UVP UVX Manual
UVX Radiometer
Instruction Guide
UVP, LLC Ultra-Violet Products Ltd.
2066 W. 11th Street Unit 1, Trinity Hall Farm Estate
Upland, CA 91786 Nuffield Road, Cambridge CB4 1TG UK
Phone: (800) 452-6788 Phone: +44(0)1223-420022
Fax: (909) 946-3597 Fax: +44(0)1223-420561
Web Site: www.uvp.com
81-0064-01 Rev L
UVX Radiometer 2
Table of Contents
General Instructions......................................................................................................................................5
Introduction................................................................................................................................................5
Features.....................................................................................................................................................5
Specifications ............................................................................................................................................6
Operating Procedures ...............................................................................................................................6
Radiometer Details........................................................................................................................................9
Circuit Description .....................................................................................................................................9
Radiometer Circuit Calibration ..................................................................................................................9
Radiometer Maintenance ........................................................................................................................10
Sensor Details.............................................................................................................................................16
Sensor Characteristics ............................................................................................................................16
Calibration Information ............................................................................................................................16
Sensor Maintenance................................................................................................................................20
General Precautions................................................................................................................................20
Application Techniques...............................................................................................................................23
Definition of Radiant Incidence................................................................................................................23
Wavelength Considerations.....................................................................................................................23
Cosine Response....................................................................................................................................26
Summary .................................................................................................................................................26
Safety Precautions......................................................................................................................................27
Component List, Replacement Parts, and Options.....................................................................................30
Component List .......................................................................................................................................30
Replacement Parts..................................................................................................................................31
Options ....................................................................................................................................................31
Warranty......................................................................................................................................................32
UVX Radiometer 3
List of Figures
Figure 1: Rear and Side Views of Radiometer..............................................................................................4
Figure 2: Radiometer Functional Block Diagram........................................................................................14
Figure 3: Radiometer Circuit Board (Component Location)........................................................................14
Figure 4: Calibration Current Source ..........................................................................................................15
Figure 5: LCD Display Pin-outs...................................................................................................................15
Figure 6: UVX-25 Sensor Solarization Curve .............................................................................................17
Figure 7: Typical UVX-25 Sensor Spectral Response................................................................................17
Figure 8: Typical UVX-31 Sensor Spectral Response................................................................................18
Figure 9: Typical UVX-36 Sensor Spectral Response................................................................................18
Figure 10: Typical Sensor Response Versus Incidence Angle...................................................................19
Figure 11: Schematic of UVX Series Sensor..............................................................................................21
Figure 12: Measurement of Irradiance........................................................................................................21
Figure 13: Typical Output From Low Pressure Mercury Lamp...................................................................22
Figure 14: Hypothetical Light Source Having an Output at 270nm Wavelength ........................................25
Figure 15: Response of Three Sensors Calibrated to Yield the Same Output at 254nm Wavelength.......25
Figure 16: Continuous Emitter, 285nm Phosphor Coated UV Lamp..........................................................26
Figure 17: Example, Illustrating Why Sensor Field of View is Important When Measuring Irradiance.......28
Figure 18: Projected Area of Sensor...........................................................................................................28
Figure 19: Cosine Response of Typical UVX Sensor (Polar Plot)..............................................................29
UVX Radiometer 4
Figure 1: Rear and Side Views of Radiometer
UVX Radiometer 5
General Instructions
Introduction
Your new UVX Digital Radiometer from UVP allows measurement of UV intensities quickly and easily.
The digital readout is in radiometric units with a broad dynamic range from 0.1 µW/cm2to 20 mW/cm2 with
accuracy and precision traceable to the National Institute of Standards and Technology (NIST). The
sensors, for measuring UV radiation at 254, 310 and 365nm, are cosine corrected. Each sensor is also
pre-calibrated and quickly interchangeable with any other sensor without affecting the overall system
accuracy.
Designed for simplicity and durability, the UVX is built with the latest in solid state electronics, has a
rugged housing, over-ranging, and low battery indicators. By using circuitry that is powered by a single 9V
transistor battery, UVX is completely portable. It can be used in a wide variety of research and industrial
applications. Some typical applications using UV light sources are: genetic experiments, photochemical
reactions, sterilization procedures, optical lab measurements, experimental biology, dermatology
research, NDT techniques, and graphics procedures.
The UVX Series Sensor that is supplied with this unit, as well as all other UVX Series Sensors, is
designed and calibrated for measurement of radiant incidences from line type and phosphor coated
mercury arc sources. There are several parameters including calibration, spectral response and sensor
field of view which users should understand to insure accurate measurements. Refer to the Applications
Techniques section of this manual, which addresses these subjects.
Features
The following is a list of features provided by the UVX Radiometer and Sensor:
•Three sensitivity ranges covering the span from 200 µW/cm2to 20 mW/cm2
•3-1/2 digit liquid crystal display readout
•Sensitivity down to 0.1 µW/cm2
•Outstanding ruggedness and reliability
•Negligible sensitivity to infrared
•Linearity of ± 1% over the total range, ± one digit
•Readout and sensor are stored in their own storage and carrying case with room for
one additional sensor
•Light weight
•Powered by a single 9V transistor battery
•Long battery life (more than 120 hours of continuous operation with a single alkaline
battery)
•Automatic low voltage battery indication
•Not sensitive to capacitive or AC pick up
•Fully interchangeable sensors for full UV band coverage
•Automatic circuit that tests the display each time the unit is turned on
•Read/Hold switch that allows holding any reading indefinitely
•Automatic reverse battery connection protection circuit
•Calibration of sensors is traceable to NIST through a standard lamp and proven
laboratory techniques
•Independent calibration of all sensors and digital radiometers allowing complete
interchangeability without reference to individual calibration factors
•Remote sensor of small size permitting measurements to be taken in constricted
areas
•Three foot long electrically shielded connecting cable
•1/4-20 UNC-2B threaded mounting hole compatible with standard tripod mount screws
UVX Radiometer 6
•Excellent cosine response with typical curve supplied in the manual
•A filter system which significantly reduces shortwave solarization phenomenon
•Internal temperature correction retains the accuracy of the sensors at both high and
low temperatures
•Externally accessible zero adjust
•Port for a chart recorder (recorder not included)
Optional Features
•A 10 to 1 attenuator allowing readings to be made up to 200mW/cm2.
Specifications
Radiometer
Conversion Rate: 2.8 readings/sec
Display: 3-1/2 digit LCG
Accuracy: ±2.5%
Linearity: ±0.2%
Resolution: 1 part in 1999
Sensitivity Ranges: 0 to 199.9 µW/cm2
0 to 1999 µW/cm2
0 to 19.99 mW/cm2
0 to 199.9 mW/cm2 w/10:1 Attenuator
Temperature Coefficient: ±0.025%/°C ± 1 digit, 0 to 50°C
Zero Drift: ±0.02 uW/cm2/°C nominal 0 to 50°C
Power: 9V transistor battery
Battery Life (Alkaline): 120 Hrs (without recorder output option)
Sensor
Spectral Response: See Figures 7, 8, 9
Accuracy: ±5% (includes NIST standard)
Linearity: ±1.0%
Cosine Response: See Figure 10
Temperature Coefficient: ±0.04%/°C nominal, 0 to 40°C
Zero Drift: ±0.35 uW/cm2/°C nominal 0 to 50°C
Operating Environment
Temperature: 0 to 50°C
Humidity: 5% to 90% RH
Operating Procedures
The UVX Radiometer provides versatility and simplicity of operation. The number of front panel controls
has been held to a minimum. Range changes are made by means of a three position range switch.
Access to the zero adjust trimpot is available through the hole in the left hand side of the case. This
simplifies the operation of the instrument and also minimizes operator error.
The procedure that follows will help in understanding the operation of this instrument.
•Turn the radiometer over and open the battery cover to ascertain if the battery has been installed.
If it is has not, snap the battery clip in place on the battery and insert the battery back into the
holder. Then close the battery cover.
•Plug the UVX sensor into the mating connector at the left rear of the UVX Radiometer. This
receptacle is identified in Figure 1.
Note: The connector goes through two "snap" positions before it is fully inserted. Failure to insert the
connector all the way in will result in erroneous readings.
UVX Radiometer 7
•Place the three position range switch in the 20 mW/cm2 position. Place the READ/HOLD switch
in the READ position.
•Turn the unit on by placing the OFF-ON/TEST switch in the ON/TEST position.
Note: For the first one second of operation, the entire display will be turned on demonstrating that all
segments, decimal points and colon of the display are functioning properly. The readout you should
see for that one second period, if everything is functioning correctly, is -18:8.8. If any one of the
segments, decimals or colon is not turned on during that time, refer to the Troubleshooting tips in this
manual.
After the one second test mode is completed, the circuit will automatically revert to the normal read
condition.
•At that time, the meter should be zeroed to assure the best accuracy. This is done by first
covering the sensor so that no UV light strikes the sensor window. (Generally, turning the sensor
upside down on a bench will suffice.) The range switch is then placed in the 200 µW/cm2position
and the zero adjustment trimpot for a display reading of 00.0 µW/cm2.
•After setting the zero, ultraviolet readings may be taken by placing the sensor in the UV
environment. The resultant intensities will be shown on the display.
UVX Radiometer 8
CAUTION
Refer to the Safety Precautions section of this manual before making ultraviolet
measurements with this radiometer. If, when the sensor has been placed in the
UV radiant incident field, all the digits are blanked except for the leading 1, an
overrange condition is indicated. This may be corrected by switching to a less
sensitive range or by moving the sensor away from the UV source. If this is
impractical, then the optional attenuator must be used.
If, however, the reading contains less than three significant digits, use a more
sensitive scale or move the sensor closer to the source.
If a reading is obtained and it is desired to hold the reading, change the position
of the HOLD/READ switch to the HOLD position. This will hold the reading until
the switch is returned to the READ POSITION.
In the event the battery voltage falls below that necessary to insure accurate
operation, the colon in the middle of the display will automatically come on. When
this happens turn off the radiometer immediately and replace the battery with a
new one.
UVX Radiometer 9
Radiometer Details
Circuit Description
This section describes how the UVX Radiometer operates. Three illustrations are included for use in
conjunction with this section. Figure 2 is a Functional Block Diagram and Figure 3 is a pictorial view of the
Circuit Board.
Current to Voltage Converter
The silicon detector used in the sensor may be modeled as a current source. For maximum linearity, the
detector load should represent a short circuit. The input amplifier on the board meets this requirement
and converts the input current to a voltage that is then applied to the analog to digital (A/D) converter. A
switchable 4, 40, or 400:1 voltage divider in the amplifier feedback loop allows the current gain selection
required to produce a readout directly in the appropriate units of measure.
A/D Converter
The A/D chip used in this circuit is a high performance, low power 3-1/2 digit converter, complete with
seven segment decoder, display drives, internal reference and a clock. This chip retains the high
accuracy of much more expensive units by providing an auto-zero to less than O uV, zero drift of less
than 1uV/°C, and roll over error of less than one count. The output of the chip drives the LCD directly.
Decimal Point Circuitry
The decimal point circuitry operates through a C-MOS chip to drive the appropriate decimal point as the
range is changed.
Low Battery Voltage Circuit
A low battery is detected by means of comparing a diode reference voltage to the trip-point of an
exclusive OR gate. When the battery voltage decreases to less than 7.0v, the colon will light up on the
display.
HOLD/READ Circuit
The A/D chip is equipped with "hold" function pin which, when driven high (by the READ/HOLD switch),
holds the currently displayed reading.
ON/TEST Circuit
The ON/TEST circuit applies a one second DC signal to the back-plane of the LCD, forcing all the
segments to come on. After one second, the TEST portion of the circuit returns the unit to normal
operation.
Radiometer Circuit Calibration
This section refers to the calibration of the radiometer, not of the sensor. UVP recommends recalibration
of the radiometer every 6 months. UVP provides calibration services for a nominal fee. Contact the factory
for details.
Note: Should the user attempt to perform a calibration on the radiometer prior to the end of the warranty
period, then the warranty on the radiometer becomes void.
Required test equipment for those who wish to calibrate their own radiometer:
•Variable current with a range from .005uA to 1.0uA. Note: See Figure 4 for a calibration current
source
•Precision microammeter measures current source output
•500 K ohm resistor (±0.1 %)
•5 to 9 V DC adjustable power supply (10mA or more)
•0 to 10V DC digital voltmeter
UVX Radiometer 10
•Small Phillips head screw driver
•Small straight screw driver for trimpot adjustment
Procedure
Calibration
•Remove the battery. Remove the two screws from the bottom of the case and carefully lift off the
bottom. As you do this, feed the battery clip through the aperture in the side of the battery holder.
Place the bottom of the case aside and lift the PC board out of the case top. Set the PC board on
the test bench.
•Be sure the OFF-ON/TEST switch is in the OFF position.
•Connect the DC power source to the plus and minus terminals of the battery clip. Note: The plus
side of the battery snap is the larger of the two. Set the voltage of the power supply at 9V DC.
•Connect the DC voltmeter ground connection to pin 32 of the A/D converter chip. Connect the
plus side of the DC voltmeter to pin 36 of the A/D converter chip as shown on the bottom edge of
Figure 3.
•Turn the 9V DC power on and depress the ON/TEST switch. This will apply power to the circuit.
Measure the voltage between pin 36 and pin 32.
•If the voltage is not 1.000 volts DC, adjust RV3 until this indication is obtained.
•Disconnect the voltmeter from the circuit.
•Reduce the power supply voltage to 7.00V DC.
•While viewing the display, adjust trimpot RV2 until the colon between the middle two digits just
begins to come on. Achieving this sets the low battery voltage indication circuit.
•Check for proper low battery voltage indication by reducing the supply voltage to 6.8 volts and
see that the colon is fully on. Then increase the supply voltage to 7.20V DC and see that the
colon is completely off.
•Return the supply voltage to 9.0 volts DC.
•Place the range selector switch in the 200 uW/cm2position.
•While viewing the display adjust trimpot RV1 until the display shows 00.0
•This completes the calibration procedure.
Ranging
•Connect the current source to the input connector as designated on Figure 4.
•Set the current source for an output of 0.00500 uA.
•Set the range switch to the 200 uW/cm2position. The display should now read 100.00 ±2.5
uW/cm2
•Change the current to 0.0500 uA.
•Set the range switch to the 2000 uW/cm2position. The display should now read 1000 ±25
uW/cm2.
•Change the current to 0.500 uA. Set the range switch to 20 uW/cm2. The display should now read
10.00 ±25 uW/cm2.
•This completes the test of the ranges of the unit.
Turn off the unit by depressing the OFF switch, disconnect the power supply and test equipment and
reassemble the circuit board back into the case. Test equipment and reassemble the circuit board back
into the case.
Radiometer Maintenance
Care of Radiometer Case
The case of the UVX Radiometer is fabricated from a durable ABS plastic. As with all plastics, solvents
should not be used for cleaning of the case. A high quality plastic cleaner or mild soap and water should
be used to clean fingerprints, dust of dirt from the case.
Note: Do not use abrasive cleaners on the radiometer. The contacts for the sensor input and the recorder
UVX Radiometer 11
output are recessed and should not require attention.
Troubleshooting Procedures
In the event the radiometer malfunctions, the following procedures will enable the user to determine the
source of error and affect repairs.
If, in the following procedures, any of the active circuit elements are replaced, then the calibration
procedure must be performed prior to putting the radiometer back into service.
Troubleshooting Tips
The following paragraphs detail some of the more common malfunctions of the circuit and give the basic
procedures by which the cause of the circuit malfunction can be determined and ultimately corrected.
These procedures are limited to those active elements that can be easily removed and replaced.
Remove the circuit board from the case. Check the battery voltage to make sure it is still above 7.0 volts.
If it is, connect the battery back into the circuit. If it is not, replace it with a new battery.
Note: In the event any component is removed and replaced as a result of any work done on this unit,
then full calibration procedure must be performed.
•Display segment does not turn on.
Turn the unit on and observe the display during the first second of operation: i.e. during test
mode. In this case the display should indicate -18:8.8 in the event anyone of the segments of the
display is not turned on, it may indicate that a contact is not making firm contact at the liquid
crystal display.
To correct this, use a pencil tip and place it on the pin contact of the malfunctioning segment.
(Refer to Figure 5 for the display pin-outs) Carefully work the contact pin back and forth with the
pencil tip and watch the segment. Performing this operation will generally correct all display
segment malfunctions.
•Colon does not turn on
If the colon does not turn on during the test mode, refer to the previous troubleshooting topic. If
the colon does not operate as a result of low battery voltage conditions, then proceed as follows.
Disconnect the battery from the circuit and connect the circuit to a variable 0 to 10 volt DC power
supply. Set the power supply voltage at 9 volts. Turn the power supply on and turn the unit on.
Slowly reduce the output of the DC power supply to 7.0 volts. If the colon does not come on, then
the trimpot RV2 is out of adjustment or the integrated circuit A2 is malfunctioning.
With the power supply set a 7.0 volts, adjust trimpot RV2 fully counterclockwise then fully
clockwise. If the colon does not come on at any time during this adjustment, then the integrated
circuit A2 is malfunctioning. Remove A2 and replace it with a new integrated circuit.
•Decimal point does not turn on.
Turn the unit on and place the range switch in the position in which the decimal point should be
on. Connect the negative input of the voltmeter to the negative side of the battery.
If the decimal point that should be on is the one corresponding to the 20 uW/cm2range, then
connect the positive side of the voltmeter to pin 9 of integrated circuit A2. If the decimal point that
is not on corresponds to the 200 uW/cm2range, connect the positive input of the voltmeter to pin
12 of integrated circuit A2.
When the range switch is in the appropriate position for the decimal point to be on, the voltmeter
should read the battery supply voltage; i.e., 9.0 volts. When the range switch is in some other
position, then the voltmeter should read less than 5 volts DC.
UVX Radiometer 12
If the voltmeter indicates correctly according to the above requirements and the decimal point
fails to come on, then the integrated circuit A2 is malfunctioning and must be replaced. If the
voltmeter does not indicate as described above, then the malfunction is in the range selector
switch and the UVX must be returned to UVP.
•Display does not turn on.
If the display fails to turn on immediately check the lead wires from the battery to make sure they
are not broken, also check the battery for an output of at least 7.0 volts. Also check the snaps on
the battery connectors. Be sure the snap fingers are pinched together for good contact when
snapped onto the battery terminals. If all these check out correctly, then integrated circuit A4 is
malfunctioning and must be replaced.
•Test mode does not operate.
Turn the unit on and momentarily connect a jumper between the plus side of the power supply
and pin 2 of integrated circuit A2. NOTE: Do not leave the jumper connected longer than a few
seconds. To do so may cause permanent damage to the Liquid Crystal Display.
During that time the test mode condition should be displayed on the readout. If the display shows
the test mode correctly, then the malfunction is in the ON/TEST switch and the unit must be
returned to UVP for repair. If it is not, then integrated circuit A2 is malfunctioning and must be
replaced.
•Hold mode does not operate.
Turn the unit on and connect the DC voltmeter between the negative side of the battery and pin 1
of integrated circuit A4. Switch from READ to HOLD. The voltmeter should indicate the battery
voltage while the switch is in the HOLD position.
If the voltmeter indicates the battery voltage, and the display does not remain steady, then the
malfunction is in the integrated circuit A4 and it must be replaced. If the voltmeter does not
indicate the battery voltage, then the malfunction is in the switch and the unit must be returned to
UVP for repair.
•No display change with UV intensity changes.
Disconnect the sensor from the sensor input jack. Connect a 500K resistor between pin 2 of
integrated circuit A1 and the junction between resistors R1and R3. Connect a variable source
between pin 3 (-) and 2 (+) of integrated circuit A1. Set the current source for an output of .00500
micro amps.
Turn the unit on and set the range switch to the 200 uW/cm2 position.
Connect the negative side of a DC digital voltmeter to pin 3 of integrated circuit A1 and the
positive side to pin 6. Turn the unit on.
For normal operation, the display should read 100.0 uW/cm2and the voltmeter should read 1.00
volts. If the display is not indicating correctly or not at all and the voltmeter is indicating 1.00 volts,
then integrated circuit A4 is malfunctioning and must be replaced.
If the voltmeter is not indicating 1.00 Volts, then the input amplifier A1 is malfunctioning and must
be replaced.
Change the range switch to the 2000 uW/cm2position. The voltmeter indication should be 0.100
volts and the display should read 100 uW/cm2.lf the voltmeter did not change from 1.00 volts,
down to 0.100 volts, then the malfunction is in the range changing switch and the unit must be
returned to UVP for repair.
Change the range switch to the 20 uW/cm2position. The display should now indicate 0.10
UVX Radiometer 13
uW/cm2 and the voltmeter should read .0100 volts Again, if the voltmeter indication did not
decrease by a factor of 10, then the malfunction is in the range changing switch and the unit must
be returned to UVP for repair.
In the event the input amplifier, A1, the range changing switch, and integrated circuit, A4, are
found to be functioning correctly, then the malfunction is in the UVX sensor.
Note: For direct traceability to NIST standards, the sensor must be returned to UVP for repair and
recalibration. Refer to the section in the manual on Sensor Details.
UVX Radiometer 14
Figure 2: Radiometer Functional Block Diagram
Figure 3: Radiometer Circuit Board (Component Location)
UVX Radiometer 15
Figure 4: Calibration Current Source
Figure 5: LCD Display Pin-outs
UVX Radiometer 16
Sensor Details
Sensor Characteristics
Solarization of Filters
Shortwave ultraviolet radiation causes a decrease in sensor output that is proportional to total exposure.
This is due to changes in the transmission properties of the filters; a phenomenon called solarization.
Solarization is especially noticeable in the 254nm sensors. Only a small amount is seen in the midrange
(310nm) sensors and virtually none in the longwave (365nm) sensors. In typical shortwave sensors
operating at 254nm, solarization begins immediately and reduces the sensor output at a rate of about
0.4% per mW-h/cm2. To correct this problem, the UVX shortwave (254nm) filters incorporate a new design
that significantly reduces the short term solarization effect. This is shown in Figure 8 where it can be seen
that solarization does not begin to take effect until after 50mW-h/cm2 total dosage and then at the reduced
rate of 0.1% per mW-hcm2.
Spectral Response Curves
Figures 7, 8 and 9 show the typical spectral response characteristics of the UVX 25, 31 and 36 Series
Sensors (respectively). In each case the absolute response curve is typical. Individual sensors may
exhibit variations in response at wavelengths distant from the calibration wavelength, but all are
accurately calibrated to a response of 1.00 at the specified calibration wavelength.
Sensor Temperature Coefficient
An added feature of the UVX Series Sensors is that special circuitry has been incorporated to reduce the
temperature induced errors present in all solid state detectors. The result is a sensor with a nominal
overall temperature coefficient of only ±0.04%/°C from 0 to 40°C.
Sensor Response Versus Incidence Angle
The UVX Series Sensors incorporate a unique diffuser at the incident surface. This diffuser enables the
sensor to detect radiation to incidence angles of ±81 from the normal. Figure 10 shows the real response
of the UVX Series Sensors, as compared to the perfect cosine response curve, with sufficient detail that
analytical corrections can be made where accurate measurements of large UV sources are required.
Calibration Information
Authorized Calibration Service
Please note this section refers to the calibration of sensors, not the radiometer. UVP maintains a
calibration laboratory to recalibrate UVX Series Sensors. A nominal fee is charged for this service. To
verify such a recalibration, the date of the most recent calibration is placed on the label attached to the
sensor and a certificate of calibration is included with the returned sensor. It is suggested that the first
recalibration take place 6 months after the initial unpacking and use of the use of the unit, not 6 months
from the initial calibration date on the sensor. Periods of time spent sealed on the dealer's shelves have
negligible effect on the accuracy of the calibration.
UVX Radiometer 17
Figure 6: UVX-25 Sensor Solarization Curve
Figure 7: Typical UVX-25 Sensor Spectral Response
UVX Radiometer 18
Figure 8: Typical UVX-31 Sensor Spectral Response
Figure 9: Typical UVX-36 Sensor Spectral Response
UVX Radiometer 19
Figure 10: Typical Sensor Response Versus Incidence Angle
Calibration Traceability
For direct traceability to NIST standards, UVX sensors must be returned to the UVP calibrations
laboratory for calibration once every 6 months. UVP does not stand behind calibrations performed by
unauthorized companies.
UVX Series Sensors are calibrated by adjusting their response to match that of an UVP Transfer
Standard Detector when exposed to radiant incidence of the appropriate calibration wavelength from a
stable, effectively monochromatic source.
The calibration of UVP Transfer Standard Detectors is accomplished by measuring their response to a
stable, effectively monochromatic radiant source of the appropriate wavelength. The absolute radiant
incidence level from this source is set by simultaneously matching it with that of National Institute of
Standards and Technology (NIST) standard of spectral irradiance. This calibration is performed at UVP
calibrations laboratory a minimum of once every six months.
The NIST standard of spectral irradiance used by UVP is a 1000 watt tungsten lamp. This lamp is
replaced after every 20 hours of operation.
Period of Calibration
UVP recommends recalibration of the UVX Series Sensors every 6 months, especially when used by the
governmental agencies and in other areas of critical application.
NOTE: All sensors must be calibrated by the UVP calibrations laboratory for direct traceability to NIST
standards.
In non-critical applications, the user may choose a longer period of time between calibrations. However,
the actual time that a sensor will remain within tolerance is dependent on such factors as care in handling
UVX Radiometer 20
and total dosage of radiation on the sensor filters (refer to “Solarization of Filters” in this manual).
Sensor Maintenance
The user should avoid performing corrective maintenance on the sensor. If required, the UVX Sensor
should be returned to the factory.
Care of Sensor Case
CAUTION: Do not use abrasive cleaners on any part of the UVX Series Sensors or allow water to get
inside the sensor.
The case of the UVX sensors is fabricated from a durable ABS plastic. As with all plastics, solvents
should not be used in cleaning of the case. A high quality plastic cleaner or mild soap and water may be
clean fingerprints, dust or dirt from the case. The contacts on the cable connector should not require
attention.
Care of the Sensor Window
Dirt, dust or fingerprints on the sensor window will cause inaccurate readings. To ensure accurate
readings, it is essential that the sensor window be kept clean. There are several ways of ensuring
cleanliness. To remove dust or dirt, use a lens tissue or a cotton swab. To remove fingerprints, use a lens
tissue or lint-free cloth moistened with alcohol. A high purity alcohol will ensure that no residue remains
after the cleaning procedure.
General Precautions
Handling
The UVX Series Sensors, although rugged, should be protected from physical shocks, moisture and
extremes of temperature.
Sensor Exposure
The sensors have been designed for minimum solarization effect as described elsewhere in this manual.
However, it is suggested that the sensor be exposed to ultraviolet radiation only for the amount of time
necessary to actually make a measurement. Excessive exposure may reduce the time between
recalibrations.
Sensor Continuity Measurements
When an ohmmeter is used to check continuity of the sensor, be careful not to use a meter that applies
more than 2 volts to the circuit. This is especially important when measuring continuity of the radiation
sensor itself; i.e., between the ring and sleeve of the connector. (See schematic, Figure 11).
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