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Campbell Scientific 3301 Wind Vane Instruction Manual PDF

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Summary of Content for Campbell Scientific 3301 Wind Vane Instruction Manual PDF

03001 R.M. Young Wind Sentry Set 03101 R.M. Young Wind Sentry Anemometer

03301 R.M. Young Wind Sentry Vane Revision: 8/07

C o p y r i g h t 1 9 8 6 - 2 0 0 7 C a m p b e l l S c i e n t i f i c , I n c .

Warranty and Assistance The 03001 R.M. YOUNG WIND SENTRY SET, 03101 R.M. YOUNG WIND SENTRY ANEMOMETER, AND 03301 R.M. YOUNG WIND SENTRY VANE are warranted by CAMPBELL SCIENTIFIC, INC. to be free from defects in materials and workmanship under normal use and service for twelve (12) months from date of shipment unless specified otherwise. Batteries have no warranty. CAMPBELL SCIENTIFIC, INC.'s obligation under this warranty is limited to repairing or replacing (at CAMPBELL SCIENTIFIC, INC.'s option) defective products. The customer shall assume all costs of removing, reinstalling, and shipping defective products to CAMPBELL SCIENTIFIC, INC. CAMPBELL SCIENTIFIC, INC. will return such products by surface carrier prepaid. This warranty shall not apply to any CAMPBELL SCIENTIFIC, INC. products which have been subjected to modification, misuse, neglect, accidents of nature, or shipping damage. This warranty is in lieu of all other warranties, expressed or implied, including warranties of merchantability or fitness for a particular purpose. CAMPBELL SCIENTIFIC, INC. is not liable for special, indirect, incidental, or consequential damages.

Products may not be returned without prior authorization. The following contact information is for US and International customers residing in countries served by Campbell Scientific, Inc. directly. Affiliate companies handle repairs for customers within their territories. Please visit www.campbellsci.com to determine which Campbell Scientific company serves your country. To obtain a Returned Materials Authorization (RMA), contact CAMPBELL SCIENTIFIC, INC., phone (435) 753-2342. After an applications engineer determines the nature of the problem, an RMA number will be issued. Please write this number clearly on the outside of the shipping container. CAMPBELL SCIENTIFIC's shipping address is:

CAMPBELL SCIENTIFIC, INC. RMA#_____ 815 West 1800 North Logan, Utah 84321-1784

CAMPBELL SCIENTIFIC, INC. does not accept collect calls.

R.M. Young Wind Sentry Table of Contents PDF viewers note: These page numbers refer to the printed version of this document. Use the Adobe Acrobat bookmarks tab for links to specific sections.

1. Introduction..................................................................1

2. Specifications ..............................................................2

3. Installation....................................................................3 3.1 Siting.........................................................................................................3 3.2 Assembly and Mounting...........................................................................3 3.3 03001 Wind Sentry Set.............................................................................3 3.4 03101 Anemometer ..................................................................................6 3.5 03301 Vane...............................................................................................6

4. Wiring............................................................................6

5. Example Programs ......................................................7 5.1 Wind Speed ..............................................................................................7 5.2 Wind Direction .........................................................................................8 5.3 Wind Vector Processing Instruction.........................................................8 5.4 Example Programs....................................................................................8

5.4.1 CR1000 Example Program .............................................................9 5.4.2 CR10X Example Program ............................................................10

5.5 Long Lead Lengths.................................................................................11

6. Sensor Maintenance..................................................12

7. Troubleshooting ........................................................12 7.1 Wind Direction .......................................................................................12 7.2 Wind Speed ............................................................................................13

8. References .................................................................13

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R.M. Young Wind Sentry Table of Contents

Appendices

A. Wind Direction Sensor Orientation........................A-1 A.1 Determining True North and Sensor Orientation................................ A-1

B. Wind Direction Measurement Theory ....................B-1 B.1 AC Half Bridge (P5) and BRHalf Instructions.................................... B-1 B.2 EX-DEL-SE (P4) Instruction .............................................................. B-1

Figures 3-1. 03001 Mounted to CM200 Series Crossarm with CM220 ..................... 4 3-2. 03001 Mounted to 019ALU or CM200 Series Crossarm

with PN 1049....................................................................................... 4 3-3. 03101 Anemometer Mounted to CM200 Series Crossarm

with CM220......................................................................................... 5 3-4. 03001 Mounted to CM100 Series Tripod Mast with CM216................. 5 A-1. Magnetic Declination for the Contiguous United States ................... A-2 A-2. Declination Angles East of True North are Subtracted from 0 to

Get True North ................................................................................ A-2 A-3. Declination Angles West of True North are Added to 0 to

Get True North ................................................................................ A-3 B-1. 03001/03301 Potentiometer in a Half Bridge Circuit ........................ B-1

Tables 1-1. Recommended Lead Lengths ................................................................. 1 4-1. Connections to Campbell Scientific Dataloggers ................................... 6 5-1. Wind Speed Multiplier ........................................................................... 7 5-2. Parameters for Wind Direction............................................................... 8 5-3. Wiring for Example Programs................................................................ 9

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R.M. Young Wind Sentry

1. Introduction The 03001 Wind Sentry Set is used to measure horizontal wind speed and direction.

Wind speed is measured with a three cup anemometer. Rotation of the cup wheel produces an AC sine wave voltage with frequency proportional to wind speed.

Vane position is transmitted by a 10K ohm potentiometer. With a precision excitation voltage applied, the output voltage is proportional to wind direction.

The 03101 Anemometer and 03301 Vane can be ordered as separate sensors, which are also covered in this manual. The R.M. Young Instruction Manual includes additional information on the operating principles, installation and maintenance of the sensor.

Lead length for the Wind Sentry is specified when the sensor is ordered. Table 1-1 gives the recommended lead length for mounting the sensor at the top of the tripod/tower with a 019ALU or CM200 series crossarm.

TABLE 1-1. Recommended Lead Lengths

CM6 CM10 CM110 CM115 CM120 UT10 UT20 UT30

12 15 15 20 25 15 25 38

The 03001 Wind Sentry ships with:

(1) 03001 Wind Sentry including 03101 Anemometer 03301 Vane crossarm band clamp (P/N 4919) (1) 10" x 3/4" unthreaded aluminium pipe (P/N 6332) (1) Allen wrench (P/N 5201)

The 03101 Anemometer ships with:

(1) 03101 Anemometer (1) 10" x 3/4" threaded galvanized pipe (P/N 12243) (1) Allen wrench (P/N 5201)

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R.M. Young Wind Sentry

The 03301 Vane ships with:

(1) 03301 Vane (1) 10 x 3/4 threaded galvanized pipe (P/N 12243) (1) Allen wrench (P/N 5201)

2. Specifications Wind Speed (Anemometer) Specifications Range: 0 to 50 m s-1 (112 mph), gust survival 60 m s-1 (134

mph) Sensor: 12 cm diameter cup wheel assembly, 40 mm diameter

hemispherical cups Accuracy: 0.5 m s-1 (1.1 mph) Turning Factor: 75 cm (2.5 ft) Distance Constant (63% recovery): 2.3 m (7.5 ft) Threshold: 0.5 m s-1 (1.1 mph) Transducer: Stationary coil, 1350 ohm nominal resistance Transducer Output: AC sine wave signal induced by rotating magnet on cup

wheel shaft 100 mV peak-to-peak at 60 rpm; 6 V peak-to-peak at

3600 rpm Output Frequency: 1 cycle per cup wheel revolution; 0.75 m s-1 per Hz Cup Wheel Diameter: 12 cm (4.7 in) Weight: 113 g (4 oz)

Wind Direction (Vane) Specifications Range: 360 mechanical, 355 electrical (5 open) Sensor: Balanced vane, 16 cm turning radius Accuracy: 5 Damping Ratio: 0.2 Delay Distance (50% recovery): 0.5 m (1.6 ft) Threshold: 0.8 m s-1 (1.8 mph) at 10 displacement 1.8 m s-1 (4 mph) at 5 displacement Transducer: Precision conductive plastic potentiometer; 10 K ohm

resistance; 0.5% linearity; life expectancy 20 million revolutions.

Rated 1 watt at 40C, 0 watts at 125C. Transducer Output: Analog dc voltage proportional to wind direction

angle with regulated excitation voltage supplied by the datalogger

Vane Length: 22 cm (8.7 in) Vane Weight: 170 g (6 oz)

Wind Sentry Assembly Specifications Operating Temperature: -50 to +50C assuming non-riming conditions Overall Height: 32 cm (12.6 in) Crossarm Length: 40 cm (15.7 in) between instruments (center-to-

center) Mounting Diameter: 26.7 mm (1.05 in), mounts on standard 3/4 in. pipe

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R.M. Young Wind Sentry

The black outer jacket of the cable is Santoprene rubber. This compound was chosen for its resistance to temperature extremes, moisture, and UV degradation. However, this jacket will support combustion in air. It is rated as slow burning when tested according to U.L. 94 H.B. and will pass FMVSS302. Local fire codes may preclude its use inside buildings.

NOTE

3. Installation 3.1 Siting

Locate wind sensors away from obstructions (e.g. trees and building). As a general rule of thumb there should be a horizontal distance of at least ten times the height of the obstruction between the windset and the obstruction. If it is necessary to mount the sensors on the roof of a building, the height of the sensors above the roof, should be at least 1.5 times the height of the building. See Section 9 for a list of references that discuss siting wind speed and direction sensors.

3.2 Assembly and Mounting Tools Required:

5/64 Allen wrench Allen wrench provided with sensor 1/2 open end wrench compass and declination angle for the site (see Appendix A) small screw driver provided with datalogger UV resistant cable ties small pair of diagonal-cutting pliers 6 - 10 torpedo level

3.3 03001 Wind Sentry Set Install the cupwheel to the anemometer shaft using the Allen wrench provided with the sensor.

The 03001 mounts to a standard 0.75 IPS schedule 40 pipe (1.05 O.D.). A 12 long mounting pipe ships with the 03001 for attaching the sensor to a 019ALU or CM200 series crossarm with the CM220 or PN 1049 (Figures 3-1 and 3-2). The 03001 can also be mounted at the top of a CM6/CM10 tripod mast, or to a CM110 series tripod with the CM216 as shown in Figure 3-4.

Mount the 019ALU or CM200 series crossarm to the tripod or tower. Orient the crossarm North-South, with the 3/4 Nu-Rail or CM220 on the North end. Appendix A contains detailed information on determining true north using a compass and the magnetic declination for the site.

Secure the mounting pipe to the 019ALU or CM220. Place the 03001 on the pipe, and orient the sensor crossarm North-South with the vane to the North. Tighten the mounting post band clamp. Final sensor orientation is done after

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R.M. Young Wind Sentry

the datalogger has been programmed to measure wind direction as described in Appendix A.

Route the sensor cable along the underside of the crossarm to the tower/tripod mast, and to the instrument enclosure. Secure the sensor cable to the crossarm and mast using cable ties.

CM220

CM200 Series Crossarm

FIGURE 3-1. 03001 Mounted to CM200 Series Crossarm with CM220

PN 1049 Nu-Rail

CM200 Series Crossarm

FIGURE 3-2. 03001 Mounted to 019ALU or CM200 Series Crossarm with PN 1049

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R.M. Young Wind Sentry

CM220

CM200 Series Crossarm

FIGURE 3-3. 03101 Anemometer Mounted to CM200 Series Crossarm with CM220

CM216

FIGURE 3-4. 03001 Mounted to CM100 Series Tripod Mast with CM216

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R.M. Young Wind Sentry

3.4 03101 Anemometer Install the cupwheel to the anemometer shaft using the Allen wrench provided with the sensor.

The 03101 mounts to a threaded 0.75 IPS schedule 40 pipe (1.05 O.D.). A 10 long mounting pipe ships with the 03101 for attaching the sensor to a 019ALU or CM200 series crossarm with CM220 (Figures 3-3) or PN 1049. The 03001 can also be mounted at the top of a CM6/CM10 tripod mast, or to a CM110 series tripod with the CM216.

Mount the 019ALU or CM200 series crossarm to the tripod or tower. Screw the mounting pipe into the base of the 03101, and attach the sensor / mounting pipe to the crossarm.

Route the sensor cable along the underside of the crossarm to the tower/tripod mast, and to the instrument enclosure. Secure the sensor cable to the crossarm and mast using cable ties.

3.5 03301 Vane The 03301 Vane is typically ordered as a replacement vane for the 03001 Wind Sentry Set, and includes the bracket for attaching it to the 03001 crossarm. PN 4913 pipe mount (not included with the sensor) can be used to attach the 03301 to a 019ALU or CM200 series crossarm (with the CM220 or PN 1049), and the mounting pipe that ships with the sensor.

4. Wiring Connections to Campbell Scientific dataloggers are given in Table 4-1. When Short Cut for Windows software is used to create the datalogger program, the sensor should be wired to the channels shown on the wiring diagram created by Short Cut.

TABLE 4-1. Connections to Campbell Scientific Dataloggers

Color

Description

CR800 CR5000 CR3000 CR1000

CR510 CR500 CR10(X)

CR21X CR7 CR23X

CR200

Black Wind Spd. Signal Pulse Pulse Pulse P_LL

White Wind Spd. Reference G Clear Wind Spd. Shield G

Red Wind Dir. Signal SE Analog SE Analog SE Analog SE Analog

Black Wind Dir. Excitation Excitation Excitation Excitation Excitation

White Wind Dir. Reference AG Clear Wind Dir. Shield G

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R.M. Young Wind Sentry

Wind Speed Wind Direction

5. Example Programs This section is for users who write their own programs. A datalogger program to measure this sensor can be created using Campbell Scientifics Short Cut Program Builder software. You do not need to read this section to use Short Cut.

5.1 Wind Speed Wind speed is measured with the Pulse Count instruction, and with the low level AC configuration. For dataloggers programmed with Edlog, specify configuration code 21 to output frequency in Hertz.

The expression for wind speed (U) is:

U = MX + B

where

M = multiplier X = number of pulses per second (Hertz) B = offset

Table 5-1 lists the multipliers (M) and offsets (Off) to obtain meters/second or miles/hour when the Pulse Count instruction is configured to output the result in Hz.

TABLE 5-1. Wind Speed Multiplier (With Configuration Code 21*)

Model Meters/Second Miles/Hour 03001 / 03101 M = 0.750

Off = 0.2 M = 1.677 Off = 0.4

*When configuration code 11 is used, the multiplier above is divided by the execution interval in seconds.

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R.M. Young Wind Sentry

5.2 Wind Direction The wind vane is coupled to a 10K potentiometer, which has a 5 degree electrical dead band between 355 and 360 degrees.

The EX-DEL_SE measurement instruction (P4) is used for dataloggers that are programmed with Edlog (e.g. CR10X, CR23X) and the CR200. The multiplier to convert the measurement result (mV) to degrees is 355 deg/excitation mV.

The BRHalf measurement instruction is used for dataloggers that are programmed with CRBasic (e.g. CR1000, CR3000). The multiplier to convert the measurement result (mV/excitation mV) to degrees is 355.

Excitation voltages, range codes, and multipliers for CSI dataloggers are listed in Table 5-2. Appendix B has additional information on the P4 and BRHalf measurement instructions.

TABLE 5-2. Parameters for Wind Direction

CR10(X) CR510 CR200

CR7 21X CR23X

CR800 CR1000

CR5000 CR3000

Measurement Range

2500 mV, slow

5000 mV, slow/60 Hz

2500 mV, 60 Hz, reverse excitation

5000 mV, 60 Hz, reverse excitation

Excitation Voltage

2500 mV 5000 mV 2500 mV 5000 mV

Multiplier 0.142 0.071 355 355

Offset 0 0 0 0

5.3 Wind Vector Processing Instruction The Wind Vector output instruction is used to process and store mean wind speed, unit vector mean wind direction, and Standard Deviation of the wind direction (optional) from the measured wind speed and direction values.

5.4 Example Programs The following programs measure the 03001 every 5 seconds, and store mean wind speed, unit vector mean direction, and standard deviation of the direction every 60 minutes. Wiring for the examples is given in Table 5-3.

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R.M. Young Wind Sentry

TABLE 5-3. Wiring for Example Programs

Color Description CR1000 CR10X

Black Wind Spd. Signal P1 P1

White Wind Spd. Reference G

Clear Wind Spd. Shield G

Red Wind Dir. Signal SE 1 SE 1

Black Wind Dir. Excitation EX 1 E1

White Wind Dir. Reference AG

Clear Wind Dir. Shield G

5.4.1 CR1000 Example Program 'CR1000 'Declare Variables and Units Public Batt_Volt Public WS_ms Public WindDir Units Batt_Volt=Volts Units WS_ms=meters/second Units WindDir=Degrees 'Define Data Tables DataTable(Table1,True,-1) DataInterval(0,60,Min,10) WindVector (1,WS_ms,WindDir,FP2,False,0,0,0) FieldNames("WS_ms_S_WVT,WindDir_D1_WVT,WindDir_SD1_WVT") EndTable 'Main Program BeginProg Scan(5,Sec,1,0) 'Default Datalogger Battery Voltage measurement Batt_Volt: Battery(Batt_Volt) '03001 or 03101 RM Young Wind Sentry Wind Speed Sensor measurement - WS_ms: PulseCount(WS_ms,1,1,1,1,0.75,0.2) If WS_ms<0.21 Then WS_ms=0 '03001 or 03301 RM Young Wind Sentry Wind Direction Sensor measurement - WindDir: BrHalf(WindDir,1,mV2500,1,1,1,2500,True,0,_60Hz,355,0) 'Use mV5000 range and 5000 mV excitation for CR3000 and CR5000 dataloggers. If WindDir>=360 OR WindDir<0 Then WindDir=0

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R.M. Young Wind Sentry

'Call Data Tables and Store Data CallTable(Table1) NextScan EndProg

5.4.2 CR10X Example Program ;{CR10X} *Table 1 Program 01: 5.0000 Execution Interval (seconds) 1: Batt Voltage (P10) 1: 1 Loc [ Batt_Volt ] ;03001 or 03101 RM Young Wind Sentry Wind Speed Sensor measurement - WS_ms: 2: Pulse (P3) 1: 1 Reps 2: 1 Pulse Channel 1 3: 21 Low Level AC, Output Hz 4: 2 Loc [ WS_ms ] 5: 0.75 Multiplier 6: 0.2 Offset 3: If (X<=>F) (P89) 1: 2 X Loc [ WS_ms ] 2: 4 < 3: 0.21 F 4: 30 Then Do 4: Z=F x 10^n (P30) 1: 0 F 2: 0 n, Exponent of 10 3: 2 Z Loc [ WS_ms ] 5: End (P95) ;03001 or 03301 RM Young Wind Direction Sensor measurement - WindDir: 6: Excite-Delay (SE) (P4) 1: 1 Reps 2: 5 2500 mV Slow Range ;5000 mV(slow/60hz) range for CR23X, 21X, or CR7 3: 1 SE Channel 4: 1 Excite all reps w/Exchan 1 5: 2 Delay (0.01 sec units) 6: 2500 mV Excitation ;5000 mV for CR23X, 21X, or CR7 7: 3 Loc [ WindDir ] 8: 0.142 Multiplier ;0.071 for CR23X, 21X, or CR7 9: 0 Offset

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R.M. Young Wind Sentry

7: If (X<=>F) (P89) 1: 3 X Loc [ WindDir ] 2: 3 >= 3: 360 F 4: 30 Then Do 8: Z=F x 10^n (P30) 1: 0 F 2: 0 n, Exponent of 10 3: 3 Z Loc [ WindDir ] 9: End (P95) 10: If (X<=>F) (P89) 1: 3 X Loc [ WindDir ] 2: 4 < 3: 0 F 4: 3 Then Do 11: Z=F x 10^n (P30) 1: 0 F 2: 0 n, Exponent of 10 3: 3 Z Loc [ WindDir ] 12: End (P95) 13: If time is (P92) 1: 0 Minutes (Seconds --) into a 2: 60 Interval (same units as above) 3: 10 Set Output Flag High (Flag 0) 14: Set Active Storage Area (P80)^15464 1: 1 Final Storage Area 1 2: 101 Array ID 15: Real Time (P77)^6687 1: 1220 Year,Day,Hour/Minute (midnight = 2400) 16: Wind Vector (P69)^28601 1: 1 Reps 2: 0 Samples per Sub-Interval 3: 0 S, theta(1), sigma(theta(1)) with polar sensor 4: 2 Wind Speed/East Loc [ WS_ms ] 5: 3 Wind Direction/North Loc [ WindDir ]

5.5 Long Lead Lengths When sensor lead length exceeds 100 feet, the settling time allowed for the measurement of the vane should be increased to 20 milliseconds.

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R.M. Young Wind Sentry

For dataloggers programmed with Edlog (and the CR200), the EX-DEL-SE (P4) measurement instruction should be used. Enter a 2 in the P4 Delay parameter for a 20 millisecond delay.

For dataloggers programmed with CRBasic, increase the Settling Time parameter of the BRHalf instruction to 20 milliseconds (20,000 microseconds).

The 60 Hz rejection option can not be used with the DC Half Bridge instruction, when the delay is not zero. Do not use long lead lengths in electrically noisy environments.

CAUTION

6. Sensor Maintenance Every month do a visual/audio inspection of the anemometer at low wind speeds. Verify that the cup assembly and wind vane rotate freely. Inspect the sensor for physical damage.

Replace the anemometer bearings when they become noisy, or the wind speed threshold increases above an acceptable level. The condition of the bearings can be checked with a paper clip as described in the R.M. Young manual.

The potentiometer has a life expectancy of fifty million revolutions. As it becomes worn, the element can produce noisy signals or become non-linear. Replace the potentiometer when the noise or non-linearity becomes unacceptable.

Contact Campbell Scientific for a Return Materials Authorization (RMA) number at (801) 753-2342.

7. Troubleshooting 7.1 Wind Direction

Symptom: -9999 or no change in direction

1. Check that the sensor is wired to the Excitation and Single-Ended channel specified by the measurement instruction.

2. Verify that the excitation voltage and Range code are correct for the datalogger type.

3. Disconnect the sensor from the datalogger and use an ohm meter to check the potentiometer. Resistance should be about 10K ohms between the black and white wires. The resistance between either the black/red or white/red wires should vary from 1K to 11K depending on vane position. Resistance when the vane is in the 5 degree dead band should be about 1M ohm.

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R.M. Young Wind Sentry

Symptom: Incorrect wind direction

1. Verify that the Excitation voltage, Range code, multiplier and offset parameters are correct for the datalogger type.

2. Check orientation of sensor as described in Section 3.

7.2 Wind Speed Symptom: No wind speed

1. Check that the sensor is wired to the Pulse channel specified by the Pulse count instruction.

2. Disconnect the sensor from the datalogger and use an ohm meter to check the coil. The resistance between the white and black wires should be a nominal 1350 ohms. Infinite resistance indicates an open coil; low resistance indicates a shorted coil.

3. Verify that the Configuration Code, and Multiplier and Offset parameters for the Pulse Count instruction are correct for the datalogger type.

Symptom: Wind speed does not change

1. For the dataloggers that are programmed with Edlog, the input location for wind speed is not updated if the datalogger is getting Program Table Overruns. Increase the execution interval (scan rate) to prevent overruns.

8. References The following references give detailed information on siting wind speed and wind direction sensors.

EPA, 1989: Quality Assurance Handbook for Air Pollution Measurements System, Office of Research and Development, Research Triangle Park, NC, 27711.

EPA, 1987: On-Site Meteorological Program Guidance for Regulatory Modeling Applications, EPA-450/4-87-013, Office of Air Quality Planning and Standards, Research Triangle Park, NC 27711.

The State Climatologist, 1985: Publication of the American Association of State Climatologists: Height and Exposure Standards, for Sensors on Automated Weather Stations, vol. 9, No. 4.

WMO, 1983: Guide to Meteorological Instruments and Methods of Observation, World Meteorological Organization, No. 8, 5th edition, Geneva, Switzerland.

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R.M. Young Wind Sentry

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14

Appendix A. Wind Direction Sensor Orientation

A.1 Determining True North and Sensor Orientation Orientation of the wind direction sensor is done after the datalogger has been programmed, and the location of True North has been determined. True North is usually found by reading a magnetic compass and applying the correction for magnetic declination; where magnetic declination is the number of degrees between True North and Magnetic North. Magnetic declination for a specific site can be obtained from a USGS map, local airport, or through a computer service offered by the USGS at www.ngdc.noaa.gov/seg/geomag/. A general map showing magnetic declination for the contiguous United States is shown in Figure A-1.

Declination angles east of True North are considered negative, and are subtracted from 0 degrees to get True North as shown Figure A-2. Declination angles west of True North are considered positive, and are added to 0 degrees to get True North as shown in Figure A-3. For example, the declination for Logan, Utah is 14 East. True North is 360 - 14, or 346 as read on a compass.

Orientation is most easily done with two people, one to aim and adjust the sensor, while the other observes the wind direction displayed by the datalogger.

1. Establish a reference point on the horizon for True North.

2. Sighting down the instrument center line, aim the nose cone, or counterweight at True North. Display the input location or variable for wind direction using a hand-held keyboard display, PC, or palm.

3. Loosen the u-bolt on the CM220 or the set screws on the Nu-Rail that secure the base of the sensor to the crossarm. While holding the vane position, slowly rotate the sensor base until the datalogger indicates 0 degrees. Tighten the set screws.

A-1

Appendix A. Wind Direction Sensor Orientation

Subtract declination from 360 Add declination to 0

22 E

18 E

16 E

14 E

12 E

10 E 8 E 6 E

4 E 2 E

0 2 W

4 W

6 W

8 W

10 W

14 W

12 W

16 W

18 W

20 W

20 E

FIGURE A-1. Magnetic Declination for the Contiguous United States

FIGURE A-2. Declination Angles East of True North Are Subtracted From 0 to Get True North

A-2

Appendix A. Wind Direction Sensor Orientation

FIGURE A-3. Declination Angles West of True North Are Added to 0 to Get True North

A-3

Appendix A. Wind Direction Sensor Orientation

This is a blank page.

A-4

Appendix B. Wind Direction Measurement Theory

It is not necessary to understand the concepts in this section for the general operation of the 03001 with Campbell Scientifics datalogger.

EXCITATION VOLTAGE (Vx)

SIGNAL + (Vs)

AZIMUTH REFERENCE

EARTH GROUND CONNECT N

Rt

Rs

IO

FIGURE B-1. 03001 / 03301 Potentiometer in a Half Bridge Circuit

B.1 BRHalf Instruction The BRHalf instruction outputs a precise excitation voltage (Vx), and measures the voltage between the wiper and ground (Vs). The resistance between the wiper and ground, Rs, and Vs varies with wind direction. The measurement result is the ratio of the measured voltage to the excitation voltage (Vs/Vx). This ratio is related to the resistance as shown below:

( )stsxs RRRVV +=

The maximum value that Rs will reach is Rf, just before it crosses over from the west side of north to the east side of north (at this point Rt = 0). Vs / Vx reaches its maximum value of 1.0 mV/mV at 355 degrees. The multiplier to convert Vs/Vx to degrees is 355 degrees / 1.0 Vs/Vx = 355. Since the datalogger outputs the ratio Vs / Vx, the multiplier is the same for both the CR10(X) and CR3000, even though they use a different excitation voltage. See Section 13.5 in the datalogger manual from more information on the bridge measurements.

B.2 EX-DEL-SE (P4) Instruction Instruction 4 outputs a precise excitation voltage (Vx) and measures the voltage between the wiper and analog ground, Vs. The resistance between the wiper and analog ground, Rs, and Vs varies with wind direction. Instruction 4 outputs the measured voltage, Vs. This measured voltage is related to resistance as shown below:

( )stsxs RRRVV +=

The maximum value that Rs will reach is Rf just before it crosses over from the west side of north to the east side of north (at this point Rt = 0). Vs reaches its maximum value of Vx. This maximum voltage equals 2500 mV for an

B-1

Appendix B. Wind Direction Measurement Theory

excitation voltage of 2500 mV recommended for the CR10(X) and 5000 mV for an excitation voltage of 5000 mV recommended for the CR23X at 355 degrees. The multiplier to convert Vs to degrees is 355 degrees / 2500 mV = 0.142 for the CR10X, or, 355 degrees / 5000 mV = 0.071 for the CR23X. See Section 13.5 in the datalogger manual from more information on the bridge measurements

B-2

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If you want to find out how the 3301 Campbell Scientific works, you can view and download the Campbell Scientific 3301 Wind Vane Instruction Manual on the Manualsnet website.

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The Instruction Manual should include all the details that are needed to use a Campbell Scientific 3301. Full manuals and user guide PDFs can be downloaded from Manualsnet.com.

The best way to navigate the Campbell Scientific 3301 Wind Vane Instruction Manual is by checking the Table of Contents at the top of the page where available. This allows you to navigate a manual by jumping to the section you are looking for.

This Campbell Scientific 3301 Wind Vane Instruction Manual consists of sections like Table of Contents, to name a few. For easier navigation, use the Table of Contents in the upper left corner.

You can download Campbell Scientific 3301 Wind Vane Instruction Manual free of charge simply by clicking the “download” button in the upper right corner of any manuals page. This feature allows you to download any manual in a couple of seconds and is generally in PDF format. You can also save a manual for later by adding it to your saved documents in the user profile.

To be able to print Campbell Scientific 3301 Wind Vane Instruction Manual, simply download the document to your computer. Once downloaded, open the PDF file and print the Campbell Scientific 3301 Wind Vane Instruction Manual as you would any other document. This can usually be achieved by clicking on “File” and then “Print” from the menu bar.