8800T Instruction Manual - Teledyne Analytical · PDF fileinstruction manual Teledyne...
Transcript of 8800T Instruction Manual - Teledyne Analytical · PDF fileinstruction manual Teledyne...
instructionmanual
Teledyne Analytical InstrumentsA Business Unit of Teledyne Electronic Technologies
Model 8800TTRACE MOISTURE ANALYZER
8800T User’ s Manual
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8800T User’ s Manual
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8800T User’s Manual Table of Contents
1.0 Overview of the 8800T .................................................12.1 Precautions using the sensor ....................................2.2 Sensor Technical Specifications ...............................2.3 Sensor Installation & Sampling Techniques ..............2.3.1 In-situ Installation ...................................................2.3.2 Extractive Installation .............................................2.4 Troubleshooting unexpected readings ......................3.1 Precautions using the 8800T .......................................133.1.1 Electromagnetic Compatibility Considerations .......3.2 Instrument Technical Specifications ..........................3.3 Installation .................................................................3.3.1 Mechanical Installation ...........................................3.3.2 Electrical Installation ..............................................3.4 Operating the Instrument ..........................................3.4.1 Starting up ..............................................................3.4.2 Display Conventions ...............................................3.4.3 Push Buttons ..........................................................3.4.4 Operating State ......................................................3.4.4.1 Viewing Dewpoint Mode ......................................3.4.4.2 Viewing Temperature at the Sensor ....................3.4.4.3 Start Calibration (SpanCheck™) Mode ...............3.4.4.4 Viewing Serial Number Mode ..............................3.4.5 SetUp State ...........................................................3.5 Troubleshooting the Instrument .................................Appendix A: Operating State User Interface flowchart ....Appendix B: Set-Up State User Interface flowchart .........Appendix C: 8800T Mechanical Drawing ........................34Appendix D: 8800T Electrical Connections .....................35Appendix E: Sensor/SpanCheck™ Theory of Operation Appendix F: Pressure Correction ....................................Appendix G: Current vs. Dewpoint ..................................
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Appendix H: Uncertainty in LBS & ppmV calculations ..4Appendix I: Sensor Response Time ................................Appendix J: Return Authorization Request .....................
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Section 1: Introduction
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1.0 Overview of the 8800T
The 8800T is a microprocessor based 4-20mA loop powered (2 wire) hygrometer, for measuring moisture content in gases in the range from -100°C to +20°C. The measuremis displayed on the instrument’s custom LCD, and is tranmitted by varying the current drawn (4-20mA) from the power supply. The current varies linearly proportional to tselected measurement units. An optional digital output isavailable which modulates/demodulates the 4-20mA loopline without interfering with its operation. With this optionthe 8800T is capable of communicating with properly equipped Personal Computers or other RS-232 capable trollers. Three front panel buttons provide the user with awide variety of features. The 8800T’ s advanced design allows it to be housed in a small stainless steel enclosurebehind the sensor probe, thus the instrument and sensora single integrated unit.The 8800T uses the Teledyne HTF™ sensor which is encap-sulated in sintered stainless steel, thus it is capable of coing into contact with a wide variety of environments. However one should keep in mind that the sensor is a setive device and it should be handled accordingly.
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8800T User’ s Manual
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Section 2: Sensor and Sampling Techniques
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2.1 Precautions using the sensor
The Teledyne HTF™ Al2O3 sensor is designed and field proven to be highly reliable, rugged and maintenance free. However the user should consider the following precau-tions:• To avoid the need for prolonged dry-down (when
expecting to measure dewpoints dryer than -65ºC), dnot expose the sensor to room air longer than necess(1 - 2 minutes). Thus, do not open the sensor containbefore you are ready to install the sensor.
• The sensor container has desiccant to keep the sensdry during shipping and to avoid damage due to condsation. Close the container immediately after removinthe sensor to avoid degradation of the desiccant.
• Do not throw away the sensor container, you may useagain to transport the sensor between locations, to stit between uses or to ship it back to the factory for cefication. The container can be attached to the loop cabby trapping the cable with the lid strap.
• Do not expose the sensor to corrosive gases such asgases containing chlorine, ammonia or HCl. (SO2 cabe monitored when the moisture content is low).
• Except for the XTR65W sensor:1. Do not expose the sensor to liquid water, as it may damaged. 2. Do not breathe directly onto the sensor, as condention may form which could damage the sensor eleme
• Do not install the sensor near heat sources such as rators or air ducts.
• Do not install the sensor in places subject to extrememechanical vibration or shock. If this is not avoidableuse resilient mounting. If in doubt, call your represent
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8800T User’ s Manual
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tive.• Do not disassemble the porous metal filter encapsula
tion, as this will damage the sensor and void your factory warranty.
• Prior to installation of the probe, ensure that no containants are present in the system (e.g. oil, liquid water
2.2 Sensor Technical SpecificationsType: .................................Hyper Thin Film high capacitance Al2O3.Dewpoint range:
XTR-100........................-148°F to +68°F (-100°C to +20°C)XTR-65..........................-85°F to +68°F (-65°C to +20°C).
Capacitance:......................15nF to 200nF.Accuracy: ..........................±5.5°F (±3°C).Repeatability: ....................±0.9°F (±0.5°C).Response time: ..................see graph in Appendix I.Temperature range: ...........-10°C to +70°C.Sample Flow range:
(linear velocity @ 1ATM):Static to 100m/s.Storage temperature: .........-40°F to+176°F (-40°C to +80°C).Mechanical:.......................encapsulated in 100µ sintered stainless steel.Calibration method: ..........SpanCheck™, sensor saturates at dewpoint abo
+68°F (+20°C). NIST/NPL traceable multi-point factory calibration available optionally.
2.3 Sensor Installation & Sampling Techniques
Keep in mind that the moisture content at the sensor is nonly due to the moisture of the gas being measured, but adue to desorption of water from tubing, trapped moisture the interconnection points, valves, filters and other hygroscopic materials in the system), leaks in the system, anders. Thus the measurement may vary from the expectatiand therefore care should be taken in choosing the samptechnique utilized in the measurement. Factors such as gpressure, flow rate, materials of construction, length and
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Section 2: Sensor and Sampling Techniques
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diameter of tubing, number of interconnecting fittings, despace in tubing and manifolds; will influence the measurement value and response time.The high capacitance HTF™ sensors can be installed eitdirectly in the line to be sampled (in-situ), or in a slip streaof a sample system (extractive).To assure a long and accurate performance of the sensoshould be protected from contaminants such as liquids (water, oil etc.), and particulates. The sintered stainless ssensor encapsulation protects from particulates larger th100 microns, finer particulates (e.g. from degraded desiccant or rust) should be filtered with a particulate filter withsuitable capability, do not use hygroscopic filter materials
2.3.1 In-situ InstallationIn-situ installation is recommended only for measuremenwhere the gas pressure is expected to vary little, the gasexpected to be free of contaminants, the gas temperaturwithin the operating specifications of the sensor, and therno chance of liquids coalescing. Examples of applicationsuited for in-situ installations are: pure gases, output of diccant dryers (for instrument air), glove boxes, etc. For moother applications in-situ installation should be avoided fothe following reasons:• Sample conditioning is almost always necessary to
avoid exposure of the sensor to liquid water and othecontaminants, such as hydrocarbons, which may damage the sensor or affect accuracy over time.
• Variations in line pressure affect the reading of the sesor because dewpoint varies with pressure.
• If the gas line is under pressure, it is more likely that water condensation occurs which may damage the sesor.
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• Under a pressurized system removal of the sensor wout the installation of isolation valves can be dangero
If in-situ installation is required, bypass mounting is prefeable; make sure to install the sensor at the upper surfacethe gas line to minimize its exposure to liquid water, shoucondensation occur, the XTR65W sensor is best suited fthese applications. Also consider the need to isolate (depsurize) before installing or removing the sensor.
MainGas Line
8800T
8800T
4-20mA loop cable
Safety shut-off Valve
BypassControlValve *
Safety shut-off Valve
Bypass Installation, Sensor Measuring at Line Pressure
In-Line Installation, Sensor Measuring at Line Pressure
MainGas Line
4-20mA loop cableoint Transmitter
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* maintain differential pressure to provide adequate flow through sample cell
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Section 2: Sensor and Sampling Techniques
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2.3.2 Extractive InstallationFor extractive installations we recommend our sample sytem ESS, which may be equipped with a variety of featursuch as: isolation valve, coalescing or particulate filter, pressure regulator, calibration sample injection or extractport, pressure gauge, flow meter, weatherproof enclosurRefer to the ESS literature for more information.If the resources to make your own sample system are avable, the following two diagrams may be used as a guidelto configure a simple system.
8800T4-20mA loop cable Exhaust
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Safety shut-off Valve
Extractive Installation, Sensor Measuring at Line Pressure
8800T4-20mA loop cable
ExhaustRegulator orNeedle Valve
Extractive Installation, Sensor Measuring at Ambient Pressure
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MainGas Line
MainGas Line
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8800T User’ s Manual
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It is generally recommended to measure at ambient presfor the following reasons:• The readings will not be affected by variations in line
pressure.• The risk of exposing the sensor to liquid water is sign
icantly reduced. • ppm readings are computed for a pressure of one atm
sphere (1 bar); and have to be corrected using softwain the instrument, or a pressure nomograph, or calcultor if the sensor is measuring at different pressures.
If readings at line pressure are necessary, it is recommento measure at ambient pressure and to use the instrumepressure compensation feature to calculate the dewpoinline pressure. See appendix F.Please make sure that:• The sample is taken from the upper surface of the ma
gas line. This avoids problems with contamination. Thsample should be taken away from pipe line walls wheflow rates may be low, and dewpoint changes may la
• For dewpoints dryer than -40°F, use stainless steel tuing only. Copper tubing is acceptable for dewpoints wter than -40°F. Do not use plastic, rubber or tygon tubiunder any circumstances, as measurements would bincorrect and/or response time slow due to water retetion inside these materials.
• Try to run pipes to the sensor upwards, so that contanants tend to fall back into the main line.
• Keep the length of the sample line to the sensor as shas possible.
• Use small diameter pipes (1/4” or 1/8” OD).• Use sufficient flow rates (e.g. 1 l/min with 6 feet of 1/8
piping is adequate). The flow rate will influence the sytems’ response time.
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• Do not install any devices upstream of the sensor, suas other measuring systems, flow meters etc., which not absolutely necessary as these are potential leak sources.
• Installation of a coalescing and / or particulate filter ahead of the sensor is desirable to prevent any liquidparticulate contamination of the sensor.
• If filters are used upstream of the sensor, make sure these contain non-hygroscopic filter materials only.
• If pressure regulators, shut off valves etc. are used upstream of the sensor, make sure these do not contrubber or other hygroscopic materials.
2.4 Troubleshooting unexpected readings
If erroneous readings are suspected on a newly acquiredinstrument, compare the serial number engraved on the sor sintered filter, to the one stored in the instrument memory. The two should be the same; if they are not, the instrument may not be calibrated with the installed sensoTo troubleshoot other problems, identify the unexpected reading category in the following table, and consider the possible causes and appropriate diagnostic action and reedy.
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Troubleshooting unexpected readings (table spans 2 pa
For non-sensor related problems (e.g. no reading on instment) refer to section 3.5
Symptom Possible Cause
Reading is not changing
Condensation in sample system.
Slow Response1. Water vapor in the system. 2. Flow rate too low. 3. Sample pipe too large and/or too long. 4. Unsuitable sample pipe material.5. Leaks6. Hygroscopic materials in sample system
Dry Reading SpanCheck™ wrongly set, or faulty sensor.
Wet ReadingLeak in system or use of unsuitable pipe.
Comparison of readings with manual cooled-mirror instrument.
Display Shows
6$7
Prolonged exposure to wet gas.
Display Shows
6+5
1. Instrument Failure
2.Short circuited sensor.
Display Shows 1. Instrument failure.
231 2. Open circuit on sensor.
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Troubleshooting unexpected readings (continued from previous pa
Symptom Diagnostic/Remedy
Reading is not changing
Condensation will occur if the temperature of the sample system, at any point i(colder) the dewpoint temperature of the sample gas. Once having formed, thereaching the sensor will have a dewpoint equal to the temperature of the condregardless of the dewpoint of the sample at the sample point.
Slow ResponseIt is usually more satisfactory to bleed a sample gas at atmospheric pressurethe sensor sampling chamber, and to use 1/8” (3mm) o.d. sample pipe.
See below re: sample pipe material, also see section 2.3
Dry Reading Verify SpanCheck™, or return sensor for full calibration to your representativ
Wet ReadingCure the leak, or replace unsuitable pipe with copper or stainless steel. Flexibnections should be made with PTFE pipe. NEVER use rubber or plastic pipe.
This type of indicator reads about 10°C dry at about -50°C dewpoint due to teture gradients within the device. The error increases at drier levels.
Display Shows
6$7
Dry the sensor, install sensor in either a known dry gas stream i.e. instrumentair or dry nitrogen, or place sensor in a dry can or bottle of desiccant and seatainer from outside air (the shipping container is designed for this purpose)
Display Shows
6+5Remove (unscrew) sensor, if the instrument still reads 6+5 the problem is with the
instrument. However, if the instrument reads 231 then check possible cause #2
Remove (unscrew) sensor and note that the meter reading returns to 231. Use a nesensor, or apply approximately 20V DC, between the center pin & the filter bothe sensor, MOMENTARILY with the sensor in a known dry condition. Polarity important, but the contact MUST be very brief or the sensor may be damaged
Display Shows
Remove (unscrew) the sensor. Short the center contact of the 8800T sensor connectionto the case, if the instrument reads 6+5 the problem is in the sensor, otherwise rethe instrument for service.
231 Check sensor connection or replace sensor.
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3.1 Precautions using the 8800T
The 8800T uses state-of-the-art microelectronics to provide a miniature full functioning instrument. The user should consider the following precautions when using any sensitelectronic device.• Do not install the unit near heat sources such as radi
tors or air ducts.• Do not install the unit in places subject to extreme
mechanical vibration or shock. If this is not avoidableuse resilient mounting. If in doubt, call your representtive.
• Observe the appropriate electrical safety codes and rulations
• If weather proofing is required consult your representtive for an optional cover.
3.1.1 Electromagnetic Compatibility ConsiderationsThe 8800T has been designed and verified by testing to meet the requirements of the EC Council EMC Directive 89/336/EEC, for Industrial, Scientific & Medical equip-ment. The sensor ground (8800T housing) is isolated from the 4-20mA loop, however they are also shunted with a 2000pF capacitor and a 33V Transient Voltage Suppressthis prevents electrostatic buildup, noise pick-up, and in conjunction with the internal fuse protects the instrumentfrom over-voltage inputs. Please consider the following electromagnetic interference issues during installation:• In order to provide an acceptable noise environment
the 8800T or any other digital equipment in the proxim-ity of inductive loads, it is recommended that there bevaristors placed across the inductors to keep down thhigh voltage spikes during transitions.
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• Any circuitry which is activated by relay contacts should account for the contact bounce, one simple debouncing method is placing a capacitor across therelay contacts.
• AC power wiring should be routed as far away from th8800T and its wiring as practical.
3.2 Instrument Technical SpecificationsEnclosure: .........................Stainless Steel, optional weather proof cover is a
able.Dimensions & Weight:......~2”Dia. x ~4.75” long including sensor & connect
(see appendix C) 0.5lbs.Pressure operating range: ..Standard: .....500 PSI (34 bar).
Optional: .....5,000 PSI (340 bar).Mechanical connections:...14mm x 1.25mm threads, and ¾”-16 threads.Electrical connections: ......2.1mm x 5.5mm (12mm minimum barrel length)
power jack, with retainer.Cable: ................................Two conductor cable, 12’ (~4m) provided.Power Requirements: ........10 to 33 VDC polarity independent, the instrume
draws 4-20mA depending on measured dewpoint.
Input resolution: ................0.1°C dewpoint.Indicators: .........................3.5 digit LCD with custom legends.
Engineering units: .............°C,°F, PPM, LBS H2O/mm scf,gm H2O/M3.Controls:............................3 push buttons, user’s selections are stored in
EEPROM.Outputs:.............................Analog and digital outputs are available from the
8800T. A. 4-20mA drawn by the instrument from the powesupply. The 4-20mA is linear to the selected engi-neering units, the range is programmable. Output resolution is 0.1°C dewpoint. B. The instrument can supply digital output by modulating the 4-20mA loop line. The timing and format of the data conforms to RS-232, however tointerface to a PC or other RS-232 device an optionadapter is required. In the digital mode the 8800T can be remotely operated and the dewpoint as well as temperature
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(and pressure if installed) can be read. In the digital mode multiple units can operate on the same loop cable as a multi-channel instrument
Alarms:..............................The 4-20mA signal or the digital output may be uby an external device to operate relays.
Isolation: ...........................Sensor and case are isolated from the current lobut are shunted with a 33V transorb and 2000pF capacitor.
3.3 Installation
3.3.1 Mechanical InstallationThe 8800T has two thread sizes for mounting to the sample cavity (consult the sensor installation section) where the dewpoint will be measured. Various adapters are availabfor direct connection into existing system openings. Ask your representative for a Sample Cell, if you do not have ability to provide an appropriate sample cavity mounting.the ¾”x16 thread is used then the 8800T wil l seal against the wall of the sample cell with the provided Viton A O-ring. Ithe 14mm x 1.25 spark plug thread is used then an addi-tional Viton gasket must be installed to provide the propeseal. Ask your representative for this gasket, it is availabfree of charge. The 8800T is light enough such that either thread will mechanically support the whole instrument. Toprevent any leaks, tighten the 8800T into the sample cavity, with a 17/8” wrench, 1/8 turn past finger-tight to assure metal-to-metal contact. Since the tightened positioning of the 8800T is unpredict-able, its front panel may be rotated (360°) to allow easy reading of the display. Press down gently on the spring loaded face plate and turn it to the desired position.The sensor can be removed from the 8800T by unscrewing it. Make sure that the sensor is securely fastened to the
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8800T User’ s Manual
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8800T (the tension washer should be compressed), so that it does not come loose during use.
3.3.2 Electrical InstallationThe 8800T wil l operate properly with 10VDC to 33VDC at its input, if this voltage is exceeded the internal fuse mayblow. When selecting the power supply voltage do not neglect the drop across any current measurement resistoand wiring in the loop. The connector is a standard 2.1mm x 5.5mm (12mm minimum barrel length) DC power jack, ainternal diode bridge accommodates either polarity. The 8800T may be powered using an off-the-shelf wall trans-former with 2.1mm connector, or from a power supply using the provided connectorized cable. The provided cais terminated with a connector which has a retainer, the retainer may be used to secure the connector to the 8800T thus avoiding accidental disconnection.The 8800T wil l draw 4mA to 20mA from the power supply depending on the dewpoint being measured. The dewpocorresponding to 4mA and to 20mA are user selectable, between the current will vary linearly to the selected engneering units, see appendix G.Various strategies for interfacing with the 8800T are shown in Appendix D.Please observe good electrical safety and grounding pratices when connecting any electrical equipment; connectone end (e.g. negative) of the power supply to earth grouis advisable.After the installation is complete, proper detection by theuser’s equipment of the 4-20mA output, may be tested usthe Analog Output test feature of the 8800T, see section 3.4.5.6.
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3.4 Operating the Instrument
3.4.1 Starting upThe instrument is ready for use as soon as the power cabinstalled. When power is applied the instrument will initiaize its program and for a moment display ;(1, then it will enter the Operating State. If the MODE button is held pressed while the instrument is performing its power-up itialization, it will enter the Set-Up State, which allows theuser to select operating variables of the instrument. To accommodate a variety of installation possibilities, the8800T front panel may be rotated (360°) by gently pressing down on the spring loaded face plate and turning it to thedesired position.
3.4.2 Display Conventions1. To display characters with the 7 segment numeric dis
play, the following pseudo-alphanumerics are used:Numbers: 0 12 3 4 5 6 7 8 9� � � � � � � � � �
Letters:ABCDEF GH IJ LNOP QRS TUXYZ$ % & ' ( ) * + �, - / 1 2 3 4 5 6 7 8 ; < =
Symbols:? - ." � �
2. The instrument will indicate whether a particular modlets you change a parameter by showing the word “SET” in the upper left corner of the display. Be carefu
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not to change any parameter inadvertently.3. °C°F appear simultaneously, to indicate the sensors’
attenuation in decibels.4. Values larger than ±1999 or smaller than ±0.01 are d
played in powers of 10±3. As required, either a “10 3” or
“10-3” will appear above and to the right of the dis-played value, the value will be rounded off to 3½ digitThe display will show 51* (out of ranGe), if the num-ber to be displayed is larger than 1,999,000. Twelve examples follow; for each the number and units desirto be displayed are shown in italics, depicted immedi-ately below them is the resultant 3½ digit LCD display
˚C DEWPOINT
˚F DEWPOINT
x10 3
PPM DEWPOINT
LBSDEWPOINT
DEWPOINT G/M3
+20°C
-100°C
+68°F
-148°F
23,612 ppmV
0.013,849
ppmV
2,000,000
0.000,000,1
1104.2
lbs H
2
O/mmSCF
0.000,921,15
lbs H
2
O/mmSCF
17.688
grams H
2
O/meters
3
0.000,014,75
grams H
2
O/meters
3
˚C DEWPOINT
˚F DEWPOINT
x10-3
PPM DEWPOINT
x10-3
LBSDEWPOINT
x10-3
DEWPOINT G/M3
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3.4.3 Push ButtonsThree push buttons are located on the front panel.
Each button is marked with an icon engraved above it.In general the MODE button navigates through the differeuser options “Modes”; the UP and DOWN buttons modifythe units, values or choices in the selected mode. Refer the flow diagrams in Appendix A for detailed overview ofbutton functionality. A button may be held down for a prolonged time, for accelerated incrementing or decrementinof numeric values.
3.4.4 Operating StateUpon power up, the unit performs certain initialization tes(see table in section 3.5), and enters the ‘Operating Statethe Viewing Dewpoint mode. Depressing the ‘MODE’ button will change modes (see appendix A) in the following order: nViewing Dewpoint ‹ oViewing Temperature ‹ pStart Calibration ‹ qViewing Serial Number ‹ (back to) nViewing Dewpoint. The unit will return to Viewing Dew-point mode if no buttons are pressed for 30 seconds, unlit is performing a calibration.
SET %HILOTEMPDEWPOINT PSI G/M³ LBS
x10¯³PPM˚C˚F
Teledyne 8800T
MODE button UP button DOWN button
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3.4.4.1 Viewing Dewpoint ModeIn this mode the user can view the dewpoint, this is indi-cated by the presence of the ‘DEWPOINT’ legend on thelower left of the display. The available engineering units which to view the moisture content are °C, °F, PPM, LBS
and G/M3; the UP and DOWN buttons scroll back and fortthrough these units in respective order. The °C and °F ardewpoint readings. The PPM is parts per million by volumcomputed at the sensor pressure (more about pressure i
appendix F). The LBS and G/M3 are pounds of water per million standard cubic feet and grams of water per standcubic meters, both in Natural Gas, they are computed according to data derived by IGT Research Bulletin 8, taing into account sensor pressure.Note that the analog output is linear to the selected engi-neering units, therefore be mindful that while scrolling through various units the analog output may change evethough the measured dewpoint is stable.The PSI legend flashes at the bottom of the display, whethere is pressure correction in the computation of the displayed values, refer to appendix F.
3.4.4.2 Viewing Temperature at the SensorIn this mode the user can view the thermodynamic tempeture at the dewpoint sensor inside the sampling chamberthis is indicated by the flashing ‘TEMP’ legend on the loweleft of the display. The available units in which to view thetemperature are °C and °F. The UP and DOWN buttons switch back and forth between these units.Pressing the MODE button changes to the Start CalibratMode.
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3.4.4.3 Start Calibration (SpanCheck™) ModeThe instrument is calibrated at the factory with the sensois shipped with and does not need to be re-calibrated prito installation.
Instrument calibration is recommended in approximately month intervals, and the XTR65W sensor should be re-cbrated after prolonged exposure to liquid water. Simply folow steps 1 - 7 of the procedure below, removing the senfrom the sample gas stream. Make sure the gas stream idepressurized before removing the sensor to avoid injuryIt is recommended to keep the sensor exposure to roomas short as possible to avoid super saturation of the sensWhile super saturation is not damaging to the sensor, it wprolong the initial dry-down time after you install the sensin the sample stream. Therefore, remove the sensor frompackaging container only after you are ready to proceed with the calibration procedure and install the sensor in thsample stream immediately after the calibration proceduis completed. If you are not ready to use the sensor rightaway after calibration, put the sensor back in the shippincontainer for dry storage.The instrument must be calibrated with the sensor it will used with. The calibration procedure takes advantage ofdesigned saturation level (DSL) feature of the sensor anexecuted by the instrument computer, by performing the lowing steps:
1. If the instrument is locked and a calibration is attempted; it will display /2& and will not perform the calibration. To unlock the instrument consult section 3.4.5.9.
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2. Push the MODE key a few times until the display show&$/.
3. Press the UP button. The display will show &1), prompt-ing you to confirm that you want to start the calibratioprocedure. You can abort the calibration procedure bpressing the MODE key.
4. Remove the sensor from its packaging container so tthe porous metal filter is visible and the sensor is exposed to in-hand micro-climate. Close the packagincontainer as soon as you have removed the sensor toavoid degradation of the desiccant inside of the con-tainer. You may want to re-use the container at a latedate.
5. Push the UP button again to confirm that you want tostart the calibration procedure. The display will flash $&�
for 60 seconds, while the sensor is saturating. Make syou keep the sensor exposed to in-hand micro-climatuntil the display shows (1'.
6. After 60 seconds, the display will flash the selected ssor type (see “Selecting a sensor type 3.4.5.2”) and then the instrument will calculate the slope and offset of thsensor curve while displaying the calculations and thewill display (1' for a few seconds, after which the instrument will automatically go into measuring modeThe sensor calibration is completed. (The display maflash�6$7, indicating that the sensor has super-saturatAs soon as the sensor is exposed to an atmosphere a dewpoint lower than the saturation dewpoint, the diplay will indicate the dewpoint measured by the sensoThe display may show alternating�6(1�and��/2�as an indication that the measured capacitance is too low tofrom a saturated sensor, in this case make sure that tsensor is fully engaged into the 8800T, and repeat the
page 22
Section 3: Instrument
or
r
or is hat
n. . r-ed
. ions
-ors he ate the
nt le in dew-m-
calibration procedure.7. Install the sensor in the sample cell or adapter fitting
put it back into the packaging container for later use.
The instrument will retain the calibration even if the poweis turned off.
Under certain conditions, an over (super) saturated sensmay need to be completely dried out before a calibrationperformed. Symptoms of these conditions are a sensor twill not go through the SpanCheck™ function to the (1'�
display, or a sensor that will not dry down after calibratioTo dry, install sensor in either a known dry gas stream i.einstrument quality air or dry nitrogen, or place sensor in adry can or bottle of desiccant and seal the container fromoutside air (the shipping container is designed for this pupose). After a minimum dry out period of 24 hours, procewith the calibration procedure of your choice.SpanCheck™ calibrates sensors by using micro climatesPlease contact your representative if you have any questabout how to create such micro climates.A perfectly acceptable and accurate for calibration microclimate may be created for the XTR100 and XTR65 sensby cupping the sensor in the palm of one’s hand during tSpanCheck™ procedure. Remember that the micro-climdoes not have to be accurate, it just has to be higher thandesigned saturation level. The dewpoint of the micro-cli-mate within the fingers is usually higher than the dewpoiof the room air and probably well above the +20°C upperrange of the sensor. On a dry day one may need to exhathe hand before cupping the sensor to guarantee a high point. The sensor should be warmed up close to body teperature before performing this procedure. Care must be
page 23
8800T User’ s Manual
ra-ur id
en-ber e
s
r
ts ate
ng
m d
taken that the sensor temperature is not below the tempeture of the hand, as in such case condensation could occand super saturate the sensor. For the same reason, avoexhaling directly onto the sensor.
3.4.4.4 Viewing Serial Number ModeIn this mode the user can view the serial number of the ssor calibrated and shipped with the instrument. This numis also engraved on the stainless steel sintered filter of thsensor element. The display shows the serial number byalternately displaying ;61 and the number. If the number islarger than 1999 then it is displayed in 2 parts, first part i
the thousands signified by the x103 legend in the upper rightcorner of the display and the second part is the units. Foexample serial number 12345 will be shown as:
Pressing the UP and DOWN buttons simultaneously resethe instrument, this is useful for restarting in the set-up st(by holding the MODE button), in installations where power can not be turned on and off easily.
Pressing the MODE button changes the unit to the ViewiDewpoint Mode.
3.4.5 SetUp StateTo enter the Setup State power-up the unit (or reset it frothe serial number Mode), and hold the MODE key pressewhile the unit is initializing. Refer to Appendix B for a flow
x10 3
12
345
XSN
page 24
Section 3: Instrument
-
d ‹
c-
-g te, r-
led
ing a t
on-
diagram of the SetUp State.The setup state provides nine capabilities, each one controlled from its own mode. Depressing the MODE buttonnavigates through the modes in the following order: nSe-lect Alternate Display Units ‹ oSelect Sensor Type ‹ pSet Measured Attenuation of Sensor at a Low Dewpoint ‹ qSet the Low Dewpoint at which the Attenuation was measurerSet the Calibration Mid-range Adjust ‹ sPerform a Test and Verification of the Analog Output ‹ tSet dewpoint cor-responding to 4mA of Analog Output ‹ uSet dewpoint cor-responding to 20mA of Analog Output ‹ vLock/Unlock the instrument ‹ (back to) nSelect Alternate Display Units.These nine functions are explained in their respective setions which follow. Changes can be made only to an unlocked instrument, the changes are stored (when the MODE button is pressed) and retained even if the unit isturned off.1. Display of alternate units: In this mode, a second engi
neering unit can be chosen to be displayed alternatinwith the engineering unit selected in the operating stafor example, a dewpoint can be displayed alternatingwith the sample temperature, or dewpoint can be altenately shown in °C and in PPM.
2. Selecting the sensor type: In this mode the user can select the software matching the type of sensor instalin the instrument; ;7� : XTR-100 (-100°C to +20°C);
;7� : XTR-65 (-65°C to +20°C).3&4 Adjusting low end sensor attenuation and dewpoint:
These modes are used to enter a data pair representlow dewpoint and the sensor attenuation measured athis low dewpoint. (see Sensor Theory of Operation appendix E). This data pair should not be modified unless the sensor is replaced. The sensor shipping c
page 25
8800T User’ s Manual
he
ay ef-
-n y
e e d
to
int
o
e 9
tainer is labeled with the proper values.5. Calibration Adjustment : In this mode the user can
enter a sensor specific Adjustment Value to improve tinstruments’ accuracy in the range of -50°C to -10°C,this adjustment has very little or no effect outside thisrange. The Calibration Adjustment Value is printed onthe shipping container supplied with the sensor, or mbe derived if the sensor can be exposed to a known rerence. ① Deriving an Adjustment Value: If the adjustment value for your sensor is not known, contact your representative and follow the instructions in paragraph B othe next page. If the value is not available, then it mabe derived using a manual method, provided that a moisture calibration lab is available.The calibration must be done in the range of -25°C to-20°C (attempting to calibrate outside this range maycause inaccuracies), the dewpoint must be kept stablduring calibration and it must be measured accuratelyby a reference instrument such as a chilled mirror. Onmust also note the state of pressure compensation anturn it on or off as applicable to the reference.The necessary steps are described below (also refer the Set-Up State flow diagram in Appendix B):a. Make sure that the low attenuation and low dewpoare correctly entered for this sensor.b. SpanCheck™ the sensor.c. Dry-down the sensor for at least 12 hrs.d. Expose the sensor to the known dewpoint (-25°C t-20°C), for a sufficient time (at least 30 min.)e. Go to the &$/�$'- mode and press the UP button, thdisplay will show the current value, in the range of -1.9to +1.99 followed by blinking horizontal lines.
page 26
Section 3: Instrument
a
w-
t.s d
ed
e 9
s d
e
its
nt.
f
f. Observe the display, if the buttons are not being pressed; the display will every few seconds show for short duration the dewpoint as being computed at themoment (utilizing the current cal-adjust value in the computation).g. Use the UP or DOWN buttons to modify the cal-adjust value and observe the alternately displayed depoint. Perform this adjustment until the dewpoint matches the value shown by the reference instrumenh. Press the MODE button to go to the next mode, thiwill save the new cal-adjust value, and it will be retaineeven if power is turned off.② Entering a known Adjustment Value: If the sensor is being replaced an adjustment value should be suppliwith the sensor, to enter it into the instrument:a. Go to the &$/�$'- mode and press the UP button, thdisplay will show the current value, in the range of -1.9to +1.99 followed by blinking horizontal lines, ignore the alternately displayed dewpoint.b. Use the UP or DOWN buttons to modify the cal-adjust value as necessary.c. Press the MODE button to go to the next mode, thiwill save the new cal-adjust value, and it will be retaineeven if power is turned off.
2), 3), 4) and 5) are set at the factory and need only bmodified when a sensor is changed.
6. Testing the analog output: By pushing the UP or DOWN buttons, the user forces the analog output to low and high values, respectively. This facilitates the hook-up and testing of the user’s monitoring equipme
7&8 Output range sett ing: These modes are used to set dewpoints corresponding to the low and/or high end o
page 27
8800T User’ s Manual
tru-
u-
e
l if
o
s
be has d
the current loop output, refer to appendix G.9. Lock/Unlock the instrument: This mode is used to
block access to parameter settings, protecting the insment from unauthorized or inadvertent changes of parameters. Attempting to change settings while instrment is locked will display /2&�To unlock the instrument press the UP button, to lockthe instrument press the DOWN button. Pressing theMODE button will navigate back to the Select AlternatDisplay Units mode.Pressing and holding either the UP or DOWN button,will save the lock or unlock setting depending on the button, and reset the instrument. This feature is usefuit is difficult to power off the instrument.Note: It is imperative that one returns the instrument tthe locked mode to avoid unauthorized changes.
3.5 Troubleshooting the Instrument
This instrument performs diagnostic tests on power up awell as once every two minutes. The table that follows, depicts all possible error/unexpected messages that maydisplayed on the instrument. For each message the tableexplanations for the reason, and if necessary a suggesteaction to remedy it.
page 28
Section 3: Instrument
a
Legend: �denotes alternately flashing messages.
DISPLAY EXPLANATION REQUIRED ACTION
LO����(55 PROM check sum failed.
pow
er o
n te
sts
HI ����(55 RAM write/read test failed. cycle power
%����(55 Unidentified power-up failure. if problem persists,
&�6�)� EEPROM Check Sum Failed. return to your representative
(55�$' A/D converter failure.
sys
tem
tes
ts o
nce
per
2 m
in. for service.
(55�5() Reference voltage for A/D out of spec.
/2�%$7 Low supply voltage. check input voltage 10-33VDC
LO�51*�
TEMPInstrument low temperature range
has been exceeded. make sure that the unit is at
HI ���51*�TEMP
Instrument high temperature rangehas been exceeded.
temperature of -10°C to +70°C.
231� Sensor circuit is open.
dew
poin
t dis
play
test
s see table in
6$7� Sensor is saturated. sensor troubleshooting
6+5� Sensor circuit is shorted. section
��� Trying to calculate dewpoint for undefined sensor.
select sensor and SpanCheck.
'% Trying to calibrate an undefined sensor.
Ca
libra
tion.
tes
ts see Calibration instructions.
6(1��/2 Sensor reading is ‘too’ low to be a satu-rated sensor, for SpanCheck.
(55�((3 EEPROM write cycle not completed.
mis
cella
neou
s
if this persists, return for service.
/2& Attempting to modify a locked unit. unlock unit, see set-up mode.
51* number can not be displayed in 3.5 digits.
���°C(���°F)w/flashingDEWPOINT
An XTR-65 sensor is measuring less than -70°C or -94°F dewpoint.
PSI flashingwhen dew
Pressure correction is enabled.
;(1 Turn on message, Xentaur (Greek Ξ=X)
page 29
8800T User’ s Manual
ca-
the
The instrument contains a fuse which may open if the instrument is subjected to voltages exceeding the specifitions. Under these circumstances the unit display will beblank and the instrument will not draw any current when powered up. The fuse is not user replaceable, therefore 8800T must be sent to your representative for servicing.
page 30
Appendices
Appendix A: Operating State User Interface flowchart
TEMP ˚F
Teledyne 8800T
SET
Teledyne 8800T
SET
Teledyne 8800T
Teledyne 8800T
Press together toRESET the Instrument. Then quickly press and hold MODE to go to Set-Up State.
SensorReading Too Low
OK
ViewingDewpoint
ViewingSensor
Temperature
CalibrationMenu
ViewingSerial
Number
Can
cel C
alib
ratio
n (c
alib
ratio
n va
lues
are
not
cha
nged
)
1 minute
1sec.
few seconds
2 se
c.
1 sec.
New
Cal
ibra
tion
Val
ues
Sto
red
selectunits
selectunits
SET
Teledyne 8800T
numbers calculatingcalibration
SET
Teledyne 8800T
SEN/2LO
SET
Teledyne 8800T
AC/_AC
SET
Teledyne 8800T
CNF/AC?
Teledyne 8800T
CAN
Confirm SpanCheck™
LEGEND: 1. Arrows leading out from below a button depict the flow as a result of pressing the button. 2. Arrows leading out of other locations depict flow as a result of completing a function or a time-out. 3. A slash '/' in the display area, is used to depict two alternately shown (flashing back and forth) messages.
Power ON initializationand sign on message
30 seconds anywhereother than calibrationwithout a key press
DEWPOINT ˚C
Teledyne 8800T
PSI
a flashingPSI legendmeans pressurecorrection isbeing applied,see appendix F
page 31
8800T User’ s Manual
/
A.0./TST
LO/BAT
A.O./RNG/
A.O./RNG/
UN/LOC
Appendix B: Set-Up State User Interface flowchart
SE
T
SE
T
LO
DE
WP
OIN
T˚C
SE
T
LO
˚C˚F
Cho
ose
alte
rnat
e un
its to
sho
w w
hen
disp
layi
ng d
ewpo
int
Cho
ose
Sen
sor
type
Set
mea
sure
d at
tenu
atio
n at
a k
now
n lo
w d
ewpo
int
Set
low
dew
poin
t for
the
abov
e se
t atte
nuat
ion
Cal
ibra
tion
Mid
rang
e A
djus
t
CAUTION! These parameters are set properly at the factory, to correspond to the shipped sensor. Do not modify them
unless you are replacing the sensor.
Pow
er-U
p w
ith
MO
DE
key
pre
ssed
LOC a
ppea
rs w
hen
chan
ging
setti
ngs
of a
lock
ed in
stru
men
t
SE
T
ALT/DSP
SE
T
SEN/XT1
DB/
SE
T
CAL/ADJ
+/-
0.01
dB
+/-
0.1˚
C
+/-
0.01
uni
ts
XT1
XT6
DB
XT
R-1
00X
TR
-65
atte
nuat
ion
Fact
ory
defa
ult i
s bl
ank
(the
re is
no
alte
rnat
e di
spla
y).
blan
k˚F
˚Cpp
mLB
SG
/M3
Tem
p˚F
Tem
p˚C
%P
SI
˚C˚F
If no
but
tons
pre
ssed
for
3 se
cond
s th
e de
wis
sho
wn
for
a m
omen
t.
page 32
Appendices
LOC
ALT/DSP
SEN/XT1
DB/
CAL/ADJ
XT1
XT6
DB
User Interface Flow Diagram - Set-Up State (continued from previous page)
LEG
EN
D:
1. A
rrow
s le
adin
g ou
t fro
m b
elow
a b
utto
n de
pict
the
flow
as
a re
sult
of
pre
ssin
g th
e bu
tton.
2. A
sla
sh '/
' in
the
disp
lay
area
, is
used
to d
epic
t tw
o al
tern
atel
y
sho
wn
(fla
shin
g ba
ck a
nd fo
rth)
mes
sage
s.
SE
T
H
I˚C
SE
T
LO
˚C
Test
Ana
log
Out
put
Set
dew
poin
t cor
resp
ondi
ng to
low
end
of a
nalo
g ou
tput
Set
dew
poin
t cor
resp
ondi
ng to
hig
h en
d of
ana
log
outp
ut
Lock
or
unlo
ck th
e in
stru
men
t
Test
Cur
rent
Loo
pVo
ltage
OK
Too
Low
20m
A4mA
Unl
ock
Lock
Pro
long
ed p
ress
of e
ither
but
ton
will
res
et th
e un
it
Whe
n lo
cked
inst
rum
ent p
aram
eter
s ca
n no
t be
chan
ged.
Fact
ory
defa
ult i
s lo
cked
.
HIL
OA.0./TST
LO/BAT
A.O./RNG/
A.O./RNG/
SE
T
UN/LOC
+/-
0.1˚
C
+/-
0.1˚
C
Fact
ory
defa
ult i
s -1
00˚C
Fact
ory
defa
ult i
s 20
˚C
Ens
ure
min
imum
vol
tage
at L
PD
Tto
be
10V
DC
, whe
n dr
awin
g 20
mA
page 33
8800T User’ s Manual
Appendix C: 8800T Mechanical Drawing
flats
for
1 "
wre
nch
7 8/
1.750"
oint Transmitter
Ma
Se
Mo
ThinkSafety Read Manual
www.teledyne-ai.com
SE
T
%H
ILO
TE
MP
DE
WP
OIN
T
PS
I G
/M³
L
BS
x10¯
³P
PM
˚C˚F
Tel
edyn
e
8
800T
14m
m x
12.
5mm
3/4"
-16
Vito
n A
O-r
ing
2.23
0"1.
850"
0.60
0"
Pow
er J
ack
scre
w-o
n re
tain
er
DC
Pow
er J
ack
Rem
ovab
le S
enso
r en
caps
ulat
edin
100m
sin
tere
d st
ainl
ess
stee
l,un
scre
w to
rem
ove.
5/16
"-24
tens
ion
was
her
fron
t pan
elro
tate
sfre
ely
360˚
page 34
Appendices
Appendix D: 8800T Electr ical Connections
Operation with Wall Transformer Dewpoint viewed on Instrument Display
Operation with Relay Option Board Dewpoint viewed on Instrument Display
and available as 4-20mA output
Operation with Remote Option Board Dewpoint viewed on Instrument Display
and available on remote
Operation with Multichannel Option Board Dewpoint viewed on each Instrument Display
and available on remote interface
Operation with DC Power Supply Dewpoint viewed on Instrument Display
and available as 4-20mA output
Operation with DC Power Supply Dewpoint viewed on Instrument Display
and available as Voltage output
Wall
Tran
sform
er120V
or 220V
VDC
DC or AC supply
10-33VDC
4-20mA
4-20mA
12-33VDC
0.4 - 2V output100W
Relay Option Board Provides two
independent Relays with programmable
trip point and hysteresis
85 - 265VAC
DC or AC supply
Display Buttons Relays
Voltage or Current Output
RS-232 Output Power Supply
RS-232C to ComputerMultichannel
Option Board
multiple units connected on the same two wires
Methods of Using and Interfacing the 8800T
maintain 10-33VDC here
oint Transmitter
Ma
Se
Mo
ThinkSafety Read Manual
www.xentaur.com
oint Transmitter
Ma
Se
Mo
ThinkSafety Read Manual
www.xentaur.com
oint Transmitter
Ma
Se
Mo
ThinkSafety Read Manual
www.xentaur.com
oint Transmitter
Ma
SeM
o
Think
Safety
Read
Manual
www.xentaur.com
oint Transmitter
Ma
SeM
o
Think
Safety
Read
Manual
www.xentaur.com
oint Transmitter
Ma
SeM
o
Think
Safety
Read
Manual
www.xentaur.com
oint Transmitter
Ma
Se
Mo
ThinkSafety Read Manual
www.xentaur.com
oint Transmitter
Ma
Se
Mo
ThinkSafety Read Manual
www.xentaur.com
page 35
8800T User’ s Manual
ic at tes and
on-ing tant ses e
me ter lu-
er o-en-of rve.
ile -at-nd e
is is g nsa-
Appendix E: Sensor/SpanCheck™ Theory of Operation
The Sensor is constructed as a capacitor whose dielectrconsists of porous Aluminum Oxide as well as the gas thhas entered in the pores of the Aluminum Oxide. The pla(electrodes) of this capacitor are an aluminum substrate a porous gold layer deposited on top of the Aluminum Oxide, the porous gold electrode allows transfer of gasesinto or out of the Aluminum Oxide pores.The capacitance due to the Aluminum Oxide is always cstant, while the capacitance due to the gas varies accordto the gas content and pressure. Since the dielectric consof water is orders of magnitude larger than that of any gabeing measured, the quantity of water vapor present in thpores changes the capacitance of the sensor to a much greater extent than any other system variable. For the sareason (the extremely large dielectric constant of the wamolecule), any capacitance variations arising from the Aminum Oxide, such as changes due to temperature, are insignificant in relation to the capacitance due to the watcontent. Thus the sensor capacitance varies greatly in prportion to the water content in the surrounding gas. The ssor is designed such that the relationship of the quantity water and the resultant capacitance has an "S" shaped cuAt the extremely dry end the curve is asymptotic to the capacitance due to the Aluminum Oxide and the gas, what the very wet end the curve is asymptotic to the capacitance due to water molecules packed extremely tightly (surated) in the pores of the Aluminum Oxide. This upper eis an excellent indication of the total pore volume; while thlower end of the curve is an indication of the distance between, and area of the capacitor plates (electrodes), ththe intrinsic capacitance of the sensor. Therefore knowinthese two points, a sensor can be calibrated with compe
page 36
Appendices
en-
ith of ec-
ue
ent e t nce, nt
he the
ges
tion for small manufacturing deviations. As the sensor is used in real world applications, it is exposed to various elements and stress; like any other ssor it may over time drift from calibration. However one must note that the intrinsic capacitance will not change wuse because it is based simply on the dielectric constantAl2O3 and the distance between, & area of the plates (eltrodes), thus the original factory measured values will always be valid. What may change is the pore volume, dto clogging with contaminants, residual oxidation, metal migration, etc. Thus to re-calibrate the sensor the instrumneeds only to "know" the capacitance at the wet end of thcurve. As discussed previously the capacitance at the weend approaches asymptotically a saturated pore capacitatherefore if the sensor is saturated (the exact water contewill not be important since the curve is asymptotic), then tinstrument can measure the capacitance and re-calibratesensor. This is refered to as SpanCheck™. The advantaof this unique capabil ity of Teledyne sensors and instrumentsare obvious in time and cost savings for re-calibration, aswell as ease of sensor replacement.
Teledyne HTF™ Sensor: Dewpoint vs. Capacitance Response Curve
Dewpoint Reference ˚C
Cap
acita
nce
(nF
)
NewSen
so
r Curve
Aged Sensor Curve
0
40
80
120
160
200
-80 -60 -40 -20 0 20
Saturated Capacitance Asymtote of Aged Sensor
Dry Capacitance Asymtote of New & Aged Sensor
Saturated Capacitance Asymtote of New Sensor
page 37
8800T User’ s Manual
page 38
Appendices
or. at
(we -
se °C hat w-ow-
nd
ures
or tory.
Appendix F: Pressure Correction
Sensor Pressure is used in the context that this is the pres-sure inside the sampling chamber when performing the measurement, i.e. it is the operating pressure of the sensGas Pressure is used in the context that this is the pressurewhich the dewpoint is to be calculated.Pressure Correction is used in the context that the values displayed signify the moisture content at some pressure refer to this as the ‘Gas Pressure’) different from the pres
sure at the sensor. Note that PPM, LBS and G/M3 readings are by definition unaffected by pressure correction becauonly the pressure at the sensor affects their value. Whileand °F are affected by pressure correction by reporting wthe dewpoint would be at the Gas Pressure when the depoint is what is measured at the pressure at the sensor. Hever, this also implies that whether pressure correction is
applied or not the PPM, LBS and G/M3 readings are affected by the setting of the sensor pressure.The factory default settings are: 14.7psi for both sensor agas pressure and pressure correction disabled.When Pressure correction is disabled all dewpoints are computed by assuming that both Sensor and Gas Pressare 14.7psi.As all Teledyne dewpoint meters, the 8800T is equipped with the necessary software to perform pressure correction. However, for the lack of space, the 8800T does not have a Pressure Correct button. Therefore the user can not set enable Pressure Correction, this must be done at the facConsult with your representative.
page 39
8800T User’ s Manual
ust
nd
:
r to r -i-
-
Appendix G: Current vs. Dewpoint
The current being pulled by the 8800T, varies with the dew-point being measured by the 8800T. To use the current to calculate the value of the dewpoint measurement, one mknow the settings of the low and high ends of the analogoutput range, then:
where: I = current drawn by 8800T loop in mA.H = value of High end of Analog Output range
converted to selected engineering unitsL = value of Low end of Analog Output range
converted to selected engineering unitsD = dewpoint measured by instrument in selected
engineering units.Consult section 3.4.5.7&8 and/or appendix B, to check aset the Analog Output low and high ranges; the factory default settings are -100°C and +20°C respectively.For example a unit with factory default settings, drawing 12mA is computed to be measuring a dewpoint of -40°C
Note that the computation is such that the current is lineathe selected engineering units. Hence, selecting ppmV oLBS or G/M3 units, will cause the analog output to be linearly proportional to those units (approximately logarithmcally proportional to dewpoint), refer to the graph that follows. Naturally selecting °C or °F will cause the analogoutput to be linearly proportional to dewpoint. When monitoring in ppmV or LBS or G/M3, the analog output low & high ranges may have to be adjusted to pro
D I 4–( ) H L–( )×16
---------------------------------------- L+=
12 4–( ) 20 100–( )–( )×16
------------------------------------------------------------ 100–( )+ 40–=
page 40
Appendices
a of og C t-r-st r
hat 0 to
nge
A
’s S ing
g
u-x to
is et-to the
vide a useful output. Consider an example where the areinterest to be monitored is 10 to 100 ppmV, and the analoutput is set up with the factory defaults of -100°C to +20°(which is 0.014 to 23612 ppmV); then the current loop ouput will vary only from ~4.1 to ~4.2 mA in the area of inteest (consult with the graph on the following page). In moinstances this would be an unacceptable output for propemonitoring of the measurement. In this example the usershould adjust the analog output low & high ranges such tthe output range is better suited to the measurement of 1100 ppmV. It may be useful to select the low and high ranges to be 5 and 150 ppmV respectively, thus out of raconditions will be detected properly. Then the low range will be set to 5ppmV which is -65.5°C dewpoint, and the high range will be set to 150ppmV which is -38.5°C dew-point. Now the current loop output will be 4.55 to 14.48 min the range of 10 to 100 ppmV, the ~10mA variation is more than sufficient for a good measurement by the userequipment. One may carry out similar calculations for LBor G/M3 and choose the appropriate settings. While makthese computations it may be useful to obtain a copy of Teledyne’s dewpoint calculator, this is a Microsoft Win-dows™ program which simplifies the process of convertindewpoint measurement units. It is available at www.Tel-edyne-ai.com. If you are not certain how to carry out such calclations send, by e-mail to [email protected] or by fa(626) 961-2538, your system specifics, and some one wil l get back to you with appropriate analog output settings. In general, if the dewpoint is monitored in °C or °F, thereno need to change the factory default -100°C to +20°C stings, because the 4-20mA provides sufficient resolution measure the output better than the specified accuracy ofsensor.
page 41
8800T User’ s Manual
BS
Relationship of 4-20mA output and instrument reading in ppmV or LInstru
men
t rea
ding
in p
pmV
Inst
rum
ent r
eadi
ng in
LB
S o
f H2O
/ m
illio
n cu
bic
feet
1010
010
0010
000
4.1m
A
5mA 0.
11
1010
010
00
12m
A
8mA
20m
A
4.5m
A
4/20 mA output
0.56 LBS = -60˚C = 10.66 ppmV
1.97 LBS = -50˚C = 38.83 ppmV
49.3 LBS = -20˚C = 1019.3 ppmV
289.1 LBS = 0˚C = 6063.8 ppmV
Low A
O rang
e =
-100
˚C H
igh A
O rang
e =
+20˚
C
Low A
O range = -6
5.5˚C High A
O range = -3
8.5˚C
page 42
Appendices
Appendix H: Uncertainty in LBS & ppmV calculationsU
ncer
tain
ty o
f LB
S &
ppm
V c
alcu
latio
ns d
ue to
+/-
3˚C
mea
surm
ent a
ccur
acy
Cal
cula
ted
ppm
V
Cal
cula
ted
LBS
H2O
/ m
msc
f
-80
-75
-70
-65
-60
-55
-50
-45
-40
-35
-30
-25
-20
0.5
0.5
0.25
2.5
0.05
0.6
0.70.80.9
1
1
0.12
3
4
5
5
6
789
10
10
20
30
40
48
3834
29
24
19
15
44
50
60
708090
100
200
300
400
500
600
700800900
1000
Measured Dewpoint ˚C
Dew
poin
t -3˚
C
Dew
poin
t +3˚
C
page 43
8800T User’ s Manual
Appendix I: Sensor Response Time
Tim
e (m
inut
es)
% of step change
0 5 10 15 20 25 30 35 40 45 50 55 60 65 70 75 80 85 90 95 100
105
05
1015
2025
3035
4045
5055
6065
7075
8085
9095
100
65%
of s
tep
chan
ge
95%
of s
tep
chan
ge
R
espo
nse
Tim
e of
TA
I A
l 2O
3 S
enso
rs to
a S
tep-
chan
ge (
DO
WN
) fr
om -
39.4
˚C
(dp)
at t
ime
0, to
-62
.2 ˚
C(d
p) a
fter
48hr
s of
equ
ilibr
ium
page 44
Teledyne, 16830 Chestnut St., City of Industry, CA 91748 Tel: (626) 934-1500
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