electronic boards and components are sensitive to electrostatic discharge (ESD).

To prevent accidental electrostatic discharge when coming into contact with components inside the instrument, touch one of the metal housing panels at the front of the instrument.

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9 Maintenance Replace the Deuterium Lamp

1 Open the doors. 2 Locate the heater fan cover.

3 Unscrew the fan cover (1.) and remove it (2.). 4 Unplug the lamp connector.

5 Unscrew the two lamp screws (Pozidriv). 6 Remove the lamp and place it on a clean place.

NOTE Do not touch the glass bulb with your fingers. It may reduce the light output.

1.

2.

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9 Maintenance Replace the Deuterium Lamp

7 Insert the lamp (RFID tag on top) (1.) and fix the screws (2.).

8 Reconnect the connector.

9 Replace the fan cover (1.) and fix its screw (2.). 10 Close the doors.

Next Steps:

11 Reset the lamp counter as described in the User Interface documentation (required for non-RFID tag lamps only).

12 Turn the lamp ON and give the lamp more than 10 minutes to warm-up.

13 Perform a Wavelength Re-calibration after lamp warm-up.

1.

2.

1.

2.

NOTE After lamp on, the detector requires a warm-up time of 60 min. No measurements should be performed during this time.

Agilent InfinityLab LC Series VWD User Manual 143

9 Maintenance Replace the Flow Cell / Cuvette Holder

Replace the Flow Cell / Cuvette Holder

For flow cell details see: Standard Flow Cell 10 mm / 14 l on page 158 Micro Flow Cell 3 mm / 2 L on page 160 Semi-micro Flow Cell (Parts) on page 162 High Pressure Flow Cell (Parts) on page 164 Bio Standard Flow Cell on page 166 Bio Micro Flow Cell on page 168

When If application needs a different type of flow cell or the flow cell needs repair.

Tools required p/n Description Wrench, 1/4 inch for capillary connections

OR 5043-0915 Fitting mounting tool

Parts required # Description 1 Flow cell

Preparations Turn the lamp OFF.

1 Open the doors. 2 Disconnect the inlet capillary and outlet tubing from the flow cell.

1.

2.

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9 Maintenance Replace the Flow Cell / Cuvette Holder

3 Unscrew the two thumb screws. 4 Pull the flow cell out of its location.

5 Insert the flow cell into its location and press it in in the center of the flow cell.

6 Fix the two thumb screws parallel and tight.

7 Reconnect the inlet capillary and the outlet tubing. 8 Close the doors.

Next Steps:

9 Configure the flow cell. For further information see Agilent Information Center or the online help of your CDS.

10 Perform a Wavelength Verification-Calibration to check the correct position of the flow cell/cuvette holder.

2.

1.

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9 Maintenance Repair the Flow Cells

Repair the Flow Cells

For details on flow cells see: Standard Flow Cell 10 mm / 14 l on page 158 Micro Flow Cell 3 mm / 2 L on page 160 Semi-micro Flow Cell (Parts) on page 162 High Pressure Flow Cell (Parts) on page 164 Bio Standard Flow Cell on page 166 Bio Micro Flow Cell on page 168

Parts required # Description 1 Flow cell

NOTE The shown cell parts will differ depending upon the flow cell type. For detailed parts schematics, refer to above mentioned pages.

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9 Maintenance Repair the Flow Cells

1

2

2

3

1

4

5

6

4

7

8

1 Cell screw

2 Conical springs

3 Ring #1 PEEK

4 Window Quartz

5 Gasket #1 (small hole)

6 RFID tag

7 Gasket #2 (large hole)

8 Ring #2 PEEK

Agilent InfinityLab LC Series VWD User Manual 147

9 Maintenance Repair the Flow Cells

1 Disassembling the Flow Cell. a Unscrew the cell screw using a 4-mm hexagonal wrench. b Remove the SST rings using a pair of tweezers.

c Use adhesive tape to remove the peek ring, the window and the gasket. d Repeat step a through step c for the other window (keep the parts

separate - otherwise they could be mixed!). 2 Cleaning the Flow Cell Parts

a Pour isopropanol into the cell hole and wipe clean with a piece of lint-free cloth.

b Clean the windows with ethanol or methanol. Dry it with a piece of lint-free cloth.

3 Reassembling the Flow Cell a Hold the flow cell cassette horizontally and place gasket in position.

Ensure both cell holes can be seen through the holes of gasket.

b Place the window on gasket. c Place the peek ring on the window. d Insert the conical springs. Make sure the conical springs point towards the

window. Otherwise tightening the cell screw might break the window.

Figure 41 Orientation of conical springs

e Screw the cell screw into the flow cell and tighten the screw.

CAUTION Scratched window surfaces by tweezers

Window surfaces can easily be scratched by using tweezers for removing the windows.

Do not use tweezers to remove windows

NOTE Always use new gaskets.

NOTE The semi-micro #1 and #2 gaskets (items 6 and 7, Semi-micro Flow Cell (Parts) on page 162) look very similar. Do not mix them up.

Conical springs

Ring - Window - Gasket - Arrangement

Agilent InfinityLab LC Series VWD User Manual 148

9 Maintenance Repair the Flow Cells

4 Repeat the procedure for the other cell side. 5 Reconnect the capillaries. 6 Perform a leak test. If OK, insert the flow cell. 7 Perform Wavelength Verification-Calibration on page 118 to check the

correct positioning of the flow cell. 8 Replace the front cover.

Agilent InfinityLab LC Series VWD User Manual 149

9 Maintenance Using the Cuvette Holder

Using the Cuvette Holder

This cuvette holder can be placed instead of a flow cell in the variable wavelength detector. Standard cuvettes with standards in it, for example, National Institute of Standards & Technology (NIST) holmium oxide solution standard, can be fixed in it.

This can be used for wavelength verifications.

When If your own standard should be used to checkout the instrument.

Parts required # p/n Description 1 G1314-60200 Cuvette Holder 1 Cuvette with the standard, e.g. NIST certified holmium oxide sample

Preparations Remove the normal flow cell. Have cuvette with standard available.

Agilent InfinityLab LC Series VWD User Manual 150

9 Maintenance Using the Cuvette Holder

1 Locate the cuvette holder on the desk. 2 Unscrew the bracket.

3 Insert the cuvette with the sample into the holder. The clear side of the cuvette must be visible.

4 Replace the bracket and fix the cuvette.

Next Steps:

5 Install the cuvette holder in the instrument.

6 Perform your Wavelength Verification/Calibration (see Wavelength Verification-Calibration on page 118) to check the correct position of the cuvette holder.

Light path Clear side

Agilent InfinityLab LC Series VWD User Manual 151

9 Maintenance Correcting Leaks

Correcting Leaks

Figure 42 Correcting leaks

Leak sensor area [1]

Flow cell area [2]

When If a leakage has occurred in the flow cell area or at the capillary connections.

Tools required Description Tissue Wrench, 1/4 inch for capillary connections

1 Open the doors. 2 Use tissue to dry the leak sensor area [1].

3 Observe the capillary connections and the flow cell area [2] for leaks and correct, if required.

Agilent InfinityLab LC Series VWD User Manual 152

9 Maintenance Correcting Leaks

4 Close the doors.

Agilent InfinityLab LC Series VWD User Manual 153

9 Maintenance Replace Leak Handling System Parts

Replace Leak Handling System Parts

Parts required p/n Description 5043-0856 Leak Adapter 5063-6527 Tubing, Silicon Rubber, 1.2 m, ID/OD 6/9 mm

Preparations Open or remove the doors

1 Locate the Leak Adapter [1] and Tubing [2] Next Steps:

2 Press the Leak Adapter [1] down and remove it together with the tubing.

3 Install the Leak Adapter by pressing it into the Main Cover.

4 Insert the Tubing [2] (ca. 85 mm required for replace- ment) between Leak Adapter outlet and Leak Pan.

5 Insert/close the doors.

(2)

(1)

Agilent InfinityLab LC Series VWD User Manual 154

9 Maintenance Replace the Module Firmware

Replace the Module Firmware

To upgrade/downgrade the modules firmware carry out the following steps: 1 Download the required module firmware, the latest FW Update Tool and the

documentation from the Agilent web. http://www.agilent.com/en-us/firmwareDownload?whid=69761

2 For loading the firmware into the module follow the instructions in the documentation.

Module Specific Information

When The installation of newer firmware might be necessary if a newer version solves problems of older versions or to keep all systems on the same (validated) revision. The installation of older firmware might be necessary to keep all systems on the same (validated) revision or if a new module with newer firmware is added to a system or if third party control software requires a special version.

Tools required Description Agilent Lab Advisor software

Parts required # Description 1 Firmware, tools and documentation from Agilent web site

Preparations Read update documentation provided with the Firmware Update Tool.

Table 20 Module Specific Information (G7114A/B)

G7114B G7114A

Initial firmware D.06.70 D.07.01

Compatibility with 1100 / 1200 series modules

When using the G7114A/B in a system, all other modules must have firmware from set 6.50 or above (main and resident). Other- wise the communication will not work.

Conversion / emulation Possible via Lab Advisor software: G7114B: G1314E/F G7114A: G1314F

Agilent InfinityLab LC Series VWD User Manual 155

10 Parts and Materials for Maintenance

Overview of Maintenance Parts 156 Standard Flow Cell 10 mm / 14 l 158 Micro Flow Cell 3 mm / 2 L 160 Semi-micro Flow Cell (Parts) 162 High Pressure Flow Cell (Parts) 164 Bio Standard Flow Cell 166 Bio Micro Flow Cell 168 Cuvette Holder (Parts) 170 Accessory Kit 171

This chapter provides information on parts for maintenance.

Agilent InfinityLab LC Series VWD User Manual 156

10 Parts and Materials for Maintenance Overview of Maintenance Parts

Overview of Maintenance Parts

Figure 43 Overview of maintenance parts

1

2

3 4

5

6

7

Agilent InfinityLab LC Series VWD User Manual 157

10 Parts and Materials for Maintenance Overview of Maintenance Parts

Item p/n Description

1 5067-5736 Door right

2 5067-5737 Door left

3 G1314-60101 Deuterium lamp (with RFID tag)

4 5043-0856 Leak Adapter

5 5063-6527 Tubing, Silicon Rubber, 1.2 m, ID/OD 6/9 mm

6 G1314-60186 Standard flow cell 10 mm, 14 L, 40 bar (with RFID tag)

OR 6 G1314-60187 Micro flow cell 3 mm, 2 L, 120 bar (with RFID tag)

OR 6 G1314-60183 Semi-micro flow cell 6 mm, 5 L (with RFID tag)

OR 6 G1314-60182 High pressure flow cell 10 mm, 14 L, 400 bar (with RFID tag)

OR 6 G1314-60023 Prep flow cell 0.06 mm

OR 6 G1314-60025 Prep flow cell 0.3 mm

OR 6 G1314-60024 Prep flow cell 3 mm

OR 6 G1314-60188 Bio standard flow cell VWD, 10 mm14 l, RFID

OR 6 G1314-60189 Bio micro flow cell VWD, 3 mm, 2 l, RFID

5062-8535 Waste accessory kit (Flow Cell to Waste)

7 5043-1013 Tubing Clip

Agilent InfinityLab LC Series VWD User Manual 158

10 Parts and Materials for Maintenance Standard Flow Cell 10 mm / 14 l

Standard Flow Cell 10 mm / 14 l

Item p/n Description

G1314-60186 Standard flow cell 10 mm, 14 L, 40 bar (with RFID tag)

5062-8522 Capillary column - detector PEEK 600 mm lg, 0.17 mm i.d., 1/16 inch o.d.

G1314-65061 Cell Repair Kit, includes 2x Gasket #1, 2x Gasket #2, 2x Window Quartz

1 G1314-65062 Cell screw kit

2 79853-29100 Conical spring kit, 10/pk

3 G1314-65065 Ring #1 kit (OUT large hole, i.d. 2.4 mm) PEEK, 2/pk

4 79853-68742 Window quartz kit, 2/pk

5 G1314-65063 Gasket #1 kit (OUT large hole, i.d. 2.4 mm) KAPTON, 2/pk

6 0515-4780 Screw for Clip, M2.2, 4.5 mm long

7 G1314-44010 Clip for RFI ID tag

8 G1314-65064 Gaskets #2 IN (small hole i.d. 1 mm), KAPTON 10/pk

9 G1314-65066 Ring #2 kit (IN small hole, i.d. 1 mm) PEEK, 2/pk

Agilent InfinityLab LC Series VWD User Manual 159

10 Parts and Materials for Maintenance Standard Flow Cell 10 mm / 14 l

Figure 44 Standard Flow Cell

1

2 (3x)

1

2 (3x)

3 4

4

5

6 7

8

9

Agilent InfinityLab LC Series VWD User Manual 160

10 Parts and Materials for Maintenance Micro Flow Cell 3 mm / 2 L

Micro Flow Cell 3 mm / 2 L

Item p/n Description

G1314-60187 Micro flow cell 3 mm, 2 L, 120 bar (with RFID tag)

5021-1823 Capillary column detector SST 400 mm lg, 0.12 mm i.d.

1 79883-22402 Window screw

2 5062-8553 Washer kit (10/pk)

3 79883-28801 Compression washer

4 79883-22301 Window holder

5 1000-0488 Quartz window

6 79883-68702 Gasket BACK (PTFE), 1.8 mm hole, outlet side (12/pk)

7 0515-4780 Screw for Clip, M2.2, 4.5 mm long

8 G1314-44010 Clip for RFI ID tag

9 G1315-68710 Gasket FRONT (PTFE), 1.3 mm hole, inlet side (12/pk)

G1314-87301 Capillary IN (0.12 mm, 310 mm lg)

G1314-87302 Capillary OUT (0.17 mm, 120 mm lg)

G1315-68713 Cell repair kit semi-micro, includes window screw kit, Gasket Kit BACK, Gasket Kit FRONT and 4 mm hexagonal wrench

79883-68703 Window screw kit, includes 2 quartz windows, 2 compression wash- ers, 2 window holders, 2 window screws and 10 washers

Agilent InfinityLab LC Series VWD User Manual 161

10 Parts and Materials for Maintenance Micro Flow Cell 3 mm / 2 L

Figure 45 Micro Flow Cell

1

3 4

5 6

1

2 (5x)

2 (5x) 3

4 5

9

7

8

Agilent InfinityLab LC Series VWD User Manual 162

10 Parts and Materials for Maintenance Semi-micro Flow Cell (Parts)

Semi-micro Flow Cell (Parts)

NOTE The semi-micro #1 and #2 gaskets (items 6 and 7) look very similar. Do not mix them up.

Item p/n Description

G1314-60183 Semi-micro flow cell 6 mm, 5 L (with RFID tag)

5021-1823 Capillary column detector SST 400 mm lg, 0.12 mm i.d.

1 G1314-20047 Cell screw

G1314-65056 Semi-micro cell kit, includes two quartz windows, one gasket #1, one #2 and two PTFE gaskets.

2 79853-29100 Conical spring kit, 10/pk

3 79853-22500 Ring SST, 2/pk

4 79853-68743 PTFE gasket (round hole i.d. 2.5 mm, o.d. 8 mm), (10/pk)

5 79853-68742 Window quartz kit, 2/pk

6 Semi-micro #1 gasket (long hole 1.5 x 3.5 mm), PTFE

7 Semi-micro #2 gasket (long hole 2 x 4 mm), PTFE

8 G1314-44010 Clip for RFI ID tag

9 0515-4780 Screw for Clip, M2.2, 4.5 mm long

Agilent InfinityLab LC Series VWD User Manual 163

10 Parts and Materials for Maintenance Semi-micro Flow Cell (Parts)

Figure 46 Semi-micro Flow Cell

1

1

2 (3x)

2 (3x)

3

3

4

4

5

5 6

7

8

9 1 - Cell screw

2 - Conical springs

3 - Ring SST

4 - PTFE gasket

5 - Quartz window

6 - Semi-micro gasket #1

7 - Semi-micro gasket #2

8 - Clip for RFI ID tag

9 - Screw for clip

Agilent InfinityLab LC Series VWD User Manual 164

10 Parts and Materials for Maintenance High Pressure Flow Cell (Parts)

High Pressure Flow Cell (Parts)

Item p/n Description

G1314-60182 High pressure flow cell 10 mm, 14 L, 400 bar (with RFID tag)

G1315-87311 Capillary ST 0.17 mm x 380 mm S/S

1 G1314-20047 Cell screw

G1314-65054 Cell kit Agilent, comprises: two windows, two KAPTON gaskets and two PEEK rings

2 Ring PEEK kit

3 Window quartz kit

4 Gasket kit, KAPTON

5 G1314-44010 Clip for RFI ID tag

6 0515-4780 Screw for Clip, M2.2, 4.5 mm long

Agilent InfinityLab LC Series VWD User Manual 165

10 Parts and Materials for Maintenance High Pressure Flow Cell (Parts)

Figure 47 High Pressure Flow Cell

1

2

3

4

1

2

3 4

5

6

1 - Cell screw

2 - Ring PEEK

3 - Quartz window

4 - Gasket KAPTON

5 - RFID Clip

6 - Screw

Agilent InfinityLab LC Series VWD User Manual 166

10 Parts and Materials for Maintenance Bio Standard Flow Cell

Bio Standard Flow Cell

Item # p/n Description

1 2 G1314-20047 Cell screw

2 6 5022-3942 Disc spring

3 1 G1314-20046 Ring (Out)

4 2 5190-0939 Sapphire window VWD

5 1 G1314-40044 Gasket Out Bio

6 1 G1314-40043 Gasket In Bio

7 1 G1314-20045 Ring (In)

8 1 G1314-60054 Cell Block Assembly VWD MP35N Fitting

9 1 5500-1297 Capillary MP35N 0.3 x 120 mm

10 1 G1314-20011 Cell shaft

11 1 G1314-60058 Cell-Plate Assembly Bio

12 2 0100-1259 Blank nut (plastic)

13 1 0515-1096 SCR-SKT-HD HEX M5X0.8 10 SST PSVT

14 1 G1314-87012 Label Standard RFID Bio

15 1 0515-4780 Screw for Clip, M2.2, 4.5 mm long

16 1 0960-2971 RF Transponder

17 1 G1314-44010 Clip for RFI ID tag

1 0470-0960 Sealant Methacrylate Ester Liquid

Agilent InfinityLab LC Series VWD User Manual 167

10 Parts and Materials for Maintenance Bio Standard Flow Cell

Figure 48 Bio Standard Flow Cell

1 2

3

4

4 5

6

7

8

9

10

11

12

13

14

15

16

17 2 1

Agilent InfinityLab LC Series VWD User Manual 168

10 Parts and Materials for Maintenance Bio Micro Flow Cell

Bio Micro Flow Cell

Item # p/n Description

1 1 79883-21701 Screw-Bushing 6

2 2 G1315-60021 Cell screw assembly (comprises window screw, spring wash- ers, compression washer, window holder and quartz window)

3 2 5190-0921 Sapphire window

4 1 79883-07101 Gasket

5 1 G1314-27201 VWD Cell Insert 3 mm MP35N

6 1 G1315-07101 Gasket Front 1.3

7 1 G1314-27700 VWD Cell Body 3 mm

8 1 0515-1056 Screw M 2.5, 4 mm lg for cell body/clamp

9 1 G1314-67003 Cap In VWD 3 mm MP35N

10 1 G1314-67004 Cap Out VWD 3 mm MP35N

11 1 G1314-20011 Cell shaft

12 1 G1314-60058 Cell-Plate Assembly Bio

13 2 0100-1259 Plastic fitting

14 1 0515-1096 SCR-SKT-HD HEX M5X0.8 10 SST PSVT

15 1 G1314-87013 Label micro RFID Bio

16 1 0515-4780 Screw for Clip, M2.2, 4.5 mm long

17 1 0960-2971 RF Transponder

18 1 G1314-44010 Clip for RFI ID tag

1 0470-0960 Sealant Methacrylate Ester Liquid

Agilent InfinityLab LC Series VWD User Manual 169

10 Parts and Materials for Maintenance Bio Micro Flow Cell

Figure 49 Bio Micro Flow Cell

1

2 3

4 5

6

7

8

9

10

11

12

13

14

15

16

2 3

17

18

Agilent InfinityLab LC Series VWD User Manual 170

10 Parts and Materials for Maintenance Cuvette Holder (Parts)

Cuvette Holder (Parts)

For information the use of the cuvette holder, refer to Using the Cuvette Holder on page 149.

Figure 50 Cuvette Holder

p/n Description

G1314-60200 Cuvette Holder

Agilent InfinityLab LC Series VWD User Manual 171

10 Parts and Materials for Maintenance Accessory Kit

Accessory Kit

Accessory kit (G7114-68755) contains some accessories and tools needed for installation and repair of the module.

p/n Description

5062-8535 Waste accessory kit

5063-6527 Tubing, Silicon Rubber, 1.2 m, ID/OD 6/9 mm (see item 4 in Figure 43 on page 156)

5181-1516 CAN cable, Agilent module to module, 0.5 m

5500-1155 Tube Connector, 90 degree, ID 6.4

5043-1013 Tubing Clip (see item 7 in Figure 43 on page 156)

0100-1516 Finger-tight fitting PEEK, 2/pk

Agilent InfinityLab LC Series VWD User Manual 172

11 Identifying Cables

Cable Overview 173 Analog Cables 175 Remote Cables 177 CAN Cable 181 RS-232 Cables 182 USB Cables 183

This chapter provides information on cables used with the Agilent 1200 Infinity Series modules.

Agilent InfinityLab LC Series VWD User Manual 173

11 Identifying Cables Cable Overview

Cable Overview

Analog cables

Remote cables

CAN cables

NOTE Never use cables other than the ones supplied by Agilent Technologies to ensure proper functionality and compliance with safety or EMC regulations.

p/n Description

35900-60750 Agilent 35900A A/D converter

01046-60105 Analog cable (BNC to general purpose, spade lugs)

p/n Description

5188-8029 ERI to general purpose

5188-8044 Remote Cable ERI ERI

5188-8045 Remote Cable APG ERI

5188-8059 ERI-Extension-Cable 1.2 m

5061-3378 Remote Cable to 35900 A/D converter

01046-60201 Agilent module to general purpose

5188-8057 Fraction Collection ERI remote Y-cable

p/n Description

5181-1516 CAN cable, Agilent module to module, 0.5 m

5181-1519 CAN cable, Agilent module to module, 1 m

Agilent InfinityLab LC Series VWD User Manual 174

11 Identifying Cables Cable Overview

LAN cables

RS-232 cables (not for

FUSION board)

USB cables

p/n Description

5023-0203 Cross-over network cable, shielded, 3 m (for point to point connection)

5023-0202 Twisted pair network cable, shielded, 7 m (for point to point connec- tion)

p/n Description

RS232-61601 RS-232 cable, 2.5 m Instrument to PC, 9-to-9 pin (female). This cable has special pin-out, and is not compatible with connecting printers and plotters. It is also called "Null Modem Cable" with full handshaking where the wiring is made between pins 1-1, 2-3, 3-2, 4-6, 5-5, 6-4, 7-8, 8-7, 9-9.

5181-1561 RS-232 cable, 8 m

p/n Description

5188-8050 USB A M-USB Mini B 3 m (PC-Module)

5188-8049 USB A F-USB Mini B M OTG (Module to Flash Drive)

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11 Identifying Cables Analog Cables

Analog Cables

One end of these cables provides a BNC connector to be connected to Agilent modules. The other end depends on the instrument to which connection is being made.

Agilent Module to 35900 A/D converters

p/n 35900-60750 35900 Pin Agilent module

Signal Name

1 Not connected

2 Shield Analog -

3 Center Analog +

Agilent InfinityLab LC Series VWD User Manual 176

11 Identifying Cables Analog Cables

Agilent Module to BNC Connector

Agilent Module to General Purpose

p/n 8120-1840 Pin BNC Pin Agilent module

Signal Name

Shield Shield Analog -

Center Center Analog +

p/n 01046-60105 Pin Pin Agilent module

Signal Name

1 Not connected

2 Black Analog -

3 Red Analog +

Agilent InfinityLab LC Series VWD User Manual 177

11 Identifying Cables Remote Cables

Remote Cables

ERI (Enhanced Remote Interface) 5188-8029 ERI to general purpose (D-Sub 15 pin male - open end) 5188-8044 ERI to ERI (D_Sub 15 pin male - male) 5188-8059 ERI-Extension-Cable 1.2 m (D-Sub15 pin male / female)

p/n 5188-8029 pin Color code Enhanced Remote

Classic Remote

Active (TTL)

1 white IO1 START REQUEST

Low

2 brown IO2 STOP Low

3 green IO3 READY High

4 yellow IO4 POWER ON High

5 grey IO5 NOT USED

6 pink IO6 SHUT DOWN Low

7 blue IO7 START Low

8 red IO8 PREPARE Low

9 black 1wire DATA

10 violet DGND

11 grey-pink +5V ERI out

12 red-blue PGND

13 white-green PGND

14 brown-green +24V ERI out

15 white-yellow +24V ERI out

NC yellow-brown

Agilent InfinityLab LC Series VWD User Manual 178

11 Identifying Cables Remote Cables

5188-8045 ERI to APG (Connector D_Subminiature 15 pin (ERI), Connector D_Subminiature 9 pin (APG))

p/n 5188-8045 Pin (ERI) Signal Pin (APG) Active (TTL)

10 GND 1

1 Start Request 9 Low

2 Stop 8 Low

3 Ready 7 High

5 Power on 6 High

4 Future 5

6 Shut Down 4 Low

7 Start 3 Low

8 Prepare 2 Low

Ground Cable Shielding NC

Agilent InfinityLab LC Series VWD User Manual 179

11 Identifying Cables Remote Cables

5188-8057 ERI to APG and RJ45 (Connector D_Subminiature 15 pin (ERI), Connector D_Subminiature 9 pin (APG), Connector plug Cat5e (RJ45))

One end of these cables provides a Agilent Technologies APG (Analytical Products Group) remote connector to be connected to Agilent modules. The other end depends on the instrument to be connected to.

Table 21 5188-8057 ERI to APG and RJ45

p/n 5188-8057 Pin (ERI) Signal Pin (APG) Active (TTL) Pin (RJ45)

10 GND 1 5

1 Start Request

9 High

2 Stop 8 High

3 Ready 7 High

4 Fraction Trig- ger

5 High 4

5 Power on 6 High

6 Shut Down 4 High

7 Start 3 High

8 Prepare 2 High

Ground Cable Shield- ing

NC

Agilent InfinityLab LC Series VWD User Manual 180

11 Identifying Cables Remote Cables

Agilent Module to Agilent 35900 A/D Converters

Agilent Module to General Purpose

p/n 5061-3378 Pin 35900 A/D Pin Agilent module

Signal Name Active (TTL)

1 - White 1 - White Digital ground

2 - Brown 2 - Brown Prepare run Low

3 - Gray 3 - Gray Start Low

4 - Blue 4 - Blue Shut down Low

5 - Pink 5 - Pink Not connected

6 - Yellow 6 - Yellow Power on High

7 - Red 7 - Red Ready High

8 - Green 8 - Green Stop Low

9 - Black 9 - Black Start request Low

p/n 01046-60201 Wire Color Pin Agilent module

Signal Name Active (TTL)

White 1 Digital ground

Brown 2 Prepare run Low

Gray 3 Start Low

Blue 4 Shut down Low

Pink 5 Not connected

Yellow 6 Power on High

Red 7 Ready High

Green 8 Stop Low

Black 9 Start request Low

Agilent InfinityLab LC Series VWD User Manual 181

11 Identifying Cables CAN Cable

CAN Cable

Both ends of this cable provide a modular plug to be connected to Agilent modules CAN or LAN connectors.

CAN Cables

LAN Cables

p/n Description

5181-1516 CAN cable, Agilent module to module, 0.5 m

5181-1519 CAN cable, Agilent module to module, 1 m

p/n Description

5023-0203 Cross-over network cable, shielded, 3 m (for point to point connection)

5023-0202 Twisted pair network cable, shielded, 7 m (for point to point connec- tion)

Agilent InfinityLab LC Series VWD User Manual 182

11 Identifying Cables RS-232 Cables

RS-232 Cables

p/n Description

RS232-61601 RS-232 cable, 2.5 m Instrument to PC, 9-to-9 pin (female). This cable has special pin-out, and is not compatible with connecting printers and plotters. It is also called "Null Modem Cable" with full handshaking where the wiring is made between pins 1-1, 2-3, 3-2, 4-6, 5-5, 6-4, 7-8, 8-7, 9-9.

5181-1561 RS-232 cable, 8 m

Agilent InfinityLab LC Series VWD User Manual 183

11 Identifying Cables USB Cables

USB Cables

To connect a USB Flash Drive use a USB OTG cable with Mini-B plug and A socket.

p/n Description

5188-8050 USB A M-USB Mini B 3 m (PC-Module)

5188-8049 USB A F-USB Mini B M OTG (Module to Flash Drive)

Agilent InfinityLab LC Series VWD User Manual 184

12 Hardware Information

Firmware Description 185 Electrical Connections 188 Rear View of the Module 189 Information on Instrument Serial Number 189

Interfaces 191 Overview Interfaces 193 ERI (Enhanced Remote Interface) 196 USB (Universal Serial Bus) 198

Setting the 6-bit Configuration Switch 199 Special Settings 201

Instrument Layout 203 Early Maintenance Feedback (EMF) 204

This chapter describes the detector in more detail on hardware and electronics.

Agilent InfinityLab LC Series VWD User Manual 185

12 Hardware Information Firmware Description

Firmware Description

The firmware of the instrument consists of two independent sections: a non-instrument specific section, called resident system an instrument specific section, called main system

Resident System

This resident section of the firmware is identical for all Agilent 1100/1200/1220/1260/1290 series modules. Its properties are: the complete communication capabilities (CAN, LAN, USB and RS- 232) memory management ability to update the firmware of the 'main system'

Main System

Its properties are: the complete communication capabilities (CAN, LAN, USB and RS- 232) memory management ability to update the firmware of the 'resident system'

In addition the main system comprises the instrument functions that are divided into common functions like run synchronization through APG/ERI remote, error handling, diagnostic functions, or module specific functions like

internal events such as lamp control, filter movements, raw data collection and conversion to absorbance.

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12 Hardware Information Firmware Description

Firmware Updates

Firmware updates can be done with the Agilent Lab Advisor software with files on the hard disk (latest version should be used).

Required tools, firmware and documentation are available from the Agilent web: http://www.agilent.com/en-us/firmwareDownload?whid=69761

The file naming conventions are: PPPP_RVVV_XXX.dlb, where PPPP is the product number, for example, 1315B for the G1315B DAD, R the firmware revision, for example, A for G1315B or B for the G1315C DAD, VVV is the revision number, for example 650 is revision 6.50, XXX is the build number of the firmware.

For instructions on firmware updates refer to section Replacing Firmware in chapter "Maintenance" or use the documentation provided with the Firmware Update Tools.

Figure 51 Firmware Update Mechanism

NOTE Update of main system can be done in the resident system only. Update of the resident system can be done in the main system only.

Main and resident firmware must be from the same set.

Resident System

Main FW update

Main System

Resident FW Update

Agilent InfinityLab LC Series VWD User Manual 187

12 Hardware Information Firmware Description

The firmware update tools, firmware and documentation are available from the Agilent web. http://www.agilent.com/en-us/firmwareDownload?whid=69761

NOTE Some modules are limited in downgrading due to their mainboard version or their initial firmware revision. For example, a G1315C DAD SL cannot be downgraded below firmware revision B.01.02 or to a A.xx.xx.

Some modules can be re-branded (e.g. G1314C to G1314B) to allow operation in specific control software environments. In this case, the feature set of the target type is used and the feature set of the original one is lost. After re-branding (e.g. from G1314B to G1314C), the original feature set is available again.

All this specific information is described in the documentation provided with the firmware update tools.

Agilent InfinityLab LC Series VWD User Manual 188

12 Hardware Information Electrical Connections

Electrical Connections

The CAN bus is a serial bus with high-speed data transfer. The two connectors for the CAN bus are used for internal module data transfer and synchronization.

One analog output provides signals for integrators or data handling systems. The ERI/REMOTE connector may be used in combination with other analytical

instruments from Agilent Technologies if you want to use features such as start, stop, common shutdown, prepare, and so on.

With the appropriate software, the LAN connector may be used to control the module from a computer through a LAN connection. This connector is activated and can be configured with the configuration switch.

With the appropriate software, the USB connector may be used to control the module from a computer through a USB connection.

The power input socket accepts a line voltage of 100 240 VAC 10 % with a line frequency of 50 or 60 Hz. Maximum power consumption varies by module. There is no voltage selector on your module because the power supply has wide-ranging capability. There are no externally accessible fuses because automatic electronic fuses are implemented in the power supply.

NOTE Never use cables other than the ones supplied by Agilent Technologies to ensure proper functionality and compliance with safety or EMC regulations.

Agilent InfinityLab LC Series VWD User Manual 189

12 Hardware Information Electrical Connections

Rear View of the Module

Figure 52 Rear view of detector (example shows a G7114A/B VWD) electrical connections and label

Information on Instrument Serial Number

Serial Number Information 1200 Series and 1290 Infinity

The serial number information on the instrument labels provide the following information:

LAN

Configuration switch

Analog output

ERI

CAN

Power socket

USB-Mini-Port

CCYWWSSSSS Format

CC country of manufacturing DE = Germany JP = Japan CN = China

YWW year and week of last major manufacturing change, e.g. 820 could be week 20 of 1998 or 2008

SSSSS real serial number

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12 Hardware Information Electrical Connections

Serial Number Information 1260/1290 Infinity

The serial number information on the instrument labels provide the following information:

CCXZZ00000 Format

CC Country of manufacturing DE = Germany JP = Japan CN = China

X Alphabetic character A-Z (used by manufacturing)

ZZ Alpha-numeric code 0-9, A-Z, where each combination unambig- uously denotes a module (there can be more than one code for the same module)

00000 Serial number

Agilent InfinityLab LC Series VWD User Manual 191

12 Hardware Information Interfaces

Interfaces

The Agilent InfinityLab LC Series modules provide the following interfaces:

Table 22 Agilent InfinityLab LC Series Interfaces

Module CAN USB LAN (on-board)

RS-232 Analog APG (A) / ERI (E)

Special

Pumps

G7104A/C 2 No Yes Yes 1 A

G7110B 2 Yes Yes No No E

G7111A/B, G5654A 2 Yes Yes No No E

G7112B 2 Yes Yes No No E

G7120A, G7132A 2 No Yes Yes 1 A

G7161A/B 2 Yes Yes No No E

Samplers

G7129A/B/C 2 Yes Yes No No E

G7167A/B, G7137A, G5668A 2 Yes Yes No No E

G7157A 2 Yes Yes No No E

Detectors

G7114A/B 2 Yes Yes No 1 E

G7115A 2 Yes Yes No 1 E

G7117A/B/C 2 Yes Yes No 1 E

G7121A/B 2 Yes Yes No 1 E

G7162A/B 2 Yes Yes No 1 E

G7165A 2 Yes Yes No 1 E

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12 Hardware Information Interfaces

CAN connectors as interface to other modules LAN connector as interface to the control software RS-232C as interface to a computer USB (Universal Series Bus) as interface to a computer REMOTE connector as interface to other Agilent products Analog output connector(s) for signal output

Fraction Collectors

G7158B 2 Yes Yes No No E

G7159B 2 Yes Yes No No E

G7166A 2 No No No No No Requires a host module with on-board LAN with minimum FW B.06.40 or C.06.40, or with addi- tional G1369C LAN Card

G1364E/F, G5664B 2 Yes Yes No No E THERMOSTAT for G1330B

Others

G7116A/B 2 No No No No No Requires a host module with on-board LAN or with additional G1369C LAN Card.

G7122A No No No Yes No A

G7170B 2 No No No No No Requires a host module with on-board LAN with minimum FW B.06.40 or C.06.40, or with addi- tional G1369C LAN Card

Table 22 Agilent InfinityLab LC Series Interfaces

Module CAN USB LAN (on-board)

RS-232 Analog APG (A) / ERI (E)

Special

NOTE The detector (DAD/MWD/FLD/VWD/RID) is the preferred access point for control via LAN. The inter-module communication is done via CAN.

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12 Hardware Information Interfaces

Overview Interfaces

CAN

The CAN is inter-module communication interface. It is a 2-wire serial bus system supporting high speed data communication and real-time requirement.

LAN

The modules have either an interface slot for a LAN card (e.g. Agilent G1369B/C LAN Interface) or they have an on-board LAN interface (e.g. detectors G1315C/D DAD and G1365C/D MWD). This interface allows the control of the module/system via a PC with the appropriate control software. Some modules have neither on-board LAN nor an interface slot for a LAN card (e.g. G1170A Valve Drive or G4227A Flexible Cube). These are hosted modules and require a Host module with firmware B.06.40 or later or with additional G1369C LAN Card.

USB

The USB interface replaces the RS-232 Serial interface in new FUSION generation modules. For details on USB refer to USB (Universal Serial Bus) on page 198.

Analog Signal Output

The analog signal output can be distributed to a recording device. For details refer to the description of the modules mainboard.

NOTE If an Agilent detector (DAD/MWD/FLD/VWD/RID) is in the system, the LAN should be connected to the DAD/MWD/FLD/VWD/RID (due to higher data load). If no Agilent detector is part of the system, the LAN interface should be installed in the pump or autosampler.

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12 Hardware Information Interfaces

Remote (ERI)

The ERI (Enhanced Remote Interface) connector may be used in combination with other analytical instruments from Agilent Technologies if you want to use features as common shut down, prepare, and so on.

It allows easy connection between single instruments or systems to ensure coordinated analysis with simple coupling requirements.

The subminiature D connector is used. The module provides one remote connector which is inputs/outputs (wired- or technique). To provide maximum safety within a distributed analysis system, one line is dedicated to SHUT DOWN the systems critical parts in case any module detects a serious problem. To detect whether all participating modules are switched on or properly powered, one line is defined to summarize the POWER ON state of all connected modules. Control of analysis is maintained by signal readiness READY for next analysis, followed by START of run and optional STOP of run triggered on the respective lines. In addition PREPARE and START REQUEST may be issued. The signal levels are defined as: standard TTL levels (0 V is logic true, + 5.0 V is false), fan-out is 10, input load is 2.2 kOhm against + 5.0 V, and output are open collector type, inputs/outputs (wired- or technique).

NOTE All common TTL circuits operate with a 5 V power supply. A TTL signal is defined as "low" or L when between 0 V and 0.8 V and "high" or H when between 2.0 V and 5.0 V (with respect to the ground terminal).

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12 Hardware Information Interfaces

Special Interfaces

There is no special interface for this module.

Table 23 ERI signal distribution

Pin Signal Description

1 START REQUEST (L) Request to start injection cycle (for example, by start key on any module). Receiver is the autosampler.

2 STOP (L) Request to reach system ready state as soon as possible (for example, stop run, abort or finish and stop injection). Receiver is any module performing run-time controlled activities.

3 READY (H) System is ready for next analysis. Receiver is any sequence con- troller.

4 POWER ON (H) All modules connected to system are switched on. Receiver is any module relying on operation of others.

5 Not used

6 SHUT DOWN (L) System has serious problem (for example, leak: stops pump). Receiver is any module capable to reduce safety risk.

7 START (L) Request to start run / timetable. Receiver is any module perform- ing run-time controlled activities.

8 PREPARE (L) Request to prepare for analysis (for example, calibration, detec- tor lamp on). Receiver is any module performing pre-analysis activi- ties.

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12 Hardware Information Interfaces

ERI (Enhanced Remote Interface) ERI replaces the AGP Remote Interface that is used in the HP 1090/1040/1050/1100 HPLC systems and Agilent 1100/1200/1200 Infinity HPLC modules. All new InfinityLab LC Series products using the FUSION core electronics use ERI. This interface is already used in the Agilent Universal Interface Box 2 (UIB2)

ERI Description

The ERI interface contains eight individual programmable input/output pins. In addition, it provides 24 V power and 5 V power and a serial data line to detect and recognize further add-ons that could be connected to this interface. This way the interface can support various additional devices like sensors, triggers (in and out) and small controllers, etc.

Figure 53 Location of the ERI interface (example shows a G7114A/B VWD)

ERI

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12 Hardware Information Interfaces

IO (Input/Output) Lines Eight generic bi-directional channels (input or output). Same as the APG Remote. Devices like valves, relays, ADCs, DACs, controllers can be

supported/controlled.

1-Wire Data (Future Use)

This serial line can be used to read out an EPROM or write into an EPROM of a connected ERI-device. The firmware can detect the connected type of device automatically and update information in the device (if required).

Pin Enhanced Remote

1 IO 1 (START REQUEST)

2 IO 2 (STOP)

3 IO 3 (READY)

4 IO 4 (POWER ON)

5 IO 5 (NOT USED)

6 IO 6 (SHUT DOWN)

7 IO 7 (START)

8 IO 8 (PREPARE)

9 1 wire DATA

10 DGND

11 +5 V ERI out

12 PGND

13 PGND

14 +24 V ERI out

15 +24 V ERI out

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12 Hardware Information Interfaces

5V Distribution (Future Use) Available directly after turning on the hosting module (assures that the

firmware can detect certain basic functionality of the device). For digital circuits or similar. Provides 500 mA maximum. Short-circuit proof with automatic switch off (by firmware).

24V Distribution (Future Use) Available by firmware command (defined turn on/off). For devices that need higher power

Class 0: 0.5 A maximum (12 W) Class 1: 1.0 A maximum (24 W) Class 2: 2.0 A maximum (48 W)

Class depends on hosting modules internal power overhead. If a connected device requires more power the firmware detects this

(overcurrent detection) and provides the information to the user interface. Fuse used for safety protection (on board). Short circuit will be detected through hardware.

USB (Universal Serial Bus) USB (Universal Serial Bus) - replaces RS232, supports: a PC with control software (for example Agilent Lab Advisor) USB Flash Disk

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12 Hardware Information Setting the 6-bit Configuration Switch

Setting the 6-bit Configuration Switch

The 6-bit configuration switch is located at the rear of the module with FUSION electronics. Switch settings provide configuration parameters for LAN and instrument specific initialization procedures. All modules with FUSION electronics: Default is ALL switches DOWN (best settings).

Default IP address for LAN 192.168.254.11 For specific LAN modes switches 4-5 must be set as required. For boot resident/cold start modes switches 1+2 or 6 must be UP.

Figure 54 Location of Configuration switch (example shows a G7114A/B VWD)

Configuration switch

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12 Hardware Information Setting the 6-bit Configuration Switch

Table 24 6-bit Configuration Switch

Mode Function/Setting

Switch 1 Switch 2 Switch 3 Switch 4 Switch 5 Switch 6

COM1

1 When selecting mode COM, settings are stored to non-volatile memory. When selecting mode TEST, COM settings are taken from non-volatile memory.

0 n.a.2

2 not assigned - Always keep these switches on position 0 (off)

n.a. LAN Init Mode n.a.

Use Default IP Address3

3 Default IP Address is 192.168.254.11

0 0 0 0 0

Use Stored IP Address 0 0 0 1 0

Use DHCP to request IP Address4

4 Host Name will be the MAC address.

0 0 1 0 0

Test 1 System n.a. n.a. n.a. ColdStart

Boot Main System / Keep Data 0 0 0 0 0

Boot Resident System / Keep Data 1 0 0 0 0

Boot Main System / Revert to Default Data

0 0 0 0 1

Boot Resident System / Revert to Default Data

1 0 0 0 1

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12 Hardware Information Setting the 6-bit Configuration Switch

Special Settings

Boot-Resident/Main

Firmware update procedures may require this mode in case of firmware loading errors (main/resident firmware part).

If you use the following switch settings and power the instrument up again, the instrument firmware stays in the resident/main mode. In resident mode, it is not operable as a module. It only uses basic functions of the operating system for example, for communication. In this mode the main firmware can be loaded (using update utilities).

Forced Cold Start

A forced cold start can be used to bring the module into a defined mode with default parameter settings. Boot Main System / Revert to Default Data

The instrument will boot to main mode and changes to the modules default parameter. May be also required to load resident firmware into the module.

Boot Resident System / Revert to Default Data The instrument will boot to resident mode and changes to the modules default parameter. May be also required to load main firmware into the module.

If you use the following switch settings and power the instrument up again, it will start as described above.

CAUTION Loss of data

Forced cold start erases all methods and data stored in the non-volatile memory. Exceptions are calibration settings, diagnosis and repair log books which will not be erased.

Save your methods and data before executing a forced cold start.

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12 Hardware Information Setting the 6-bit Configuration Switch

Table 25 Boot Resident / Forced Coldstart

SW1 SW2 SW3 SW4 SW5 SW6 Init Mode

1 0 0 0 0 0 Boot Main System / Keep Data

1 1 0 0 0 0 Boot Resident System / Keep Data

1 0 0 0 0 1 Boot Main System / Revert to Default Data

1 1 0 0 0 1 Boot Resident System / Revert to Default Data

Note: The setting '0' (down) is essential.

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12 Hardware Information Instrument Layout

Instrument Layout

The industrial design of the module incorporates several innovative features. It uses Agilents E-PAC concept for the packaging of electronics and mechanical assemblies. This concept is based upon the use of expanded polypropylene (EPP) layers of foam plastic spacers in which the mechanical and electronic boards components of the module are placed. This pack is then housed in a metal inner cabinet which is enclosed by a plastic external cabinet. The advantages of this packaging technology are: virtual elimination of fixing screws, bolts or ties, reducing the number of

components and increasing the speed of assembly/disassembly, the plastic layers have air channels molded into them so that cooling air can

be guided exactly to the required locations, the plastic layers help cushion the electronic and mechanical parts from

physical shock, and the metal inner cabinet shields the internal electronics from electromagnetic

interference and also helps to reduce or eliminate radio frequency emissions from the instrument itself.

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12 Hardware Information Early Maintenance Feedback (EMF)

Early Maintenance Feedback (EMF)

Maintenance requires the exchange of components which are subject to wear or stress. Ideally, the frequency at which components are exchanged should be based on the intensity of usage of the module and the analytical conditions, and not on a predefined time interval. The early maintenance feedback (EMF) feature monitors the usage of specific components in the instrument, and provides feedback when the user-selectable limits have been exceeded. The visual feedback in the user interface provides an indication that maintenance procedures should be scheduled.

EMF Counters

EMF counters increment with use and can be assigned a maximum limit which provides visual feedback in the user interface when the limit is exceeded. Some counters can be reset to zero after the required maintenance procedure.

The detector provides the following EMF counters: Deuterium Lamp On-Time Number of UV lamp ignitions

Using the EMF Counters

The user-settable EMF limits for the EMF Counters enable the early maintenance feedback to be adapted to specific user requirements. The useful maintenance cycle is dependent on the requirements for use. Therefore, the definition of the maximum limits need to be determined based on the specific operating conditions of the instrument.

Lamp Type Counter Reset Comment

lamp with RFID tag NO

lamp without RFID tag YES via Lab Advisor or Instant Pilot

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12 Hardware Information Early Maintenance Feedback (EMF)

Setting the EMF Limits

The setting of the EMF limits must be optimized over one or two maintenance cycles. Initially the default EMF limits should be set. When instrument performance indicates maintenance is necessary, take note of the values displayed by the EMF counters. Enter these values (or values slightly less than the displayed values) as EMF limits, and then reset the EMF counters to zero. The next time the EMF counters exceed the new EMF limits, the EMF flag will be displayed, providing a reminder that maintenance needs to be scheduled.

NOTE This function is only available via Agilent Lab Advisor or Instant Pilot.

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13 LAN Configuration

What You Have to Do First 207 TCP/IP parameter configuration 208 Configuration Switch 209 Initialization Mode Selection 210 Dynamic Host Configuration Protocol (DHCP) 212 General Information (DHCP) 212 Setup (DHCP) 213

Manual Configuration 215 With Telnet 216

This chapter provides information on connecting the module to the Agilent ChemStation PC.

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13 LAN Configuration What You Have to Do First

What You Have to Do First

The module has an on- board LAN communication interface.

1 Note the MAC (Media Access Control) address for further reference. The MAC or hardware address of the LAN interfaces is a world wide unique identifier. No other network device will have the same hardware address. The MAC address can be found on a label at the rear of the module underneath the configuration switch (see Figure 56 on page 207).

Figure 55 MAC-Label

2 Connect the instrument's LAN interface (see Figure 56 on page 207) to the PC network card using a crossover network cable (point-to-point) or a hub or switch using a standard LAN cable.

Figure 56 Location of LAN interfaces and MAC label

NOTE This chapter is generic and may show figures that differ from your module. The functionality is the same.

Part number of the detector main board

Revision Code, Vendor, Year and Week of assembly

MAC address

Country of Origin

LAN interface

MAC label

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13 LAN Configuration TCP/IP parameter configuration

TCP/IP parameter configuration

To operate properly in a network environment, the LAN interface must be configured with valid TCP/IP network parameters. These parameters are: IP address Subnet Mask Default Gateway The TCP/IP parameters can be configured by the following methods: by automatically requesting the parameters from a network-based DHCP

Server (using the so-called Dynamic Host Configuration Protocol). This mode requires a LAN-onboard Module or a G1369C LAN Interface card, see Setup (DHCP) on page 213

by manually setting the parameters using Telnet by manually setting the parameters using the Local Controller

The LAN interface differentiates between several initialization modes. The initialization mode (short form init mode) defines how to determine the active TCP/IP parameters after power-on. The parameters may be derived non-volatile memory or initialized with known default values. The initialization mode is selected by the configuration switch, see Table 26 on page 210.

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13 LAN Configuration Configuration Switch

Configuration Switch

The configuration switch can be accessed at the rear of the module.

Figure 57 Location of Configuration switch (example shows a G7114A/B VWD)

The module is shipped with all switches set to OFF, as shown above.

Configuration switch

NOTE To perform any LAN configuration, SW1 and SW2 must be set to OFF.

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13 LAN Configuration Initialization Mode Selection

Initialization Mode Selection

The following initialization (init) modes are selectable:

Default IP address for LAN is 192.168.254.11.

DHCP address is the modules LAN MAC address.

Using Stored

When initialization mode Using Stored is selected, the parameters are taken from the non-volatile memory of the module. The TCP/IP connection will be established using these parameters. The parameters were configured previously by one of the described methods.

Figure 58 Using Stored (Principle)

Table 26 Initialization Mode Switches

SW1 SW2 SW3 SW4 SW5 SW6 Init Mode

0 0 0 0 0 0 Use Default IP Address

0 0 0 0 1 0 Use Stored IP Address

0 0 0 1 0 0 Use DHCP

Note: The setting 0 (down) is essential.

Non-Volatile

RAM

Stored

Parameter

Active

Parameter

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13 LAN Configuration Initialization Mode Selection

Using Default

When Using Default is selected, the factory default parameters are taken instead. These parameters enable a TCP/IP connection to the LAN interface without further configuration, see Table 27 on page 211.

Figure 59 Using Default (Principle)

Since the default IP address is a so-called local address, it will not be routed by any network device. Thus, the PC and the module must reside in the same subnet.

The user may open a Telnet session using the default IP address and change the parameters stored in the non-volatile memory of the module. He may then close the session, select the initialization mode Using Stored, power-on again and establish the TCP/IP connection using the new parameters.

When the module is wired to the PC directly (e.g. using a cross-over cable or a local hub), separated from the local area network, the user may simply keep the default parameters to establish the TCP/IP connection.

Active

Parameter

Default

Parameter

NOTE Using the default address in your local area network may result in network problems. Take care and change it to a valid address immediately.

Table 27 Using Default Parameters

IP address: 192.168.254.11

Subnet Mask: 255.255.255.0

Default Gateway not specified

NOTE In the Using Default mode, the parameters stored in the memory of the module are not cleared automatically. If not changed by the user, they are still available, when switching back to the mode Using Stored.

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13 LAN Configuration Dynamic Host Configuration Protocol (DHCP)

Dynamic Host Configuration Protocol (DHCP)

General Information (DHCP) The Dynamic Host Configuration Protocol (DHCP) is an auto configuration protocol used on IP networks. The DHCP functionality is available on all Agilent HPLC modules with on-board LAN Interface or LAN Interface Card G1369C, and B-firmware (B.06.40 or above) or modules with "D"-firmware. All modules should use latest firmware from the same set.

When the initialization mode DHCP is selected, the card tries to download the parameters from a DHCP Server. The parameters obtained become the active parameters immediately. They are not stored to the non-volatile memory of the card.

Besides requesting the network parameters, the card also submits its hostname to the DHCP Server. The hostname equals the MAC address of the card, e.g. 0030d3177321. It is the DHCP server's responsibility to forward the hostname/address information to the Domain Name Server. The card does not offer any services for hostname resolution (e.g. NetBIOS).

Figure 60 DHCP (Principle)

DHCP Server

Active Parameter

NOTE 1 It may take some time until the DHCP server has updated the DNS server with the hostname information.

2 It may be necessary to fully qualify the hostname with the DNS suffix, e.g. 0030d3177321.country.company.com.

3 The DHCP server may reject the hostname proposed by the card and assign a name following local naming conventions.

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13 LAN Configuration Dynamic Host Configuration Protocol (DHCP)

Setup (DHCP)

1 Note the MAC address of the LAN interface (provided with G1369C LAN Interface Card or mainboard). This MAC address is on a label on the card or at the rear of the mainboard, for example, 0030d3177321. On the Local Controller the MAC address can be found under Details in the LAN section.

Figure 61 LAN Setting on Instant Pilot

The DHCP functionality is available on all Agilent HPLC modules with on-board LAN Interface or LAN Interface Card G1369C, and B-firmware (B.06.40 or above) or modules with "D"-firmware. All mod- ules should use latest firmware from the same set.

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13 LAN Configuration Dynamic Host Configuration Protocol (DHCP)

2 Set the configuration switch to DHCP either on the G1369C LAN Interface Card or the mainboard of above mentioned modules.

3 Turn on the module that hosts the LAN interface. 4 Configure your Control Software (e.g. OpenLAB CDS ChemStation Edition, Lab

Advisor, Firmware Update Tool) and use MAC address as host name, e.g. 0030d3177321. The LC system should become visible in the control software (see Note in section General Information (DHCP) on page 212).

Table 28 G1369C LAN Interface Card (configuration switch on the card)

SW 4 SW 5 SW 6 SW 7 SW 8 Initialization Mode

ON OFF OFF OFF OFF DHCP

Table 29 LC Modules with 8-bit configuration switch (B-firmware) (configuration switch at rear of the instrument)

SW 6 SW 7 SW 8 Initialization Mode

ON OFF OFF DHCP

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13 LAN Configuration Manual Configuration

Manual Configuration

Manual configuration only alters the set of parameters stored in the non-volatile memory of the module. It never affects the currently active parameters. Therefore, manual configuration can be done at any time. A power cycle is mandatory to make the stored parameters become the active parameters, given that the initialization mode selection switches are allowing it.

Figure 62 Manual Configuration (Principle)

TELNET

Session

Control

Module

Stored

Parameter

Non-Volatile

RAM

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13 LAN Configuration Manual Configuration

With Telnet Whenever a TCP/IP connection to the module is possible (TCP/IP parameters set by any method), the parameters may be altered by opening a Telnet session. 1 Open the system (DOS) prompt window by clicking on Windows START

button and select Run.... Type cmd and press OK. 2 Type the following at the system (DOS) prompt:

c:\>telnet or c:\>telnet

Figure 63 Telnet - Starting a session

where may be the assigned address from a Bootp cycle, a configuration session with the Handheld Controller, or the default IP address (see Configuration Switch on page 209). When the connection was established successfully, the module responds with the following:

Figure 64 A connection to the module is made

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13 LAN Configuration Manual Configuration

3 Type ? and press enter to see the available commands.

Figure 65 Telnet Commands

4 To change a parameter follows the style: parameter value, for example:

ip 134.40.28.56

Then press [Enter], where parameter refers to the configuration parameter you are defining, and value refers to the definitions you are assigning to that parameter. Each parameter entry is followed by a carriage return.

Table 30 Telnet Commands

Value Description

? displays syntax and descriptions of commands

/ displays current LAN settings

ip sets new ip address

sm sets new subnet mask

gw sets new default gateway

exit exits shell and saves all changes

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13 LAN Configuration Manual Configuration

5 Use the / and press Enter to list the current settings.

6 Change the IP address (in this example 192.168.254.12) and type / to list current settings.

7 When you have finished typing the configuration parameters, type exit and press Enter to exit with storing parameters.

Figure 68 Closing the Telnet Session

Figure 66 Telnet - Current settings in "Using Stored" mode

information about the LAN interface MAC address, initialization mode Initialization mode is Using Stored active TCP/IP settings

TCP/IP status - here ready connected to PC with controller software (e.g. Agilent ChemStation), here not connected

Figure 67 Telnet - Change IP settings

change of IP setting to Initialization mode is Using Stored

active TCP/IP settings

stored TCP/IP settings in non-volatile memory

connected to PC with controller software (e.g. Agilent ChemStation), here not connected

NOTE If the Initialization Mode Switch is changed now to Using Stored mode, the instrument will take the stored settings when the module is re-booted. In the example above it would be 192.168.254.12.

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14 Appendix

General Safety Information 220 General Safety Information 220 Safety Standards 220 General 220 Before Applying Power 221 Ground the Instrument 221 Do Not Operate in an Explosive Atmosphere 222 Do Not Remove the Instrument Cover 222 Do Not Modify the Instrument 222 In Case of Damage 222 Solvents 223 Safety Symbols 224 Refrigerant 226

Waste Electrical and Electronic Equipment (WEEE) Directive 229 Radio Interference 230 Sound Emission 231 Solvent Information 232 Declaration of Conformity for HOX2 Filter 233 Agilent Technologies on Internet 234

This chapter provides addition information on safety, legal and web.

Agilent InfinityLab LC Series VWD User Manual 220

14 Appendix General Safety Information

General Safety Information

General Safety Information The following general safety precautions must be observed during all phases of operation, service, and repair of this instrument. Failure to comply with these precautions or with specific warnings elsewhere in this manual violates safety standards of design, manufacture, and intended use of the instrument. Agilent Technologies assumes no liability for the customers failure to comply with these requirements.

Safety Standards This is a Safety Class I instrument (provided with terminal for protective earthing) and has been manufactured and tested according to international safety standards.

General Do not use this product in any manner not specified by the manufacturer. The protective features of this product may be impaired if it is used in a manner not specified in the operation instructions.

WARNING Ensure the proper usage of the equipment.

The protection provided by the equipment may be impaired.

The operator of this instrument is advised to use the equipment in a manner as specified in this manual.

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14 Appendix General Safety Information

Before Applying Power

Ground the Instrument

WARNING Wrong voltage range, frequency or cabling

Personal injury or damage to the instrument

Verify that the voltage range and frequency of your power distribution matches to the power specification of the individual instrument.

Never use cables other than the ones supplied by Agilent Technologies to ensure proper functionality and compliance with safety or EMC regulations.

Make all connections to the unit before applying power.

NOTE Note the instrument's external markings described under Safety Symbols on page 224.

WARNING Missing electrical ground

Electrical shock

If your product is provided with a grounding type power plug, the instrument chassis and cover must be connected to an electrical ground to minimize shock hazard.

The ground pin must be firmly connected to an electrical ground (safety ground) terminal at the power outlet. Any interruption of the protective (grounding) conductor or disconnection of the protective earth terminal will cause a potential shock hazard that could result in personal injury.

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14 Appendix General Safety Information

Do Not Operate in an Explosive Atmosphere

Do Not Remove the Instrument Cover

Do Not Modify the Instrument Do not install substitute parts or perform any unauthorized modification to the product. Return the product to an Agilent Sales and Service Office for service and repair to ensure that safety features are maintained.

In Case of Damage

WARNING Presence of flammable gases or fumes

Explosion hazard

Do not operate the instrument in the presence of flammable gases or fumes.

WARNING Instrument covers removed

Electrical shock

Do Not Remove the Instrument Cover

Only Agilent authorized personnel are allowed to remove instrument covers. Always disconnect the power cables and any external circuits before removing the instrument cover.

WARNING Damage to the module

Personal injury (for example electrical shock, intoxication)

Instruments that appear damaged or defective should be made inoperative and secured against unintended operation until they can be repaired by qualified service personnel.

Agilent InfinityLab LC Series VWD User Manual 223

14 Appendix General Safety Information

Solvents

WARNING Toxic, flammable and hazardous solvents, samples and reagents

The handling of solvents, samples and reagents can hold health and safety risks.

When working with these substances observe appropriate safety procedures (for example by wearing goggles, safety gloves and protective clothing) as described in the material handling and safety data sheet supplied by the vendor, and follow good laboratory practice.

Do not use solvents with an auto-ignition temperature below 200 C (392 F). Do not use solvents with a boiling point below 56 C (133 F).

Avoid high vapor concentrations. Keep the solvent temperature at least 40 C (72 F) below the boiling point of the solvent used. This includes the solvent temperature in the sample compartment. For the solvents methanol and ethanol keep the solvent temperature at least 25 C (45 F) below the boiling point.

Do not operate the instrument in an explosive atmosphere.

Do not use solvents of ignition Class IIC according IEC 60079-20-1 (for example, carbon disulfide).

Reduce the volume of substances to the minimum required for the analysis.

Never exceed the maximum permissible volume of solvents (8 L) in the solvent cabinet. Do not use bottles that exceed the maximum permissible volume as specified in the usage guideline for solvent cabinet.

Ground the waste container.

Regularly check the filling level of the waste container. The residual free volume in the waste container must be large enough to collect the waste liquid.

To achieve maximal safety, regularly check the tubing for correct installation.

NOTE For details, see the usage guideline for the solvent cabinet. A printed copy of the guideline has been shipped with the solvent cabinet, electronic copies are available in the Agilent Information Center or via the Internet.

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14 Appendix General Safety Information

Safety Symbols Table 31 Symbols

The apparatus is marked with this symbol when the user shall refer to the instruction manual in order to protect risk of harm to the operator and to protect the apparatus against damage.

Indicates dangerous voltages.

Indicates a protected ground terminal.

The apparatus is marked with this symbol when hot surfaces are available and the user should not touch it when heated up.

Sample Cooler unit is designed as vapor-compression refrigeration system. Contains fluorinated greenhouse gas (refrigerant) according to the Kyoto protocol. For specifications of refrigerant, charge capacity, carbon dioxide equivalent (CDE), and global warming potential (GWP) see instrument label.

Flammable Material For Sample Thermostat which uses flammable refrigerant consult Agilent Information Center / User Manual before attempting to install or service this equipment. All safety precautions must be followed.

Confirms that a manufactured product complies with all applicable Euro- pean Community directives. The European Declaration of Conformity is available at: http://regulations.corporate.agilent.com/DoC/search.htm

Manufacturing date.

Power symbol indicates On/Off. The apparatus is not completely disconnected from the mains supply when the power switch is in the Off position

Pacemaker Magnets could affect the functioning of pacemakers and implanted heart defibrillators. A pacemaker could switch into test mode and cause illness. A heart defibril- lator may stop working. If you wear these devices keep at least 55 mm dis- tance to magnets. Warn others who wear these devices from getting too close to magnets.

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14 Appendix General Safety Information

Magnetic field Magnets produce a far-reaching, strong magnetic field. They could damage TVs and laptops, computer hard drives, credit and ATM cards, data storage media, mechanical watches, hearing aids and speakers. Keep magnets at least 25 mm away from devices and objects that could be damaged by strong magnetic fields.

Indicates a pinching or crushing hazard

Indicates a piercing or cutting hazard.

Table 31 Symbols

WARNING A WARNING

alerts you to situations that could cause physical injury or death.

Do not proceed beyond a warning until you have fully understood and met the indicated conditions.

CAUTION A CAUTION

alerts you to situations that could cause loss of data, or damage of equipment.

Do not proceed beyond a caution until you have fully understood and met the indicated conditions.

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14 Appendix General Safety Information

Refrigerant The refrigerant HFC-134a is used only in the Agilent Infinity II Sample Cooler.

Table 32 Physical properties of refrigerant HFC-134a

Molecular weight 102

Critical temperature 101.1 C

Critical pressure 40.6 bar

Boiling point -26.5 C

Table 33 Physical properties of refrigerant R600a (isobutane)

Molecular weight 58.12

Critical temperature 134.98 C

Critical pressure 36.6 bar

Boiling point -11.7 C

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14 Appendix General Safety Information

WARNING Refrigerant

Refrigerant HFC-134a is known as a safe refrigerant, however accidents can occur if it is handled incorrectly. For this reason, the following instructions must be observed:

Avoid contact with liquid refrigerant HFC-134a. At atmospheric pressure HFC-134a evaporates at approximately -26 C and causes frost bite.

After skin contact, rinse the affected area with water.

After eye contact, rinse the eye(s) with plenty of water for at least 15 minutes and consult a doctor.

HFC-134a must not be allowed to escape in enclosed areas. Although HFC-134a is not toxic, there is a danger of suffocation as gaseous refrigerant is heavier than air.

Please observe the following first aid instructions. After inhalation, move the affected person to fresh air, keep him warm and allow him to rest. If necessary, he should be supplied with oxygen. If he has stopped breathing or is breathing erratically, he should be given artificial respiration. In the case of cardiac arrest, carry out heart massage. Send for a doctor immediately.

Moreover, it must be noted that HFC-134a must always be extracted from the system and collected. It must never be discharged into the atmosphere on environmental grounds (greenhouse effect).

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14 Appendix General Safety Information

CAUTION General hazards and improper disposal

Improper disposal of the media and components used pollutes the environment.

The disposal or scrapping of the Sample Cooler or the Sample Thermostat must be carried out by a qualified disposal company.

All media must be disposed of in accordance with national and local regulations.

Please contact your local Agilent Service Center in regard to safe environmental disposal of the appliance or check www.agilent.com for more info.

CAUTION Risk of fire or explosion

Dispose of properly in accordance with federal or local regulations. Flammable Refrigerant Used.

Do not dispose of in domestic household waste.

To return unwanted products, contact your local Agilent office, or see http://www.agilent.com for more information.

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14 Appendix Waste Electrical and Electronic Equipment (WEEE) Directive

Waste Electrical and Electronic Equipment (WEEE) Directive

This product complies with the European WEEE Directive marking requirements. The affixed label indicates that you must not discard this electrical/electronic product in domestic household waste.

NOTE Do not dispose of in domestic household waste

To return unwanted products, contact your local Agilent office, or see http://www.agilent.com for more information.

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14 Appendix Radio Interference

Radio Interference

Cables supplied by Agilent Technologies are screened to provide optimized protection against radio interference. All cables are in compliance with safety or EMC regulations.

Test and Measurement

If test and measurement equipment is operated with unscreened cables, or used for measurements on open set-ups, the user has to assure that under operating conditions the radio interference limits are still met within the premises.

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14 Appendix Sound Emission

Sound Emission

Sound pressure

Sound pressure Lp <70 db(A) accroding to DIN-EN 27779

Schalldruckpegel

Schalldruckpegel Lp <70 db(A) nach DIN-EN 27779

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14 Appendix Solvent Information

Solvent Information

Flow Cell To protect optimal functionality of your flow-cell: Avoid the use of alkaline solutions (pH > 9.5) which can attack quartz and

thus impair the optical properties of the flow cell.

Use of Solvents Observe the following recommendations on the use of solvents. Brown glass ware can avoid growth of algae. Avoid the use of the following steel-corrosive solvents:

solutions of alkali halides and their respective acids (for example, lithium iodide, potassium chloride, and so on),

high concentrations of inorganic acids like sulfuric acid and nitric acid, especially at higher temperatures (if your chromatography method allows, replace by phosphoric acid or phosphate buffer which are less corrosive against stainless steel),

halogenated solvents or mixtures which form radicals and/or acids, for example: 2CHCl3 + O2 2COCl2 + 2HCl

This reaction, in which stainless steel probably acts as a catalyst, occurs quickly with dried chloroform if the drying process removes the stabilizing alcohol,

chromatographic grade ethers, which can contain peroxides (for example, THF, dioxane, diisopropyl ether) should be filtered through dry aluminium oxide which adsorbs the peroxides,

solvents containing strong complexing agents (e.g. EDTA), mixtures of carbon tetrachloride with 2-propanol or THF.

Avoid the use of dimethyl formamide (DMF). Polyvinylidene fluoride (PVDF), which is used in leak sensors, is not resistant to DMF.

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14 Appendix Declaration of Conformity for HOX2 Filter

Declaration of Conformity for HOX2 Filter

Agilent InfinityLab LC Series VWD User Manual 234

14 Appendix Agilent Technologies on Internet

Agilent Technologies on Internet

For the latest information on products and services visit our worldwide web site on the Internet at:

http://www.agilent.com

www.agilent.com Agilent Technologies Inc. 2014-2020

Published in Germany 09/2020

Document No: SD-29000240 Rev. D

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