TORO TDC解码控制器使用数明书

ߜ10 PID Control Loops with Auto-Tuning ߜJ, K, T, E, R or S Thermocouple, RTD and 4 to 20 mA Current Input TypesSelectable for Each Loopߜ 2 Alarm Setpoints Per LoopߜOptical Isolation for ElectricallyNoisy EnvironmentsProgram 28145679103Probes sold separately.KQSS-316G-12, $25 eachSee Section AߜRelay, Triac, 4 to 20 mA andac SSR Output CapabilityߜOptional RS-232, RS-422 andRS-485 Digital CommunicationsߜCoded Security Levels to PreventUnauthorized Access to ProgrammingߜModular Construction Allows FieldInstallation of Output, Alarm, andCommunications OptionsCN3390 Series$2480Basic UnitMulti-Loop PID Temperature/Process Controllers CN3390 SeriesACCEPTS10 INPUTS!P-129P-130Takes the Place of Ten ControllersThe OMEGA ®CN3390 ON/OFF, proportional, PID Multi-Loop Temperature/Process Controller,measuring only 95 mm (3.75") deep, features the inputs,outputs, programmable features and sophisticated control techniques typically found only in much larger controllers. The CN3390 requires only 30% of the mounting space required for 10 individual controllers. All hardwiring is done once on high quality plug-on terminal strips, so the unit can easily be installed or taken out of service.The CN3390, with its optical isolation of inputs, outputs and optional digital communications, is built to handle most real-world factory conditionswithout special filtering equipment, such as snubbers,isolated power supplies or noise suppressors.Digital Signal Processing (DSP) sets the CN3390controller apart from other multi-loop controllers. DSP maintains the integrity of the sensor input signals, resulting in more stable control. Over-sampling of inputs (92 times per second per input) and an input update rate of 0.5 seconds per loop ensure that theCN3390 responds quickly to process changes.Through simple programming selections, you can adjust the controller displays to establish the range and engineering units of indication for the current input.The CN3390 provides two alarm setpoints per loop (20 total), and an alarm LED for each loop. Any of these 20setpoints can be connected to the common alarm output or one of ten optional alarm outputs. The common alarm output can be turned off fromeither the front panel alarm acknowledge pushbutton or from a remote pushbutton.The CN3390 alarm setpoints can be mapped to an optional internal alarm board. The alarm board’s digital alarm outputs or the common alarm can be connected to a remote single relay alarm module or an external 10-relay alarm output board.All control selections and programmed information are selectable from the front panel pushbuttons. Straightforward cues and high resolution LED’s send clear messages regarding the operation,set-up and programming of the controller. The autoscan feature scrolls through each loop, displaying process temperature, setpoint and loop number.Optional RS-232C, RS-422A and RS-485 digital communications are available for all 10 loops. Using RS-422A or RS-485, you can address up to 255 controllers.CN3390 offers flexible mounting: remote mounting,panel door mounting, or basic sub-panel mounting. The front panel display plugs directly into the controller chassis so it can be mounted remotely or simply removed to prohibit tampering or unauthorizedprogramming. Remote connection cables are available in 450 mm (18"), 1.5 m (5') and 4.5 m (15') lengths.CN3390 shown with remote mounting cableP-131SpecificationsControl Modes (Field Selectable)Automatic:ON/OFF,proportional, proportional with automatic reset/integral and/or rate/derivative (PID, PI, PD)Manual:Bumpless, balanceless transfer with proportional control;disintegration time = 1 to 100 sec Control Adjustments (Field Selectable)Control Setpoint:Instrument sensor range (°F, °C, %)Setpoint Limits:Instrument sensor range Deadband:0.01 to 25.00%Proportional Band:0.1 to 999.9% of span Automatic Reset:0.00 to 99.99repeats/minute Rate:0 to 1000 secondsOutput Cycle Time:0.1 to 60.0 secondsOutput Limit:0 to 100% ON Control Outputs (Plug-In):Total 5outputs modules, 2 control loops per output module Relay:N.O., rated 1.0 A @120Vac or 0.5 A @ 230 VAc (resistive load)1 A SSR: 1 A continuous, 10 A in-rush current at 120 or 230 Vac (resistive load)Current/Voltage:Non-isolated:4to 20 mA into 0 to 800 Ωload;isolated: 4 to 20 mA into 0 to 400Ωload with 24 V power supply SSR Pulse:transistor output of 20Vdc nominal at 40 mAAlarm Outputs: 2 field assignable alarm setpoints per loop, each can be mapped to any one of 10 alarm outputs or the common alarmoutput; 1 common latching alarm output, current limited, emitterfollower transistor; optional 10 open collector transistor outputs,sink 40mAdc at 50VdcAlarm Modes:High and low, range 100% of span, non-latching; ±deviation, sensor span above/below control setpointReset Differential: 0 to 25%instrument sensor range, 0.01incrementsAlarm Relay Board (Optional):10 relays, rated 10 A @ 120 V, form C contacts; includes 24 Vdc power supply (unregulated) to power relay coils; requires 120 Vac or 240 Vac inputInput Update Rate: 2 updates per second (92 samples per second)CN3390 Multi-Loop PIDTemperature/Process ControllersP-132two relays, one 1 A SSR, one 4-20 mA isolated and one 20 Vdc pulse control outputs, with optional digital communications, $2480 + 85 + 370 = $2935Ordering Example: CN3390-R , ten loop controller with ten relay outputs = $2480OCW-1 OMEGACARE SM extends standard 1-year warranty to a total of 2 years ($150), $2480 + 150 = $2630Open Sensor andOut-Of-Range Conditions:Programmable for 0-100% output Digital Communications Option: RS-232C single drop, isolated;RS-422A, RS-485 multi-drop, isolated; baud rate 300, 600, 1200, 2400, 4800, 9600, 19,200; data string ASCII,asynchronous, one start, one parity, seven data and one stop bit or binary Instrument Power:120 or 230 Vac(+10%, -15%), 50 to 60 Hz, 7 VA nominal power consumptionOperating Environment:0 to 55°C (30 to 130°F) ambient temperature with relative humidity less than 95% non-condensing Dimensions:318 W x 292 D x 95 mm L (12.5 x 11.5 x 3.75")Weight: 10 lb (4.5 kg)†3390A-RS is equivalent to -2optionOMEGACARE SM extended warranty program is available for models shown on this page. Ask your sales representative for full details when placing an order.CANADA www.omega.ca Laval(Quebec) 1-800-TC-OMEGA UNITED KINGDOM www. Manchester, England0800-488-488GERMANY www.omega.deDeckenpfronn, Germany************FRANCE www.omega.frGuyancourt, France088-466-342BENELUX www.omega.nl Amstelveen, NL 0800-099-33-44UNITED STATES 1-800-TC-OMEGA Stamford, CT.CZECH REPUBLIC www.omegaeng.cz Karviná, Czech Republic596-311-899TemperatureCalibrators, Connectors, General Test and MeasurementInstruments, Glass Bulb Thermometers, Handheld Instruments for Temperature Measurement, Ice Point References,Indicating Labels, Crayons, Cements and Lacquers, Infrared Temperature Measurement Instruments, Recorders Relative Humidity Measurement Instruments, RTD Probes, Elements and Assemblies, Temperature & Process Meters, Timers and Counters, Temperature and Process Controllers and Power Switching Devices, Thermistor Elements, Probes andAssemblies,Thermocouples Thermowells and Head and Well Assemblies, Transmitters, WirePressure, Strain and ForceDisplacement Transducers, Dynamic Measurement Force Sensors, Instrumentation for Pressure and Strain Measurements, Load Cells, Pressure Gauges, PressureReference Section, Pressure Switches, Pressure Transducers, Proximity Transducers, Regulators,Strain Gages, Torque Transducers, ValvespH and ConductivityConductivity Instrumentation, Dissolved OxygenInstrumentation, Environmental Instrumentation, pH Electrodes and Instruments, Water and Soil Analysis InstrumentationHeatersBand Heaters, Cartridge Heaters, Circulation Heaters, Comfort Heaters, Controllers, Meters and SwitchingDevices, Flexible Heaters, General Test and Measurement Instruments, Heater Hook-up Wire, Heating Cable Systems, Immersion Heaters, Process Air and Duct, Heaters, Radiant Heaters, Strip Heaters, Tubular HeatersFlow and LevelAir Velocity Indicators, Doppler Flowmeters, LevelMeasurement, Magnetic Flowmeters, Mass Flowmeters,Pitot Tubes, Pumps, Rotameters, Turbine and Paddle Wheel Flowmeters, Ultrasonic Flowmeters, Valves, Variable Area Flowmeters, Vortex Shedding FlowmetersData AcquisitionAuto-Dialers and Alarm Monitoring Systems, Communication Products and Converters, Data Acquisition and Analysis Software, Data LoggersPlug-in Cards, Signal Conditioners, USB, RS232, RS485 and Parallel Port Data Acquisition Systems, Wireless Transmitters and Receivers。

TDC-400 SeriesDC Digital High-Resolution Controller Quick Calibration & Troubleshooting GuideGENERALThe MODE button selects a particular function, or mode, and theindicator for the selected mode turns on solid. Pushing the MODE button saves any new setting of the current mode before switching to the next mode. The adjust up (▲) and adjust down (▼) buttonsare used to make adjustments to the current mode. For moredetails regarding calibration and features refer to the manual.Reference RotationsDIRECT ActingREVERSE ActingQuick Calibration Procedure1. Before applying power, ensure that the unit is properlymounted and properly wired to the actuator. Refer to the pertinent MKT Data Sheet specified for the actuator. Ensure potentiometer gears are tight and properly meshed. 2. Apply power to the actuator on Connector J2: terminal #1(neutral), terminal #2 (line), and terminal #3 (Earth). There is no need for a signal connection during calibration. 3. Push the MODE button until the yellow “MANUAL/FB POTCAL” LED is illuminated. The LED may be flashing (at different speeds) through the next several steps. This is 4. Use the adjust buttons (▲ and ▼) to move the actuator andverify that the limit switches are set past the desired open and closed positions, but not so far as to interfere with the mechanical end stops, if the actuator has this feature. Then move the actuator to mid stroke. 5. If LED is solid, proceed to Step 7. 6. If LED is flashing, loosen the gear on the actuator shaft and rotate the potentiometer until the LED is no longer flashing, but on solid – this indicates the center of the potentiometer’s travel. Note that the LED will flash as a slower rate the farther away from the mid position it gets. Once the LED is on solid tighten the actuator shaft gear and ensure that the gear engagement is tight and properly meshed.7. Push the MODE button until the “CLOSE” LED is lit solid. Usethe adjust buttons (▲ and ▼) to drive the actuator toward the desired closed position until the associated limit switch trips. Then tap the other adjust button to move the actuator just off the limit switch to the desired valve closed position. This position corresponds to a minimum input signal. 8. Push the MODE button until the “OPEN” LED is lit solid. Usethe adjust buttons (▲ and ▼) to drive the actuator toward the desired open position until the associated limit switch trips. Then tap the other adjust button to move the actuator just off the limit switch to the desired valve open position. This position corresponds to a maximum input signal.9. If an OTR-101 option module is installed, follow AuxiliaryOpen/Close Setup (see below); otherwise continue to the next step. 10. Push the MODE button until the “COMMAND TYPE” LED is litsolid. Use the adjust buttons (▲ and ▼) to select the appropriate input signal (4-20mA, 1-5VDC, 0-5VDC, 0-10VDC, 2-10VDC, or Digital). If 0-5VDC or 0-10VDC isselected, the LOSS OF COMMAND feature is not available, so proceed to Step 12. 11. Push the MODE button until the “LOSS OF COMMAND” LEDis lit solid; this sets the actuator to a predetermined position upon loss of command. Use the adjust buttons (▲ and ▼) to select appropriate position (OPEN, CLOSE, or LAST POSITION). 12. If an OTR-101 or OTX-101 option module is installed, followPosition Output Mode Setup (see below); otherwise continue to the next step. 13. Push the MODE button until the “AUTO” LED is lit solid. Yourcalibration is not COMPLETE . Connect the command signal wires to connector J2; terminal #4 (signal ground) and terminal #5 (mA input) OR terminal #6 (voltage input), depending on the application. If a signal input was already connected, the actuator should have moved to that position.Auxiliary Open/Close Setup(for units with an OTR-101 option module only)1. Push the MODE button until the “AUX CLOSE OUTPUT” LEDis lit solid. Use the adjust buttons (▲ and ▼) to drive theactuator to the desired auxiliary close position.2. Push the MODE button until the “AUX OPEN OUTPUT” LEDis lit solid. Use the adjust buttons (▲ and ▼) to drive theactuator to the desired auxiliary open position.3. Continue with Step 10 in the Quick Calibration Procedure(see above).Position Output Mode Setup(for units with an OTR-101 or OTX-101 option module only)1. Push the MODE button until the green “POSITION OUT CAL”LED is lit solid while the “CLOSE” LED flashes.2. Use the adjust buttons (▲ and ▼) to set the desired outputvoltage (VDC) or current (mA) on the option module output for the closed position.3. Push the MODE button so the “POSITION OUT CAL” LEDremains solid while the “OPEN” LED flashes. Use the adjust buttons (▲ and ▼) to set the desired output voltage (VDC) or current (mA) on the option module output for the openposition.4. Continue with Step 13 in the Quick Calibration Procedure(see above).FAULT INDICATORSThe TDC-400 detects various fault conditions that prohibit the unit from controlling the actuator. A combination of the three Fault indicators (red, yellow, and green) will turn on or flash to indicate a specific detected fault. If an appropriate relay option module is installed, the Fault relay output on the option module will turn off (indicating a fault) when any of the Fault indicators turn on or flash. A communications option module can also read the specific conditions causing a fault. Note that a fault condition DOES NOT disable the motor outputs when manually controlling the actuator with the adjust buttons; while useful for troubleshooting, care should be exercised when operating the motor under a fault condition. The OVERRIDE mode can also operate the motor when a fault condition exists - see OVERRIDE MODE for details. Note that the indicators may not indicate all the fault conditions that may exist. This means that when the indicated fault is corrected, the unit may display another fault that has not been corrected. The table below provides a summary of the Fault indications which is followed by a description of each fault.Low Battery Voltage - When the TDC-400 detects that the battery/power supply voltage connected to BAT POS (J2-1) and BAT NEG (J2-2) drops below 10V, the motor outputs are turned off and the TDC-400 suspends all other operations until the voltage returns to 10V or more. However, the Low Battery Voltage fault indication will maintain for 3 seconds after voltage returns. Since DC motors present a large load (from in-rush currents) when turned on, a weak battery or insufficient power supply may experience a short voltage drop below 10V until the motor begins to move. Therefore, the Low Battery Voltage indication provides warning of batteries in need of recharge or power supplies that have insufficient current for the application.Motor 1 Stall - A stall condition is detected when no actuator motion is detected while the Motor 1 output is turned on and drawing more than 0.5A of motor current. The fault condition will disable the Motor 1 output only, and the fault is cleared when the TDC-400 detects a motion greater than 1.5 in either direction. The fault can be cleared if 1) the command signal commands a Motor 2 operation, 2) manual operation with the adjust buttons results in a motion greater than 1.5 , or 3) a mechanical manual override forces the 1.5 motion, provided the mechanical motion is monitored by the feedback pot.Motor 2 Stall - A stall is detected when no actuator motion is detected while the Motor 2 output is turned on and drawing more than 0.5A of motor current. The fault can be cleared in the same manner as previously described for a Motor 1 Stall.Double Stall - If the TDC-400 detects a stall condition in both directions, both motor outputs will be disabled. The command signal cannot clear this condition; only manual operation or a mechanical override can clear the fault. Alternatively, the TDC-400 can be powered off and then on to temporarily clear the fault; however, this practice should be avoided without permanently correcting the cause of such a fault.Motor 1 Current Trip - A current trip fault is detected when themotor current exceeds the current trip setting (see TRIP SETTING) while the Motor 1 output is turned on. The fault can be cleared in the same manner as previously described for a Motor 1 Stall. NOTE: Successive attempts with manual operation using the adjust buttons can exceed the torque limit set by the Trip Setting.Motor 2 Current Trip - A current trip fault is detected when the motor current exceeds the current trip setting (see TRIP SETTING) while the Motor 2 output is turned on. The fault can be cleared in the same manner as previously described for a Motor 1 Current Trip.Double Current Trip - If the TDC-400 detects a current trip fault in both directions, both motor outputs will be disabled. The fault can be cleared in the same manner as previously described for a Double Stall.Motor 1 No Motion - A no motion fault is detected when no actuator motion is detected while the Motor 1 output is turned on and drawing less than 0.5A of motor current. The fault can be cleared in the same manner as previously described for a Motor 1 Stall. A stall usually indicates a heavy mechanical load or stall, while a no motion fault usually indicates a broken motor wire or disengaged feedback pot. Note that a stall cannot be detected in applications using very small motors (locked rotor currents less than 0.5A); only a no motion fault can be detected. Motor 2 No Motion - A no motion fault is detected when no actuator motion is detected while the Motor 2 output is turned on and drawing less than 0.5A of motor current. The fault can be cleared in the same manner as previously described for a Motor 1 Stall. A no motion fault differs from a stall as previously describe for a Motor 1 No Motion fault.Double No Motion - If the TDC-400 detects a no motion fault in both directions, both motor outputs will be disabled. The fault can be cleared in the same manner as previously described for a Double Stall.Feedback Alarm - A fault condition is detected whenever the feedback signal is out of range (that is, less than 5% of the potentiometer value or more than 95% of the potentiometer value), or when any of the potentiometer connections are broken. Normal operation resumes when the potentiometer is reconnected or back in range.Loss of Command - If the command signal is disconnected, the fault indication will remain on until the signal is reconnected. See LOSS OF COMMAND for details.Command Out of Range - If the command signal goes out of range, the fault indication will remain on until the signal is back in range. See LOSS OF COMMAND for detailsTROUBLESHOOTINGA-T Controls product, when properly selected, is designed to perform its intended function safely during its useful life. However, the purchaser or user of A-T Controls products should be aware that A-T Controls products might be used in numerous applications under a wide variety of industrial service conditions. Although A-T Controls can provide general guidelines, it cannot provide specific data and warnings for all possible applications. The purchaser / user must therefore assume the ultimate responsibility for the proper sizing and selection, installation, operation, and maintenance of A-T Controls products. The user should read and understand the installation operation maintenance (IOM) instructions included with the product and train its employees and contractors in the safe use of A-T Controls products in connection with the specific application.While the information and specifications contained in this literature are believed to be accurate, they are supplied for informative purposes only. Because A-T Controls is continually improving and upgrading its product design, the specifications, dimensions and information contained in this literature are subject to change without notice. Should any question arise concerning these specifications, the purchaser/user should contact A-T Controls.For product specifications go to /A-T Controls, Inc. • 9955 International Boulevard, Cincinnati, OH 45246 • Phone: (513) 530-5175 • Fax: (513) 247-5462 • 。

Range 600mV 0.1mV 0.001V 0.01V 0.1V 1V6V 60V 600V 1000VResolution Accuracy ±(0.5%+4)±(0.5%+2)±(0.7%+10)Range 600Ω0.1Ω0.001k Ω0.01k Ω0.1k Ω0.001MΩ0.01M Ω6k Ω60k Ω600k Ω6M Ω60M ΩResolution Accuracy ±(0.8%+5)±(0.8%+3)±(1.0%+25)Operating ManualI. General IntroductionThis brand new UT890C+/D Operating Manual is a handheld 3-5/6 digit True RMS Digital Multi-meter featuring stable performance and high reliability. Its whole circuit design utilizes a large scale integrated circuit that uses ∑△ADC converter as its core and is further equipped with full function overload protection, making it an ideal tool for users to measure the followings: DC and AC voltage, electric current, resistance, capacitance, frequency, temperature (UT890D/C+), diode, triode and continuity test.Safety Rules and Instructions● This unit is designed and produced in strict accordance with GB4793, Safety Requirements for Electronic Measuring Instrument and Safety Standards coded as IEC61010-1 and IEC1010-2-032. It complies with safe standards, such as double insulation, over voltage (CAT II 1000V, CAT III 600V) and class of pollution II. Please follow the instructions contained in this manual, otherwise the protection provided by this unit may be impaired.● You should not use this unit unless its back cover is properly secured in place, otherwise you are exposed to shock hazard. ● The range switch should be switched to a correct range.● Check the insulation layer of the test leads to ensure no damaged or broken cable.● The red and black test leads should be well inserted into the jacks that are in compliance with the measurement requirements to ensure good contact.● The input signal should not exceed the specified limit value to avoid shock or unit damage.● It is prohibited to change range when measuring voltage or electric current so as to avoid unit damage.● Damaged fuse must only be replaced with fuse with identical specification.● To avoid electric shock, the potential difference measured between “COM” and earth “ ” should be no more than 1000V. ● To avoid electric shock, test with great caution in case the voltage to be measured maybe higher than DV 60V or AC 30Vrms. ● Battery should be replaced in time so as to ensure measurement accuracy when the LCD displays “ ”.● Power should be turned off immediately upon the test is completed and battery should be taken out if it may not be used for a long period of time.● Do not use the unit under an environment with high temperature and high humidity, especially not store it in a wet place as the dampened unit may perform badly.● Please do not change the circuit of the unit arbitrarily so as to avoid unit damage or safety hazard.● Maintenance: Please use wet cloth and mild detergent rather than abrasive material or solvent for the cleaning of its exterior housing.III. Characteristics● More than 30 functional ranges are available.● LCD display, visible area 63×29mm.● Over range display “OL”.● Maximum displayed value 5999.● Overload protection for all ranges.● Auto power off.● Temperature scope:Working temperature: 0℃~40℃（32℉~104℉） Storage temperature: -10℃~50℃（14℉~122℉）● Low battery indicator: The symbol “ ” will be displayed at top left of the LCD.● It has functions, including data hold, measurement of maximum/ minimum value, relative measurement, backlight, etc.II. Symbol DescriptionIV. Technical IndexesAccuracy: ±（α% reading plus figure）, 1 year warranty period Environment Temperature: 23℃±5℃ Relative humidity:＜75%1. DC VoltageInput impedance: 1GΩfor the range of 600mV while 10MΩ for all2. AC VoltageRange 6V 0.001V 0.01V 0.1V 1V60V 600V 750VResolution Accuracy ±(0.8%+3)±(1.0%+10)Input impedance: 10MΩfor all the ranges.Frequency scope: 40Hz – 1KHz (Only applicable to sine wave and triangular wave, but only being referable for other waves whose frequencies are equal or higher than 200Hz.)Guaranteed Accuracy: within 5~100% of its range and allow less t han 5 figures of remaining reading in case of short circuit.Overload Protection: 750Vrms or at a peak value of 1000Vp-p.Display: True RMS 3. DC CurrentRange 60μA 0.01μA 0.001m A 0.01mA 0.1m A 0.01A6mA 60mA 600mA 20AResolution Accuracy ±(0.8%+8)±(1.2%+5)±(2.0%+5)Maximum input current: 20A (measuring electric current between 5A and 20A, testing time ≤10 seconds, Interval≥15 mins). Measuring voltage drop: 600mV when at its full range.4. AC CurrentRange 6mA 0.001m A 0.01m A 0.1mA 0.01A60mA 600mA 20AResolution Accuracy ±(1.0%+12)±(2.0%+3)±(3.0%+5)Frequency scope: 40Hz – 1KHz (Only applicable to sine wave and triangular wave, but only being referable for other waves whose frequencies are equal or higher than 200Hz.)Guaranteed Accuracy: within 5~100% of its range and allow less Maximum input current: 20A (measuring electric current between 5A and 20A, testing time ≤10 seconds, Interval≥15 mins) Measuring voltage drop: 600mV when at its full range Display: True RMS 5. ResistanceRange of 600Ω: measured value=displayed value - value shown when Overload protection: 600Vrms. 6. CapacitanceRange 9.999n F 0.001nF0.01nF～ 0.1μF 1μF 10μF99.99nF～ 999.9μF 9.999mF 99.99mFResolution Accuracy±(5.0%+35)±(2.5%+20)±(5.0%+10)10mF≤C≤20mF:±(10.0%+5)>20mF:reading is for reference onlyRange: Auto (Reading for distributed capacitance of test leads may be shown when the unit is in open circuit. It is recommended to use7. FrequencyRange9.999Hz ～10.00MHz0.001Hz～0.01MHzResolutionAccuracy ±(0.1%+5)Range: Auto Input frequency:≤100KHz: 100mVrms≤Input frequency≤30Vrms ;＞100kHz~1MHz: 200mVrms≤Input frequency≤30Vrms; ＞1MHz: 600mVrms≤Input frequency≤30Vrms; Overload protection: 600Vrms .8.Diode & Buzzer Continuity TestRange DescriptionDisplay forward voltage of the diode under test (approximate value) and the range scope is 0～3V.If it is equal or less than 10Ω, the buzzer beeps, indicating circuit is closed; if it is equal or more than 100Ω，the buzzer remain silence, indicating open circuit with a voltage of approximately 1V. Overload protection: 600Vrms .9. hFE Test for Transistors Range DescriptionhFETest ConditionIt can be used to test hFE specificiations for Transistors of NPN or PNP type. Display range: 0-1000βBase current is about 10μA, Vce is about1.2V 10. Temperature Test (Only for UT890C+)Accuracy ±3±5±(1.0%+3)±(1.5%+5)±(2.5%+5)±(2.0%+3)Function RangeResolution Temperature ℃Temperature ℃-40～0℃1℃>0～100℃>100～1000℃－40～32F 1F>32～212F >212～1832FV. How to Use it:Instructions before operating(1). Once the unit is powered up, please check the 9V batterycontained in this unit, and if the battery voltage is insufficient, there will be asymbol “ ” being displayed on the screen, then the battery should bereplaced to ensure measurement accuracy.the jacks for test leads warns that for the prevention of internal circuit from being damaged, the input voltage or current should not exceed the rated value.(3). Before measuring, the range switch should be switched into the range needed.123456 (see Fig. 1)①② LCD③ Combination keys: MAX MIN/④ Range switch⑤ Jack for transistor testing ⑥ Input Jack1. DC Voltage Measurement(1). Insert the black test lead into “COM”, while insert the red test lead into “V”.the test leads in parallel with the power or load under test, the polarity shown by the unit is the polarity of the terminal connected by the red test lead.1) If the voltage being measured remains unknown, turn the range switch into the maximum range first and then gradually adjusting it downward.2) If “OL” is shown on the LCD, it indicates that it has exceeded the range, so the range should be switched into a higher one.higher than 1000V should be input into the unit, as though it is possible to display a higher voltage, but this may incur a risk of damaging internal wiring!4) In case the input impedance is around 10MΩ, it may result in measurement error if such load is connected into a circuit with high impedance. Under most circumstances, if the circuit impedance is less than 10kΩ, then the error is ignored (0.1% or even lower).5) Especially be cautious to avoid shock when measuring high voltage. 2. AC Voltage Measurement(1) Insert the black test lead into “COM”, while insert the red test lead into “V”.P/N: 110401105881X REV.0 DATE:2016/06/08(2) Switch the range switch into the range “ ”. Then connect thetest leads in parallel with the power or load under test.1) Refer to the No. 1, 2, 4 and 5 of notes for DC voltage measurement.higher than 750V should be input into the unit, as though it is possibleto display a higher voltage, but this may incur a risk of damaginginternal wiring!1) If the current being measured remains unknown, turn the rangeswitch into the maximum range first and then gradually adjusting itdownward.2) If “OL” is shown on the LCD, it indicates that it has exceeded therange, so the range should be switched into a higher one.indicates that no voltage higher than 20A should be input into theunit, otherwise F2 fuse may be blown.3. DC Current Measurement(1) Insert the black test lead into “COM” first, then when measuringcurrent equal or less than 600mA, insert the red test lead into “mAμA”,otherwise, insert the red test lead into the jack for 20A.(2) Switch the range switch into the range “ ”. Then connect thetest leads in series with the load under test, the polarity shown bythe unit is the polarity of the terminal connected by the red test lead.4. AC Current Measurement 1) Insert the black test lead into “COM” first, then when measuringcurrent equal or less than 600mA, insert the red test lead into “mAμA”,otherwise, insert the red test lead into the jack for 20A.2) Switch the range switch into the range “ ”. Then connect thetest leads in series with the load under test.Refer to No. 1), 2) and 3) of the Notes for DC current measurement.5. Resistance (1) Input the black test lead into “COM”, while insert the red test lead into “Ω”. (2) Switch the range to range “Ω” and connect the test leads in Notes NotesNotes Notes Notes Notes 1) To ensure measurement accuracy, for the range of 600Ω：measured value=displayed value - value shown when test leads are short connected.2) If the resistance under test is higher than the range selected, the unit will display “OL”. Then a higher range should be selected. Forany resistance higher than 1MΩ or even higher, it may take a few seconds for the reading to become stable, which is normal whenmeasuring high resistance.3) The red test lead can also be used to check whether or not F1 or F2 has been blown. If the “mAμA” jack is tested to be 1MΩ and “A” jack is tested to be 0Ω, then the fuse acts good. If the unit displays “OL”, then the fuse has been blown.4) In case of no input, i.e. the case of open-circuit, the unit displays “OL”.5) When checking the impedance of an internal circuit, the circuitunder test must be cut off from all power sources and all capacitivecharge must be discharged.6. Capacitance MeasurementThe unit may display a reading even if there is no input at all, whichis the distributed capacitance of the test leads. For the measurementof a resistance less than 1μF, this value has to be deducted from thefinal measured value to ensure measurement accuracy. Therefore, the relative measurement function of this unit can be used to haveit automatically deducted for the convenience of checking reading.1) The unit will display “OL” in case the capacitance to be measuredhas been short connected or exceeds the maximum range of theunit, the displayer will show “OL”.2) For the measurement of large capacitance, it is normal for theunit to take several seconds to stabilize its reading.3) To avoid unit damage or harm to the personal safety, the capacitorto be tested must have all its residual charge discharged before thetest, which is especially the case for capacitor with high voltage. 7. Frequency Test1. Insert the red test lead into “Hz” jack, while insert the black testlead into “COM” jack.2. Switch the range switch into the range “Hz”. Then connect thetest leads in parallel with the frequency source, frequency valuecan thus be read directly from its displayer.The input frequency must comply with the requirements stipulated by the Technical Indexes.8. Test of Diode Insert the black test lead into “COM” jack, while insert the red test lead into “V” jack (the polarity of red test lead is “+”). Switch the rangeswitch into the range “ ”. Then connect the test lead with the diode under test, the reading is the forward voltage drop of the diode. If the diode under test is in open circuit or its polarity is reverse connected, the unit will display “OL”. For silicon p–n junction, approximately 500~800mV is generally considered normal.1) When measuring a connected diode, the circuit under test mustbe first cut off from all power sources and all capacitors must haveall their residual charge discharged.2) Only a diode with approximately 0~3V voltage can be measured.9. Buzzer Continuity Test Insert the black test lead into “COM”, while insert the red test lead into “V”. Switch the range switch into the range “ ” and then connect the test leads into the circuit under test. If both ends of the circuit has a resistance higher than 100Ω，it is considered that the electric circuit is disconnected and the buzzer remains silence. If the resistance between both ends is found to be equal or less than 10Ω, it is then considered that the electric circuit is well connected and the buzzer When measuring an energized circuit, the circuit under test must first be cut off from all power sources and all capacitors must have all their residual charge discharged. 10. hFE Test for Transistors (1) Switch the range switch to the range “hFE”.(2) Once the transistor has been confirmed whether to be a NPN or PNP type, insert its base, emitter and collector separately into corresponding jacks on the panel.(3) Approximate hFE value will be displayed on the displayer. Test condition: 1b≈10μA, Vce≈1.2V 。

P-64RTD Digital ControllersThe OMEGA ®4200A Series is anideal controller for RTD applications. This quality-built linearized instrument is available in both 1.0° and 0.1° resolution models. Higher accuracies, accuracies 5 to 10 times greater than the typical 1% meter indicating controller, are achieved through a unique linearizing technique.PR-10-2-100-1/4-12-E general-purpose RTD probe sold separately. 2nd Setpoint: Relay (On/Off Only): SPDT, rated 3 A at 120 Vac Adjustments Proportional Band (Gain): 0 to 3% of span, or on/off; selectable Manual Reset (Offset): Adjustable Cycle Time: Automatically adjusts with load requirement to give least wear with minimum ripple (10 s minimum)Display and Indications Temperature: Filtered LED, 3 or 31⁄2 digits, 2 readings per second update; readability is 1.0° or 0.1° (°F or °C), depending on model Setpoint: By spring loaded switch, first or second setpoint is displayed in place of temperature; setpoint adjusted by 25 turn potentiometer; 1.0° or 0.1° setability Outputs: LED indication for both first and second setpoints; LED are “on” when output drive signal present; “on/off” indication on relay and triac model; proportional intensity for option “F”Temperature Overrange: Red LED indication Setpoint Resolution: 1.0° or 0.1° (°F or °C), depending on model Repeatability: ±0.1% to ±0.2% of span Adjustment: By 25 turn potentiometer; see “setpoint” under “display and indication” section.Power: 120/240 Vac (10%, -15%, 50/60 Hz); power consumption less than 5 W Environmental and Physical Operating Temperature: -1 to 54°C (30 to 130°F)Weight: 1 kg (2 lb)1⁄4 DIN Case: Metal; plug-in with screw terminal on rear; adjustable brackets for panel mounting; panel cutout is 92 x 92 mm (3.622 x 3.622")Specifications*RTD Input Type: 100 Ω platinum;alpha = 0.00385 (DIN curve)Configuration: 3 wiresExternal Lead Wire Resistance Effect: 0.1% span up to 10 Ω per lead wire legSensor Break Protection: Built-in, upscale on open sensorCalibration Accuracy: 1.0° Resolution Model:±0.1% of span ±1 digit0.1° Resolution Model:±0.2% of span ±1 digit Stability: 0.1% for 30 to 130°F,0.1%, 10% to 15% line voltage Common Mode Rejection: Maximumerror ±1°C with 240 V, 60 Hz applied as common mode signal between sensor input and chassis groundSeries Mode Rejection: Maximumerror ±1°C with series mode signal of 100 mV peak-to-peak @ 60 HzControl Output 1st Setpoint(Adjustable Time Proportional): Relay (Standard Model):SPDT relay 7 A resistive @ 120 Vac, 5 Aresistive at 240 VacOption “T” (Triac):Solid stateplug-in triac rated 1 A holding and 10 A in-rushOption “F” (Current Proportional): 4 to 20 mAdc into 1000 Ω maximumOption “DC” (DC Pulse): 20 VdcOrdering Examples: 4202APF1, RTD digital controller.OCW-3, OMEGACARE SMextends standard 2-year warranty to a total of 5 years.U H igh-Accuracyto 0.1% of Span U S ingle and DualSetpoint Models U 1.0° and 0.1° ModelsU A djustable ProportionBand U B right LED DisplayOMEGACARE SM extended warranty program is available for models shown on this page. Ask your sales representative for full details when placing an order. OMEGACARE SM covers parts, labor and equivalent loaners.* Specifications and configurations subject to change as advances in technology allow. 4201APF1.。

FUNCTIONAL DESCRIPTION.The TD-3 is a CTCSS Decoder and Encoder designed especially for use with Hamtronics Receiver modules in repeater use, but allowing also for general use in other radios. It is tun-able to cover the entire range of tone frequencies from 63 to 250 Hz.The unit normally is used to inhibit a repeater transmitter from responding to received signals which do not have the appropriate subaudible tone to gain access. This is done by inhibiting the COS signal from the receiver squelch circuit which is required to make the transmitter respond. It may also be used in non-repeater receiver systems where muting of the receiver audio is required so that only stations with the proper tone are heard.While the unit normally is used only for receiver control by decoding tones on the received signal, circuitry is also included to generate that tone to be applied to the Exciter module in a repeater or transceiver so that the subaudible tone is also transmitted. THEORY OF OPERATION.Refer to the schematic diagram. The heart of the unit is the 567 phase-lock loop decoder chip, U2. The fre-quency of the loop detector is set by R6/R7 and C9-C12. Audio input for the chip is derived from the discrimi-nator of the receiver and processed through active low-pass filter Q1 to reduce the level of audio in the normal voice range and enhance the relatively low level of the subaudible tone. Since the response bandwidth of the phase-lock loop in U2 is proportional to the incoming audio level, R4 is ad-justed to provide adequate sensitivity without overdriving U2, thereby opti-mizing the bandwidth of tones which will activate the unit.Bias for Q1 normally is provided by the +4V riding on the discriminator output of the detector ic in Hamtronics receivers. If another type of receiver is used, it is necessary to supply bias for this stage as described under in-stallation procedures.U2 pin 8 normally rests at a logic high with no tone signal present. The bias current through R5 turns on Q2,which provides a ground to the outputat E2. When the proper tone is de-tected, pin 8 goes low, and Q2 isturned off, removing the ground fromE2.The ground at E2 normally is usedto shunt the COS signal from the re-ceiver to ground, thereby preventingthe COS signal from activating theCOR board in the repeater. This dis-ables the transmitter unless the propertone is received. Another way to usethe TD-3 in a transceiver is to mutethe audio from a receiver unless thetone is present. This is done by usingthe ground at E2 to short the audiopath before the speaker amplifier inthe receiver.Q3 provides a tone signal for useby a transmitter, when required. Someof the square-wave audio tone signalfrom the phase-lock oscillator in U2 islow-pass filtered by R8/C13 andR9/C14 to provide a quasi-sinewavetone signal. This is amplified by Q3and applied through level control R11to the mic. input of the exciter. Theseries resistance of R13 prevents t heamplifier from loading down the nor-mal audio applied to the mic. input ofthe exciter.ASSEMBLY.Construction is fairly simple. R e-fer to the parts list and component lo-cation diagram, and solder all parts inplace, using short leads. Followingare some special points to consider.a. Install the ic socket with thenotch facing to the left as shown.Then, plug in the ic, being careful notto let pins bend over instead of goingin the socket.b. Resistors mounted verticallyare shown with the body of the resistordesignated by a circle.c. For the most common fre-quency range, R7 is a combination ofa 10K resistor in series with a 2.2K re-sistor. Install one in each hole, andjoin them at the top. Twist the topleads together, solder, and clip off theexcess. For the other frequencyranges, a single resistor (not supplied)can be substituted. See table 2 forvalues.d. Install R8 with a 1/4 inch highloop formed in the right-hand lead toact as a test point.e. Observe polarity on elec-trolytic capacitors, diodes, transistors,and ic's.f. Cut hookup wires to length,strip each end 1/4 inch, and then sol-der one end to terminal pads as fol-lows. Wire lengths are as required toconveniently mount the TD-3 behind aHamtronics receiver module. Notethat no wire is prepared for E5, thetransmit af output, since this functionnormally is not used. If you do use it,attach a hookup wire to it as requiredfor your installation.TABLE 1. HOOKUP WIRES.COLOR LENGTH P AD FUNCTIONORN9"E1DISC AUDIOBLU8½"E2RCVR COSBRN6¾"E3CTCSS DISABLERED8¾"E4B+ INPUTg. Check over construction to besure all parts are installed in the properholes with the proper polarity. Checkall solder joints for bad joints, soldersplashes, etc.SELECTING FREQUENCYRANGE.The value of R7 sets the tuningrange of TONE FREQ pot R6. Thevalue of the resistors used for R7 sup-plied with the unit (10K in series with2.2K) provides a tuning range whichcovers the 100 Hz tone which is usedmost often. If you are using anothertone frequency, consult the chart b e-low, and install a resistor (or two r e-sistors in series by placing one in eachhole and tack-soldering the two leadsat the top). The information is givenas a guide. If you don't have the ex-act value(s) required, use a combina-tion of resistors which will come close,and tune the unit before mounting, sothe resistors can easily be changed.TABLE 2. RESISTOR SELECTION.TONE RANGE RES R763-72 Hz22K72-80 Hz18K80-95 Hz15K95-125 Hz10K + 2.2K125-150 Hz10K150-250 Hz 6.8KMOUNTING.The usual location for the TD-3HAMTRONICS® TD-3 SUBAUDIBLE TONE DECODER MODULEmodule in a Hamtronics REP-200 R e-peater is on the rear panel of the e n-closure near the receive coax connector. This is convenient for con-nections to the feedthrough capacitors on the partition, and it allows easy ac-cess to the pots for adjustment. The module is designed to be mounted with the pots at the top, just below the up-per edge of the box. To locate the mounting holes, draw a line one inch below the top of the box. Then, mark the two mounting holes 1-7/8 inches apart on the line, with the first hole about 1 inch from the side partition. Attach the module with 4-40 screws and standoffs or spacers as desired. HOW TO MAKE CONNECTIONS.Connections are made with the hookup wires previously soldered to the terminal pads on the module. Be sure to read the discussions below if you have not installed a TD-3 before.B+ for the unit is connected to the red wire on E4. The negative supply normally is connected through the mounting hardware to the chassis. Since an 8 volt regulator is used in the TD-3, B+ can be anything from 10 to 15Vdc.The most convenient place to pick up B+ and COS lines is at the feed-through capacitors on the partition. The discriminator connection must be made at the discriminator terminal on the receiver, since this line is not available at any of the feedthrough ca-pacitors. If you wish to use touch-tone control to disable the tone de-coder, you will need to add another ft capacitor to the receiver partition and a wire from the other side of the ft cap to the auxiliary control output of a touch-tone controller.TABLE 3. NORMAL HAMTRONICSREPEATER CONNECTIONS.TD-3 E1(orn)to rcvr disc termTD-3 E2(blu)to rcvr COS termTD-3 E4(red)to rcvr B+ termTD-3 E3(brn)to control board auxfunction via new ft cap. AUDIO INPUT.Audio from the receiver normally should be picked up from the dis-criminator for connection to E1. Some later model receivers have a terminal pin on the receiver for the discrimina-tor audio. On earlier models which donot have a dedicated terminal, the dis-criminator audio is accessible at theresistor/capacitor junction of the de-emphasis network as follows.In earlier model R144 Receivers,connect to the right hand lead of R23,at the junction of C38. In the originalR451 Receiver, connect to the righthand lead of R29, at the junction ofC45. In the R76 Receiver, connect tothe junction of R20 and C34.Input transistor Q1 normally getsits bias from the discriminator inHamtronics receivers; so there is nobias resistor in the Q1 base circuit. Ifyou are operating from a receiver otherthan ours, it is necessary to provide a680K bias resistor from E1 to the 8Vdc supply line in the TD-3 and toconnect a blocking capacitor of 0.1 uFor larger in series with the audio inputso the external circuit is does not pro-vide a dc path.OUTPUT CIRCUIT.Output terminal E2 is connected tothe receiver circuit being switched.Normally, the unit is used to inhibitthe repeater by grounding the COSsignal from the receiver to the CORboard in the repeater. The easiestplace to connect is at the COS terminalon the right side of the receiver.OPTION FOR RECEIVERAUDIO MUTING.If the unit is used in a transceiversystem to mute the audio instead of in-hibiting the transmitter, then E2 can beconnected to short the audio to groundsomewhere in the path from the dis-criminator to the output stage. Theremust be a fairly large series resistor(larger than 10K) in the audio path be-fore the connection from E2. Be care-ful not to connect the shorting outputof E2 in such a way that it shorts thesource of tone signal to the TD-3. Insuch installations, the tone should betaken close to the discriminator, andthe shorting connection should be a p-plied later in the signal path after alarge resistance. It may be necessaryto add this resistor to the audio path.OPTION TO CONTROLTD-3 ON/OFF WITHTOUCH-TONES.If a our COR-5 Computerized R e-peater Controller or the TD-2 (orsimilar) DTMF Decoder/ControllerModule is used to turn the subaudibletone feature on and off remotely, or ifa front panel switch is required to dis-able the subaudible tone function,merely connect it to ground E3 on theTD-3 when you want to disable thetone squelch function. When a groundis applied to E3, output transistor Q2is inhibited from generating a ground.This option requires an extra feed-through capacitor to be installed on therepeater's receiver enclosure. If theTD-2 DTMF module is used, t h e re-peater will default with the subaudibletone function enabled.OPTION TO TRANSMITENCODED TONE.In most repeaters, it is unnecessaryto retransmit the subaudible tone; it isonly necessary to inhibit the repeater ifa station is heard without the propertone. If you wish to have your re-peater retransmit the tone, do the fol-lowing.a. Add an extra feedthrough ca-pacitor on the receiver enclosure b e-hind the others, and add an extrafeedthrough capacitor on the exciterenclosure about in line with the devia-tion pot on the exciter.b. Connect a hookup wire from E5on the TD-3 to the added feedthroughcapacitor on the inside of the receivercompartment. Continue with a wirefrom the ft cap on the outside of thereceiver compartment over to the ftcap at the outside of the exciter com-partment.c.The connection to the exciterdepends on which exciter you have.For the TA51 (vhf) Exciter, run ashort hookup wire from the ft cap onthe inside of the compartment over tothe loop at the top of R22. This i n-jects the audio directly into the lowpass filter at the input of the modula-tor. For the TA451 (uhf) Exciter,connect a 47K resistor from the ft capon the inside of the compartment overto the lead of C11 closest to deviationpot R15. This also injects the toneinto the modulator, but the 47K resis-tor prevents loading of the circuit inthe uhf exciter.d.If you are using your transmit-ter for an application other than a r e-peater, you probably do not need thefeedthrough capacitors. Just run a short length of wire directly to the ex-citer at the connection point given in step c.e.If you need to connect the tone to another type of transmitter, use a similar approach. It is important to inject the tone into the modulator of the transmitter in a way which by-passes the speech processing circuits for the microphone, but at the same time does not load down the audio coming from those circuits. Normally, there will be a low-pass filter which allows the audio to be injected into the modulator while keeping the oscillator rf signal from getting out into the audio circuits.Once the mic gain control in the exciter is adjusted for proper deviation of the repeater, XMIT LEVEL control R11 on the TD-3 is adjusted for the desired deviation of the subaudible tone. The TD-3 has a resistor (R13) in series with its output to avoid loading down the exciter audio circuits. If XMIT LEVEL control R11 provides too high a level, even with it adjusted to a low setting, additional resistance can be added in series with output ter-minal E5 or R13 can be made larger.Normally, the level of the tone should be set for about 300 Hz de-viation. That is sufficient for the de-coder to detect. Sometimes people want to use much higher levels on tones, and not only is this unnecessary but it causes the tone to be heard as a buzz on the voice signal, and if set high enough, may even have a detri-mental effect on a touch-tone com-mand system.ALIGNMENT.The following assumes all of the installation procedures have been done prior to alignment.The tone frequency can be set in either of two ways. If a frequency counter is available, connect it through a resistor to Test Point 1, which is a loop formed in the right side of R8. A resistor of 10K to 100K normally must be connected in the pick up line at the TD-3 to minimize loading and noise pickup to prevent erratic readings. For an accurate adjustment, it is nec-essary to remove any possible audio input to the decoder ic by turning R4 fully ccw. With the lowest frequency range, adjust FREQ pot R6 for the de-sired tone frequency. If R6 cannot beadjusted to the desired frequency, itmay be necessary to change the valueof R7 as explained in the section afterASSEMBLY on page 1.The alternate method of adjustingfrequency is to simply apply a re-ceived signal with the proper subaudi-ble tone present and adjust FREQ potR6 to the center of the adjustmentrange in which the ic responds to thetone. Response is indicated by a dcvoltmeter connected to E3, which hasabout 0.6 Vdc with no tone detectedand ground with proper tone detection.To locate the exact center of the set-tings which allow response, the sensi-tivity pot may be reduced to the pointwhere the TD-3 responds only over avery narrow range of settings.Another way to check for responseof the TD-3 is to monitor the COSvoltage at the feedthrough cap on thereceiver enclosure.Since the response bandwidth(range of tone frequencies which willbe detected) is proportional to thelevel of tone applied to U2, it is desir-able to adjust the level for optimumtone acceptance. If R4 is set too sen-sitive (cw), then the bandwidth will befairly wide, up to three times as wideas optimum. If R4 is set too insensi-tive (ccw), then some stations may bea little too weak or off the tone fre-quency a little too far to access the re-peater.Normally, a system should be runwith about 300 Hz tone deviation onthe transmitters (mobiles using the re-peater). Obtain a weak signal with atone a little below the low end of ex-pected range of levels to be encoun-tered in the system. For example, atour factory, we usually apply an rfsignal of about 0.15 uV with about a200 Hz tone deviation. AdjustSENSITIVITY pot R4 cw from no tonelevel to a level just high enough so theTD-3 responds. Then, any signal younormally expect to encounter will beable to access the repeater.We normally use a service monitorwith a subaudible tone synthesizer anda deviation monitor. However, youdon't need to have a fancy signal gen-erator. Just make sure the signal usedfor testing has its tone encoder on theproper frequency and at a relativelylow level of deviation. You don'twant to adjust the TD-3 to match atone which is off frequency. If youuse a strong rf signal or a normal tonelevel rather than a weak tone as wesuggested, then adjust R4 just a littlefurther cw than the point at which thedecoder first responds. Then, weaksignals will be able to access the r e-peater too.The only other adjustment is thetransmit audio level (R11) which isdiscussed on page 2 under the sectionon Option to Transmit Encoded Tone.If you do not use this option, R11 canbe left in any position.TROUBLESHOOTING.The circuit is relatively simple.With the theory of operation presentedon page 1 and the following list of dcand signal levels, troubleshootingshould be straight forward. An oscil-loscope is usually essential in trouble-shooting, although it may be possibleto get by with just a voltmeter.Unless otherwise specified, the fol-lowing test data is taken with 13.6Vdcat the B+ input (8Vdc out of the volt-age regulator) and a 100 Hz tone a p-plied from one of our receivers with300 Hz tone deviation. That results inabout 200 mV p-p tone level at inputterminal E1. Current drain of the unitis about 20 mA.TABLE 4. TYPICAL TEST VOLTAGES.Location Typical IndicationE14Vdc with 200mV p-p toneQ1-base4Vdc with 200mV p-p toneQ1-coll8 VdcQ1-emit 3.3Vdc & 200mV p-p toneU2-1 5 VdcU2-2 5.8VdcU2-32Vdc (tone 75mV p-p min to beable to decode)U2-48VdcU2-57V p-p square wave centered at3.7VdcU2-62V p-p triangle wave centered at4 VdcU2-8 &0Vdc with tone received &Q2-base 1.2 Vdc with tone absentQ3-base1V p-p rounded triangle wavecentered at 1.3VdcQ3-emit Same waveform at 0.6VdcQ3-coll3V p-p rounded triangle wavecentered at 5.8VdcPARTS LIST.Ref # Value (marking)C1 2.2 uf electrolyticC247 uF electrolyticC3-C4.033 uF mylarC5.01 uF monolithic (103)C6 2.2 uF electrolyticC710 uF electrolyticC847 uF electrolyticC9-C140.15 uF polyesterC15 2.2 uF electrolyticCR11N4148Q1-Q32N3904 or 2N4124R1-R347KR420K or 22K pot (203, 223,or 22K)R527KR65K, 20-turn potR710K in series with 2.2K(frequency dependent,see text)R8-R1027KR1120K potR12 3.3KR1310KU178L08 8Vdc regulatorU2NE567P PLL Tone De-tector。

Haawking DSC2803X数字信号控制器数据手册编号：北京中科昊芯科技有限公司2022年03月V1.3历史版本记录目录1.器件概述 (5)1.1产品特性 (5)1.2应用 (6)2.DSC28034简介 (7)2.1器件特性 (7)2.2产品编码 (8)2.3引脚分配 (9)2.4信号说明 (10)3.功能概述 (19)3.1系统架构 (19)3.2内存映射 (19)3.3简要说明 (21)3.3.1HXS320F2803x DSC (21)3.3.2内存总线 (21)3.3.3外设总线 (21)3.3.4实时JTAG和分析 (22)3.3.5闪存 (22)3.3.6M0、M1、L0、L1SARAM (22)3.3.7引导ROM (23)3.3.8.1JTAG引导模式 (23)3.3.8.2GetMode获取模式 (24)3.3.8.3引导加载器使用的外设引脚 (24)3.3.8安全性 (24)3.3.9外设中断扩展（PIE）模块 (25)3.3.10外部中断（XINT1-XINT3） (26)3.3.11内部振荡器、外部振荡器和PLL (26)3.3.12看门狗 (26)3.3.13外设时钟 (26)3.3.14低功耗模式 (27)3.3.15通用输入/输出（GPIO）复用器 (27)3.3.1632位CPU定时器（0,1,2） (28)3.3.18控制外设 (28)3.3.19串行端口外设 (29)3.4寄存器映射 (29)3.5器件仿真寄存器 (30)3.7LDO/VREG/BOR/POR (34)3.7.1VREG (34)3.7.1.1使用片上VREG (35)3.7.1.2不使用片上VREG (35)3.7.2片上上电复位（POR）和掉电复位（BOR）电路 (35)3.8系统控制 (36)3.8.1内部零引脚振荡器 (39)3.8.2晶体振荡器选项 (40)3.8.3基于PLL的时钟模块 (41)3.9低功耗模块 (41)4.外设 (43)4.1模拟器件 (43)4.1.1特性 (43)4.1.2ADC MUX多路复选 (47)4.1.3比较器模块 (47)4.2同步串行通信接口（SPI）模块 (48)4.3异步串行通信接口（SCI）模块 (51)4.4本地互联网络（Lin）模块 (53)4.5增强型控制器局域网络（eCAN）模块 (55)4.6内部集成电路接口（I2C）模块 (58)4.7增强型PWM模块（ePWM1/2/3/4/5/6/7） (61)4.8高分辨率PWM模块（HRPWM） (63)4.9增强型脉冲捕获模块（eCAP） (64)4.10高分辨率脉冲捕获模块（HRCAP） (66)4.11增强型正交编码器模块（eQEP） (67)4.12JTAG端口 (72)4.13GPIO控制寄存器 (74)4.14直接存储访问存储单元（DMA） (78)5.开发支持 (83)5.1集成开发环境Haawking IDE (83)5.2仿真器 (84)5.2.1简介 (84)5.2.2概览 (84)5.2.2.1特性 (85)5.3串口下载器 (86)5.4JTag下载工具 (87)6.1绝对最大额定值 (88)6.2推荐工作条件 (88)6.3ESD额定值 (89)6.4电气特性 (89)6.5功耗 (91)6.6散热设计考虑 (92)7.热特性/机械数据 (93)7.1LQFP80 (93)7.2TQFP64 (94)8.参考文献 (95)1.器件概述1.1产品特性高能效32位处理器(H28x内核)✓主频120MHz（周期8.33ns）✓哈佛(Harvard)总线架构✓硬件乘法/除法单元✓4/6通道高速DMA✓快速中断响应和处理✓统一存储器编程模型✓高效代码（使用C/C++和汇编语言）增强型控制外设✓增强型脉宽调制器(ePWM)✓高分辨率PWM(HRPWM)✓增强型捕获(eCAP)✓高分辨率输入捕获(HRCAP)✓增强型正交编码器脉冲（eQEP）✓模数转换器(ADC)✓片载温度传感器✓比较器芯片及系统开销✓3.3V单电源供电✓无上电顺序要求✓集成上电和掉电复位✓代码安全模块✓无模拟支持引脚时钟和系统控制✓两个内部12MHz零引脚振荡器✓片载振荡器/外部时钟输入✓看门狗定时器模组功能✓支持锁相环路(PLL)倍频系数动态调整多达45个具有输入滤波功能、可单独编程的多路复用GPIO✓可支持所有外设中断的外设中断扩展(PIE)模块✓三个32位CPU定时器✓每个ePWM模块中包含独立的32位定时器✓片载存储器✓闪存，SRAM，OTP，引导ROM可用128位安全密钥/锁✓保护安全内存块✓防止固件逆向工程✓串行端口外设✓一个SCI(UART)模块✓两个SPI模块✓一个内部集成电路(I2C)总线✓一个本地互连网络(LIN)总线✓一个增强型控制器局域网络(eCAN)总线高级仿真特性✓分析和断点功能✓封装选项✓80引脚薄型四方扁平(LQFP)封装✓64引脚TQFP封装✓温度选项✓工作温度:-40°至105°1.2应用●电器●医疗、保健与健身●楼宇自动化●电机驱动器●电动汽车、混合动力电动汽车（EV/HEV）动力传动●电力传送●工厂自动化●电信基础设施●电网基础设施●2.DSC28034简介2.1器件特性表2-1DSC2803x产品特性（1）：ADC主频=30MHz时，转换速率是1.56Msps，由于可以同时采样转换两个通道，故最高速率为3.12Msps。

Rev. 0.1 2/12Copyright © 2012 by Silicon LaboratoriesAN6711. IntroductionPrecision32™ devices use one or more Port I/O Crossbar Decoders to assign internal digital signals to Port I/O pins. A crossbar decoder provides the system designer with flexibility to customize the pinout according to the needs of the application. The Port I/O Crossbar Decoder is particularly useful in low pin count devices where the number of internal digital signals outnumber the available I/O pins.The crossbars are fully supported by the Silicon Labs Precision32 SDK, including Hardware Access Layer (HAL)routines and code examples showing how to configure a crossbar for a particular peripheral. Additionally, the Precision32 AppBuilder application provides a graphical interface to easily configure pins in a crossbar.Figure 1 shows an example of how internal signals are routed to the Port Banks of SiM3U1xx devices through the use of two crossbar decoders. Port Bank 0 (PB0) and Port Bank 1 (PB1) are connected to crossbar 0, and Port Bank 2 (PB2) and Port Bank 3 (PB3) are connected to crossbar 1.2. Relevant DocumentationPrecision32 Application Notes are listed on the following website: /32bit-mcu.⏹ AN664: Precision32™ CMSIS and HAL User’s Guide⏹ AN670: Getting Started with the Silicon Labs Precision32™ AppBuilderAN6713. Crossbar FunctionThe primary function of a crossbar decoder is to route internal digital signals to Port Bank pins. Figure2 is a block diagram of crossbar0 on SiM3U1xx devices. The inputs to the crossbar are a number of internal digital signals inside the device. The XBAR0H, XBAR0L, and PBSKIP registers in the port configuration module (PBCFG) define how the internal digital signals are mapped to the I/O pins of PB0 and PB1.AN6713.1. Crossbar Functionality on ResetAfter a device reset, all crossbars enter a disabled default reset state. Port Bank pins connected to a disabled crossbar are forced into a high impedance digital input mode. Firmware must enable the crossbar associated with a specific Port Bank pin in order to use that pin as an output. In most applications, firmware will enable all crossbars on the device to control all the available I/O pins on the device.When a crossbar is enabled with no internal signals selected to be routed to I/O pins, the crossbar provides full general purpose input/output (GPIO) access to the Port Banks associated with it. Pins with full GPIO access can be used as digital inputs, digital outputs, or may be used by various analog functions on the device. As internal signals are selected to be routed to I/O pins (or “enabled in the crossbar”), the crossbar claims pins from the associated port banks. Pins claimed by the crossbar cannot be used as GPIO and are under the full control of the crossbar and the associated peripheral.3.2. Skipping Pins in the CrossbarThe crossbars have a pin-skipping feature for pins that must be reserved GPIO or analog functions. Any Port Bank pin with its corresponding PBSKIPEN bit set to 1 cannot be claimed by the crossbar and will remain available for GPIO or analog functions. The ability to have the crossbar skip certain pins is useful when a system designer is trying to achieve a specific pinout for the device.3.3. Crossbar Priority OrderAs internal signals are enabled in a crossbar, the crossbar claims pins from the Port Banks to connect to the internal signal, starting with the least significant Port Bank pin and finishing with the most significant Port Bank pin. As an example, crossbar0 of SiM3U1xx devices would start with PB0.0, then PB0.1, and continue in this fashion until reaching PB1.15. If the crossbar encounters a pin that has its PBSKIPEN bit set to 1, it skips over the pin and claims the next available pin. Any pin not claimed by the crossbar can be used for GPIO or analog functions.The crossbar uses a priority order to assign enabled internal signals to claimed Port Bank pins. This priority order varies with the specific crossbar implementation. Figure3 shows an example priority order from crossbar0 of SiM3U1xx devices. In this example, there are four enabled peripherals that require pin assignment: SPI0, EPCA0, UART0, and UART1. From the enabled peripherals, SPI0 has the highest priority, so it will be assigned to the first three pins claimed by the crossbar. Note that in this example configuration, firmware configured the first 8 pins of PB0 (PB0.0 - PB0.7) to be skipped by the crossbar; the crossbar will assign the SPI0 pins to PB0.8, PB0.9, and PB0.10. Following the priority order, the EPCA0 pins are assigned to PB0.11, PB0.12, PB0.15, PB1.0. The PB1.2. PB0.13 and PB0.14 pins are not assigned to EPCA0 because they are configured to be skipped by the crossbar. UART0 and UART1 are assigned to the next four available pins: PB1.3, PB1.4, PB.15, and PB1.6. The remaining pins (PB1.7–PB1.15) are not claimed by the crossbar.3.4. Creating a Flexible Device PinoutThe definition of a system can sometimes change in the middle of the design cycle, necessitating a pinout change. Planning ahead for such changes in pinout can save costly PCB revisions and decrease time to market when a system definition change does occur. In the example pinout shown in Figure3, SPI0 is used in 3-wire mode. If the communication protocol was changed from 3-wire to 4-wire mode, then PB0.11 would be used for the NSS signal, causing all peripherals of lower priority order to shift by one pin. Using the crossbar’s skip functionality, the system designer can plan ahead for such a change by skipping PB0.11 when the specification calls for 3-wire SPI mode. The skipped pin can later be un-skipped if the specification later requires the use of 4-wire SPI without affecting the location of peripherals with a lower priority order. If the specification does not change, the skipped pin can be used for GPIO (e.g., to control an LED or as a debug signal). Adding a few skipped pins when determining the original device pinout can allow future functionality to be added with minimal impact on the device pinout.AN671AN6714. Configuring the Crossbar and Port I/O in FirmwareThe Precision32 AppBuilder application provides a graphical interface to easily configure pins in the crossbars.This software uses the Hardware Access Layer (HAL), a part of the Silicon Labs SDK package that enables rapid development on SiM3xxxx devices. The crossbars and Port Banks on SiM3xxxx devices are part of the PBCFG and PBSTD modules.The following steps show an example of how to initialize the crossbars and pins on SiM3U1xx devices to achieve the pinout shown in Figure 3 using the Silicon Labs HAL:1. Enable the APB clock to the I/O modules:2. Configure pins to be skipped by the crossbars and enable signals in the crossbars. A full list of signal names that may be enabled in the crossbars can be found in a file named SI32_PBCFG_A_Support.h.3. Configure the functional and output mode of each pin:4. Enable the crossbar or crossbars:Silicon Laboratories Inc.400 West Cesar Chavez Austin, TX 78701USASimplicity StudioOne-click access to MCU and wireless tools, documentation, software, source code libraries & more. Available for Windows, Mac and Linux!IoT Portfolio /IoTSW/HW/simplicityQuality/qualitySupport and CommunityDisclaimerSilicon Labs intends to provide customers with the latest, accurate, and in-depth documentation of all peripherals and modules available for system and software implementers using or intending to use the Silicon Labs products. Characterization data, available modules and peripherals, memory sizes and memory addresses refer to each specific device, and "Typical" parameters provided can and do vary in different applications. Application examples described herein are for illustrative purposes only. Silicon Labs reserves the right to make changes without further notice and limitation to product information, specifications, and descriptions herein, and does not give warranties as to the accuracy or completeness of the included information. Silicon Labs shall have no liability for the consequences of use of the information supplied herein. This document does not imply or express copyright licenses granted hereunder to design or fabricate any integrated circuits. The products are not designed or authorized to be used within any Life Support System without the specific written consent of Silicon Labs. A "Life Support System" is any product or system intended to support or sustain life and/or health, which, if it fails, can be reasonably expected to result in significant personal injury or death. Silicon Labs products are not designed or authorized for military applications. Silicon Labs products shall under no circumstances be used in weapons of mass destruction including (but not limited to) nuclear, biological or chemical weapons, or missiles capable of delivering such weapons.Trademark InformationSilicon Laboratories Inc.® , Silicon Laboratories®, Silicon Labs®, SiLabs® and the Silicon Labs logo®, Bluegiga®, Bluegiga Logo®, Clockbuilder®, CMEMS®, DSPLL®, EFM®, EFM32®, EFR, Ember®, Energy Micro, Energy Micro logo and combinations thereof, "the world’s most energy friendly microcontrollers", Ember®, EZLink®, EZRadio®, EZRadioPRO®, Gecko®, ISOmodem®, Precision32®, ProSLIC®, Simplicity Studio®, SiPHY®, Telegesis, the Telegesis Logo®, USBXpress® and others are trademarks or registered trademarks of Silicon Labs. ARM, CORTEX, Cortex-M3 and THUMB are trademarks or registered trademarks of ARM Holdings. Keil is a registered trademark of ARM Limited. All other products or brand names mentioned herein are trademarks of their respective holders.。

使用前请详细阅读本说明书目录一. 主要特点┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈3二. 技术参数┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈3三. 主要性能┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈31.镜头电压的调整┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈32.协议设置┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈43.波特率设置┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈54.地址码设置┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈5四. 系统接线示意图┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈7五. 解码器接线示意图┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈8六. 常用主机的解码器设置参数┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈9七. 解码器手动测试功能使用说明┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈10八. 常用故障分析及解决方法┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈11警告：1.本产品升级或参数有调整，恕不另行通知。

在保修期内请勿私自拆机或更换元器件！为防止起火或触电，切勿将本机倒置或置于有水或潮湿的地方！2.使用本设备前，请详细核对云台电压，出厂默认为24V。

3.使用前请详细阅读说明书，并选择正确的接线方式，以免对您的设备造成损坏。

4.进行协议波特率设置时，请断电3秒钟后再通电，以便主机进行确认。

本解码器是安防监控系统中的一种前端设备，通过操作软件（控制键盘等）对云台、摄像机镜头、电源、雨刷、灯光的控制。

一. 主要特点：●采用PIC单片机设计，本产品兼容多种协议，具有抗雷击抗干扰电路，产品采用工业级元器件，主控部分选用进口优质元器件，保证本机长时间高效运作。

●本机具备防高压、静电、雷击功能、采用多重线路保护。

●本机有多种电源可供外部设备使用（摄像机，云台等）。

如：AC220V、AC24V、DC12V。

●可选择云台电压，通过AC24V——AC220V开关选择电压以匹配云台电压。

二.技术参数：工作电压：AC220V±10%工作电流： AC100mA（不含云台工作电流）功率： 30W -50W环境温度： -30℃-70℃工作温度：≤50℃工作寿命：继电器20万次、元器件8年镜头电压： DC6V-12V（可调）镜头控制：光圈、焦距、变倍云台电压： AC24V/AC220V（可选）云台控制：上、下、左、右、自动摄像机电源：DC12V，800mA通讯方式：RS-485 半双功辅助开关： 2组（2常开触点AUX1 AUX2控制雨刷，灯光等）适用环境：室内外通用机箱材料：金属协议：兼容多种协议，多种波特率（0-64位地址设定）电压调节开关：内置12V-14V电压调节功能节点数量： 32/128/1024信号传输距离：1500米（以外部影响而定，距离过长增加中继器）三.主要性能：1.镜头电压的调整通过对电位器的调整（6V～12V），实现对摄像机镜头的光圈、焦距、变倍的控制，电压高，镜头动作加快；电压低，镜头动作放慢，出厂设定为8.5V-9V※2.四位拨码开关的设置（协议开关的设置） ON=1 OFF=0序号协议拨码开关位置波特率适用范围备注1 PELCO-DHCPELCOD-2400派尔高系列/康银主机HC-96002 PELCO-P 9600 派尔高主机德加拉主机地址从0开始3 PIH1016 (利凌) 2400 利凌矩阵4 HY 9600 德加拉、康银系列5 B01 9600 维多、明景6 RM110／S1601 9600 诚丰系列/三乐系列7 HN-C 9600 华南光电系列8 SAMSUNG 9600 三星9 银信V1200／9600 银信矩阵地址码从0开始10 SANTACHI-450/9600卡拉特KDT348矩阵48009600/4800三立矩阵卡拉特矩阵KDT304-480011 VICON( surveyor99) 4800 PICO2000系统唯康主机12 KODICOM–RXKRE-301RX9600PICASO主机KODICOM主机增加光圈控制/十进制地址码13 DH大华/／KCL 9600/19200大华、凯创、录林王嵌入式DH=9600KCL=1920014 红苹果9600 红苹果矩阵15 NEOCAM 9600 耐康姆系统16 Kalatel(kdt-312)DCW06019600卡拉特设备DCW系统DCW系统※3.八位拨码开关的1、2位设置（波特率设置）ON=1 OFF=0序号波特率拨码开关位置备注1 1200／19200 根据协议不同，自动识别这两种波特率2 24003 48004 9600※协议波特率设置时，尽量断电后进行，以便主机进行确认。

TDC解码控制器使用说明书美国托罗公司北京代表处2008年6月一、面板简介1、左右按钮，可以选择在同一行内进行选择。

2、上下按钮，可以上下调整显示并选择。

3、LCD显示面板。

4、旋转调整按钮，可以通过该钮调整设置量的大小。

5 、主页按钮可以从任何功能区域中返回到正常操作界面。

按下此按钮，所有调整将会保存。

6、手动灌溉按钮可以通过此按钮手动激活灌溉站或者程序。

7、编辑灌溉按钮用来创建或调整灌溉程序。

采用本功能可以设定程序类型，标准程序或GROWIN程序，灌溉天数，灌溉时间，结束时间，延迟时间，施肥的时间，重复次数。

浸入时间，控制站，控制站工作时间和每个程序的最大同时开启站数。

8、诊断按钮用来确认控制器和解码器及电磁阀之间的通讯状态。

9、控制站设置按钮可以用来调整控制站的各种参数。

在本功能区间内，可以设定控制站分配到指定的解码器上，解码器编号和通道，特殊控制站比例调节参数，指定时间关闭，设定控制站类型，编辑控制站的说明内容。

10、比例调节按键可以用来调整灌水指定比例。

适用于对于整个系统，某个程序，或者某个控制站。

11、开始按钮执行某个选择的程序或者手动运行12、暂停/重新开始按钮可以暂停当前运行的程序。

在暂停时按此按键可以重新运行当前程序。

13、停止按钮将会停止当前运行的程序或控制站14、系统设置按钮允许使用者调整控制器参数。

可以调整控制器激活时间，设定语言，时间，日期，日期变化，控制站延迟，最大同时启动数量，调整显示对照，设定传感器类型。

此菜单内，可以重置所有程序，控制站参数，所有关闭的操作。

二、系统自检电源供给后，系统将进行约10秒钟的不可撤销的自检程序。

界面如下。

在这个过程中如果检查到系统问题，将会提示到显示屏上。

正常自检完成后，显示如下信息：第一行：TDC硬件版本编号和版本日期第二行：检测到的站点数量，检测到的传感器数量。

第三行：上一次电力供给切断时间主页信息将在以上内容显示完成后出现，如下：主页按键：以上为有无雨量传感器的显示不同。

Digital Phosphor OscilloscopesTDS3000C Series DatasheetThe TDS3000C Series provides you with the performance you need at a price you can afford. Bandwidths range from 100 MHz to 500 MHz, with up to 5 GS/s sample rates for accurate representation of your signal.Notice to EU customersThis product is not updated to comply with the RoHS 2 Directive 2011/65/EU and will not be shipped to the EU. Customers may be able to purchase products from inventory that were placed on the EU market prior toJuly 22, 2017 until supplies are depleted. Tektronix is committed to helping you with your solution needs. Please contact your local salesrepresentative for further assistance or to determine if alternative product(s)are available. Tektronix will continue service to the end of worldwide support life.Key performance specifications100 MHz, 300 MHz, and 500 MHz bandwidth models2 or 4 analog channel modelsSample rates up to 5 GS/s real time on all channels10k record length on all channels3,600 wfms/s continuous waveform capture rate Suite of advanced triggersKey featuresFront-panel USB host port for easy storage and transfer ofmeasurement data25 automatic measurementsFFT standardMultiple language user interfaceWaveAlert ®automatic waveform anomaly detectionTekProbe ® interface supports active, differential, and current probes for automatic scaling and unitsPortable designLightweight design (only 7 lb./3.2 kg) for easy transportOptional internal battery operation provides up to three hours without line powerApplication modules for specialized analysisAdvanced analysis moduleLimit testing moduleTelecommunications mask testing module Extended video moduleApplicationsDigital design and debugVideo installation and servicePower supply designEducation and trainingTelecommunications mask testingManufacturing testGeneral bench testingDPOs provide greater level of insight into complex signalsThe TDS3000C Series offers fast waveform capture rates on a continuous basis that save you time by quickly revealing the nature of faults, so advanced triggers can be applied to isolate them.Real-time intensity grading highlights the details about the history of a signal's activity, making it easier to understand the characteristics of the waveforms you've captured. Unlike other comparable oscilloscopes, the history remains even after the acquisition has been stopped.Quickly debug and characterize signals with DRT sampling technology and sin (x)/x interpolationThe TDS3000C Series combines unique digital real-time (DRT) sampling technology with sin(x)/x interpolation to allow you to accurately characterize a wide range of signal types on all channels simultaneously. With the TDS3000C Series there is no change in sampling rate when additional channels are turned on, unlike other comparable oscilloscopes. This sampling technology makes it possible to capture high-frequency information, such as glitches and edge anomalies, that elude other oscilloscopes in its class, while sin(x)/x interpolation ensures precisereconstruction of each waveform.Look for unintentional circuit noise with the TDS3000C series’ FFT capability.Custom video triggering allows the TDS3000C Series to trigger on standards such asRS-343 (26.2 kHz scan rate).The TDS3000C Series provides breakthrough test speeds for telecommunications line card testing. The telecom QUICKMENU puts all the commonly used telecom test functions on a single menu.DatasheetEasy to setup and useWhen working under tight deadlines, you need your oscilloscope to be intuitive; you want to minimize time spent learning and relearning how to use it. The TDS3000C Series oscilloscopes help reduce your learning curve. Simple navigation and dedicated front-panel controls get you to where you want to be quickly, so that you spend less time learning andmore time on the task at hand.The TDS3000C series with the TDS3LIM module is ideal for manufacturing testapplications where fast Go/No-Go decisions are required.WaveAlert waveform anomaly detection alerts you to any waveform that deviates fromthe “normal” input such as the glitch on channel 2.Easily transfer, document, and analyze data on your PC.Simple documentation and analysisThe TDS3000C Series comes equipped with a USB host port so you can easily store and transfer measurement information to your PC.OpenChoice ®PC Communication Software allows you to simply pull screen images and waveform data into a standalone desktop application or directly into Microsoft Word and Excel.If you prefer not to use a PC for analysis, the TDS3000C Series comes standard with 25 automatic measurements, waveform add, subtract, divide,and multiply math functions, and Fast Fourier Transform (FFT). Unlike other comparable oscilloscopes, the TDS3000C Series math andmeasurement allows you to use the full acquisition record length or isolate a specific occurrence within an acquisition.Instrument controlUtilizing the built-in ethernet port, e*Scope web-based remote control allows you to a control TDS3000C series oscilloscope from anywhere,using the internet and your PC.TDS3000C Series Digital Phosphor OscilloscopesWork where you need toThe TDS3000C Series packs the power of a DPO in a compact design that is only 5.9 in. (149 mm) deep, freeing up valuable benchtop space. And when you need to move your oscilloscope to another lab, its portable 7 lb.(3.2 kg) design makes for easy transport.If your work demands even more mobility, then the optional battery packwill give you up to three hours of operation without line power.TDS3BATC provides you with up to three hours of portable battery operation.SpecificationsAll specifications are guaranteed unless noted otherwise. All specifications apply to all models unless noted otherwise.Vertical systemHardware bandwidth limitsInput coupling AC, DC, GNDInput impedance 1 MΩ in parallel with 13 pF or 50 ΩInput sensitivity range1 MΩ 1 mV/div to 10 V/div 50 Ω 1 mV/div to 1 V/div Vertical resolution 9 bits Maximum input voltage1 MΩ150 V RMS with peaks at ≤400 V 50 Ω5 V RMS with peaks at ≤30 V DatasheetDC gain accuracy ±2%Position range±5 divHorizontal systemSeconds/division rangeTime base accuracy±20 ppm over any 1 ms time intervalTrigger systemTrigger modes Auto (supports Roll Mode for 40 ms/div and slower), Normal, Single Sequence B triggerTrigger after time or events Trigger after time range 13.2 ns to 50 s Trigger after events range 1 to 9,999,999 eventsTrigger typesEdge Conventional level-driven trigger. Positive or negative slope on any channel. Coupling selections: AC, DC, Noise Reject, HF Reject, LF RejectVideo Trigger on all lines or individual lines, odd/even or all fields on NTSC, PAL, SECAMExtended video Trigger on specific lines in broadcast and non-broadcast (custom) standards and on analog HDTV formats (1080i, 1080p, 720p,480p). Requires TDS3VID application modulePulse width (or glitch)Trigger on a pulse width <, >, =, ≠ to a selectable time limit ranging from 39.6 ns to 50 sRunt Trigger on a pulse that crosses one threshold but fails to cross a second threshold before crossing the first again Rise/fall time Trigger on pulse edge rates that are either faster or slower than a set rate. Edges can be rising, falling, or either Pattern Specifies AND, OR, NAND, NOR when true or false for a specific timeState Any logic state. Triggerable on rising or falling edge of a clock. Logic triggers can be used on combinations of 2 inputs (not 4)Comm Provides isolated pulse triggering required to perform DS1/DS3 telecommunications mask testing per ANSI T1.102 standard.Requires TDS3TMT application moduleAlternateSequentially uses each active channel as a trigger sourceAcquisition systemDPOCaptures and displays complex waveforms, random events and subtle patterns in actual signal behavior. DPOs provide 3 dimensions of signal information in real time: Amplitude, time, and the distribution of amplitude over time Sample Sample data onlyAverage Waveform averaged, selectable from 2 to 512 Envelope Min-max values acquired over one or more acquisitionsPeak detectHigh-frequency and random glitch capture. Captures glitches as narrow as 1 ns (typical) using acquisition hardware at all time base settingsTDS3000C Series Digital Phosphor OscilloscopesVertical systemDatasheetAcquisition systemWaveAlert®Monitors the incoming signals on all channels and alerts the user to any waveform that deviates from the normal waveform beingacquiredSingle sequence Use the Single Sequence button to capture a single triggered acquisition sequence at a timeWaveform measurementsCursors Amplitude, timeAutomatic measurements Display any four measurements from any combination of waveforms. Or display all measurements with measurement snapshotfeature. Measurements include Period, Frequency, +Width, -Width, Rise time, Fall time, +Duty cycle, -Duty cycle, +Overshoot,High, Low, Max, Min, Peak-to-peak, Amplitude, Mean, Cycle mean, RMS, Cycle RMS, Burst width, Delay, Phase, Area 1, CycleArea 1Measurement statistics Mean, Min, Max, Standard deviation. Requires TDS3AAM application moduleThresholds User-definable thresholds for automatic measurements; settable in percent or voltageGating Isolate a specific occurrence within an acquisition to take measurements, using either the screen or cursorsWaveform mathArithmetic Add, subtract, multiply, and divide waveformsFFT Spectral magnitude. Set FFT vertical scale to Linear RMS or dBV RMS, and FFT window to Rectangular, Hamming, Hanning, orBlackman-HarrisAdvanced math Integrate, differentiate, define extensive algebraic expressions including analog waveforms, math functions, scalars, up to twouser-adjustable variables and results of parametric measurements. For example: (Intg (Ch1-Mean(Ch1)) × 1.414 × VAR1) 2Waveform processingAutoset Single-button, automatic setup of all channels for vertical, horizontal and trigger systems, with undo autosetDeskew Channel-to-channel deskew ±10 ns may be manually entered for better timing measurements and more accurate math waveformsDisplay systemDisplay type 6.5 in. (165.1 mm) liquid-crystal TFT color displayDisplay resolution640 horizontal × 480 vertical pixels (VGA)Interpolation Sin(x)/xWaveform styles Dots, vectors, variable persistence, infinite persistenceGraticules Full, grid, crosshair, and frame. NTSC, PAL, SECAM, and vectorscope (100% and 75% color bars) with optional TDS3VIDapplication moduleFormat YT, XY, and Gated XYZ (XY with Z-axis blanking available on 4-channel instruments only)1Requires TDS3AAM application module.2Requires TDS3AAM application module.Input/output portsEthernet port RJ-45 connector, supports 10Base-T LANUSB port Front-panel USB 2.0 host port. Supports USB flash driveGPIB port Full talk/listen modes, setting and measurements.(Optional with TDS3GV Communications Module)RS-232C port DB-9 male connector, full talk/listen modes; control of all modes, settings and measurementsBaud rates up to 38,400(Optional with TDS3GV Communications Module)VGA video DB-15 female connector, monitor output for direct display on large VGA-equipped monitors(Optional with TDS3GV communications module)External trigger input BNC connector, input impedance >1 MΩ in parallel with 17 pF; max input voltage is 150 V RMSPower sourceAC line powerSource voltage100 V RMS to 240 V RMS ±10%Source frequency45 Hz to 440 Hz from 100 V to 120 V45 Hz to 66 Hz from 120 V to 240 VPower consumption75 W maximumBattery power Requires TDS3BATC, rechargeable lithium ion battery packOperating time, typical 3 hoursPhysical characteristicsDimensionsWeightPackage dimensionsRackmount (RM3000)TDS3000C Series Digital Phosphor OscilloscopesDatasheetEMC, environment and safetyTemperatureOperating0 ºC to +50 ºCNon-operating-40 ºC to +71 ºCHumidity(Operating and non-operating)At or below +30 ºC Up to 95% RH+30 ºC up to +50 ºC Up to 45% RHAltitudeOperating To 3,000 metersNon-operating15,000 metersElectromagnetic compatibility Meets or exceeds EN61326 Class A, Annex D radiated and conducted emissions and immunity; EN6100-3-2 AC PowerlineHarmonic Emissions; EN6100-3-3 Voltage Changes, Fluctuation, and Flicker; FCC 47 CFR, Part 15, Subpart B, Class A;Australian EMC frameworkSafety UL61010B-1, CSA1010.1, IEC61010-1, EN61010-1Ordering informationTDS3000C familyTDS3012C100 MHz, 2 channels, 1.25 GS/sTDS3014C100 MHz, 4 channels, 1.25 GS/sTDS3032C300 MHz, 2 channels, 2.5 GS/sTDS3034C300 MHz, 4 channels, 2.5 GS/sTDS3052C500 MHz, 2 channels, 5 GS/sTDS3054C500 MHz, 4 channels, 5 GS/sPlease specify a language option and a power plug option from the lists that follow.Standard accessoriesProbesP6139B500 MHz 10x passive probe, one per channel AccessoriesFront protective coverAccessory trayDocumentation CD Contains User Manuals in all languagesFront panel overlay Translated front panel overlay. Specify language option.Installation and Safety ManualPower cord Specify power plug option.OpenChoice® PC connectivity software Enables fast and easy communication between Windows PC and the TDS3000C Series through LAN, GPIB, or RS-232. Transfer and save settings, waveforms, measurements, and screen imagesTraceable Certificate of Calibration NIM/NISTWarrantyThree year warranty covering all labor and parts, excluding probes and accessoriesInstrument optionsPower plug optionsOpt. A0North America power plug (115 V, 60 Hz)Opt. A1Universal Euro power plug (220 V, 50 Hz)Opt. A2United Kingdom power plug (240 V, 50 Hz)Opt. A3Australia power plug (240 V, 50 Hz)Opt. A4North America power plug (240 V, 50 Hz)Opt. A5Switzerland power plug (220 V, 50 Hz)Opt. A6Japan power plug (100 V, 50/60 Hz)Opt. A10China power plug (50 Hz)Opt. A11India power plug (50 Hz)Opt. A12Brazil power plug (60 Hz)Opt. A99No power cordTDS3000C Series Digital Phosphor OscilloscopesDatasheetLanguage optionsOpt. L0English manualOpt. L1French manualOpt. L2Italian manualOpt. L3German manualOpt. L4Spanish manualOpt. L5Japanese manualOpt. L6Portuguese manualOpt. L7Simplified Chinese manualOpt. L8Traditional Chinese manualOpt. L9Korean manualOpt. L10Russian manualOpt. L99No manualLanguage options include translated front-panel overlay for the selected language(s). Service optionsRecommended accessoriesProbesADA400A100x, 10x, 1x, 0.1x high-gain differential amplifier P5100A 2.5 kV, 100x high-voltage passive probeP5205A 1.3 kV, 100 MHz high-voltage differential probe P5210A 5.6 kV, 50 MHz high-voltage differential probe P6243 1 GHz, ≤1 pF input C 10x active probeTCP202A50 MHz, 15 A AC/DC current probeTCP30315 MHz, 150 A current probe 3TCP305A50 MHz, 50 A current probe 3TCP312A100 MHz, 30 A current probe 3TCPA300100 MHz probe amplifier3Requires TCPA300 probe amplifier.TCPA40050 MHz probe amplifierTCP404XL 2 MHz, 500 A current probe 4AccessoriesTDS3GV GPIB, VGA, RS-232 interfaceTDS3AAM Advanced Analysis Module. Adds extended math capability, arbitrary math expressions, measurement statistics, and additionalautomated measurementsTDS3LIM Limit Testing Module. Adds custom waveform limit testing capabilitiesTDS3TMT Telecom Mask Testing Module. Adds pass/fail compliance of ITU-T G.703 and ANSI T1.102 standards, custom mask testing, andmoreTDS3VID Extended Video Analysis Module. Adds video quickmenu, autoset, hold, line count trigger, video picture mode, vectorscope 5mode, HDTV format trigger graticules, and moreTDS3BATC Lithium-ion battery pack for up to 3 hours continuous operation without line powerTDS3ION Battery chargerAC3000Soft case for carrying instrumentHCTEK4321Hard plastic case for carrying instrument(requires AC3000)RM3000Rackmount kit071-2507-xxService manual (English only)Tektronix is registered to ISO 9001 and ISO 14001 by SRI Quality System Registrar.Product(s) complies with IEEE Standard 488.1-1987, RS-232-C, and with Tektronix Standard Codes and Formats.4Requires TCPA400 probe amplifier.5Vectorscope does not support composite video.TDS3000C Series Digital Phosphor Oscilloscopes 11DatasheetASEAN / Australasia (65) 6356 3900 Austria 00800 2255 4835*Balkans, Israel, South Africa and other ISE Countries +41 52 675 3777 Belgium 00800 2255 4835*Brazil +55 (11) 3759 7627 Canada180****9200Central East Europe and the Baltics +41 52 675 3777 Central Europe & Greece +41 52 675 3777 Denmark +45 80 88 1401Finland +41 52 675 3777 France 00800 2255 4835*Germany 00800 2255 4835*Hong Kong 400 820 5835 India 000 800 650 1835 Italy 00800 2255 4835*Japan 81 (3) 6714 3010 Luxembourg +41 52 675 3777 Mexico, Central/South America & Caribbean 52 (55) 56 04 50 90Middle East, Asia, and North Africa +41 52 675 3777 The Netherlands 00800 2255 4835*Norway 800 16098People's Republic of China 400 820 5835 Poland +41 52 675 3777 Portugal 80 08 12370Republic of Korea +822 6917 5084, 822 6917 5080 Russia & CIS +7 (495) 6647564 South Africa +41 52 675 3777Spain 00800 2255 4835*Sweden 00800 2255 4835*Switzerland 00800 2255 4835*Taiwan 886 (2) 2656 6688 United Kingdom & Ireland 00800 2255 4835*USA180****9200* European toll-free number. If not accessible, call: +41 52 675 3777For Further Information. Tektronix maintains a comprehensive, constantly expanding collection of application notes, technical briefs and other resources to help engineers working on the cutting edge of technology. Please visit . Copyright © Tektronix, Inc. All rights reserved. Tektronix products are covered by U.S. and foreign patents, issued and pending. Information in this publication supersedes that in all previously published material. Specification andprice change privileges reserved. TEKTRONIX and TEK are registered trademarks of Tektronix, Inc. All other trade names referenced are the service marks, trademarks, or registered trademarks of their respective companies.27 Mar 2017 41W-12482-26 。

S-133ߜUp to Three Pens ߜ254 mm (10 in) Chart ߜAccepts Thermocouple,RTD, V , mV or mA Signals ߜOverall Accuracy of ±0.25%of Span ߜUp to Six I/O Modules Available, Including Input Isolation ߜRetransmission Options Available on up to Three Channels ߜFlow Totalization on All Three Channels ߜOne or Two PID Control Outputs Available The new OMEGA ®CT1000A microprocessor-based circular recorder offers a wide range of measurement and control capabilities. The recorder is available as a one-, two-, or three-channel recorder offering up to 12output relays allocated to six setpoints which in turn can be allocated to any channel or channels. The unit can be supplied for flow indication and recording with totalization on up to three channels.Flow indication and recording with totalization on all channels is also available. Each channel has two totalizers, one of which can be used for a batch total resettable from thefront panel, and displayed in sequence with flow rate. The other is used for display of a secure total accessible only by operating the appropriate channel select buttons.Specifications Inputs No. of Inputs:1, 2, or 3Input Impedance:Millivolt inputs >10 ΩVoltage inputs 500 ΩCurrent inputs 10 ΩTemperature:Thermocouple 1700°C (3090°F) max.Minimum span 100°C (180°F)Resistance thermometer 600°C (1000°F) max. Minimum span 50°C (90°F)Cold Junction:Automatic cold junction compensation (ACJC) fittedMicroprocessor-Based Circular Recorders Up to 12 Output RelaysModel CT1000A $1525Basic Unit OMEGA CARES-134SCircular Recorders Wide Range of Measurement and Control CapabilitiesLinearization:Programmable for all inputs. State whether linear, square root, power 3⁄2, 5⁄2law, or type of thermocouple or RTD Broken Sensor Protection:Programmable, upscale or downscale drive or none (not available on mA and V inputs)Filter Time:Programmable from 0 to 60 sec in 1-sec steps Event Marker:Voltage free contacts or 0-5 V logic level Change of Input Mode:By repositioning plug-in link Change of Input Range/Scan:Programmable Program Modification:By user-operated membrane switches above chart Floating Inputs-Isolation:2.5 Vdc max between channels upon removal of terminal block links Insulation, Inputs to Ground:500 Vdc Interference Suppression (based on 0-1000 mV range input): Radiated (r.f.):F.S. <±2% over range 20 MHz to 1000 MHz at field strength of 5 V Line Interruption:<100 msec loss, no effect, >110 ms loss instrument returns to operation after automatic reset Line Interference:<500 V input,pulse width up to 125 µs, no effect Common Mode:<1% span error max for 250 V rms 50 Hz Series Mode:<1% span error for 200% span, 50 Hz Outputs and Setpoints No. of Setpoints:Up to two setpoints per channel Setpoint Adjustment:Programmable No. of Relays:Up to two per channel Relay Contacts:Single pole changeover Voltage:250 Vac, 250 Vdc max Current:5 Aac, 5 Adc max Loading (non-inductive):1250 VA, 50 W max I nsulation, Contacts to Ground:2 kV rms Relay Action (programmable):Energized above (EA) setpoint or energized below (EB) setpoint,3 state or latching; external counter drive option (module 5) 50 msec pulse 24 V max current 150 mA Analog Outputs Output module (module 8) is isolated and includes a relay.The maximum isolation voltage is 1000 V between input and output Retransmission:Programmable min (zero) and max (full scale) values from 0-20 mA in 0.1 mA steps, up to 20 mA into 1 k Ωmax Control:P, PI or PID Analog Output:Up to 20 mA at 15 V; channel 1 reverse or direct Analog Controller Output:Up to 20 mA 1 k Ωmax (reverse or direct)Time Proportioning Controller Action:Time proportioning, reverse or direct programmable Time Proportioning Cycle Time:5 to 60 sec, programmable in 1 sec steps Proportional Band:2 to 500%,programmable in 1% steps Integral Action Time:1 to 1800 sec, programmable in 1 sec steps and OFF Derivative Action Time:0 to 600 sec, programmable in 1 sec steps and OFF Approach Band:0.1 to 3.0 proportional bands,programmable in 0.1 steps Setpoint Change:No erroneous generation of derivative response Accuracy ±0.25% span max for all zero-based ranges within permitted limits. Ref.conditions 20°C (68°F) and 115 V or 230 V apply Linearizer Accuracy:±0.1°C typical ResolutionMeasurement:mV, V, mA, TC ≥0.1% span, for all zero-basedranges within permitted limits R/T:0.06 ΩPen:≤0.13% full scale travelDisplay:±1 digitPens Response Time:6 sec for 10% to 90% typical. Inputsignals can be averaged over a 0 to60 sec (filter) time, programmable in1 sec stepsRamp/Soak Option:Allows four “menus”; each menucan contain up to 30 segments thatcan be split into 1 to 9 profilesSolid State Relay Option(Module J):Provides two solid stateswitching 24 Vdc at 30 mA driveoutputs used to drive externallymounted solid state relaysIsolated Input Option (Module K):Provides up to 2 kV isolationchannel-to-channel and channel-to-ground. Up to two allowed, position2 for channel 2 and/or position3 forchannel 3Displays and RecordsDisplay:20 character, dot matrixvacuum fluorescent with blue filterProcess variable 4 digitProgramming:Up, down scrollswitches above chartChart:Circular with linear graduationsChart Speed:1 rev per hour up to1 rev per week (168 hr),programmable in 1-hour stepsPens:Red: channel 1; Green:channel 2; Blue: channel 3,disposableEvent Pen:Pen 3, 3 positions:center, off, at chart rim. Time linecoincident with pen 1; contactclosure or 0-5 V logicCT1000AMicroprocessor-Based Circular RecordersFlow Input VersionGeneralFlow Total:Programmable ON or OFFCount Rate Zero: Programmable from 0 to 0.999 in 0.001 pps steps then 1.0 to 9.99 in 0.01 steps Count Rate Cut Off:Totalization can be stopped if flow rate falls below preset value. Preset value adjustable over full span Count Rate Full Scale: Programmable from 0.001 to 0.999 then 1.00 to 10.00 ppsAnalog InputsMathematical Function Accuracyx1⁄2-0 to 100%0.1% of reading x3⁄2-7 to 100%0.2% of reading x5⁄2-18 to 100%0.3% of reading Below these values, the error increases asymptotically as input approaches zeroFrequency Inputs:Module C accuracy ±0.1% or1 digit, whichever is greaterfor zero-based ranges High Level Input:Frequency Range:Between 0-0.1 Hz and 0-4 kHza. TTL level square waveb. Open collector to accept currentlevel 2 mA at 5 Vc. Volt free contacts to acceptcurrent level 2 mA at 5 Vd. Voltage square wave. When thepeak value lies between 2 V and+50 and the trough value liesbetween –50 V and 1 VLow Level Inputs:a.Vortex and ElectromagneticFlowmeters:Amplitude:4 mA or greater square wave,with an offset up to 20 mA,0-4 mA, 16-20 mA or 4-20 mAVolt drop:Maximum 2 V at 20 mAFrequency Range:0.1 Hz to 4 kHzb.Turbine and Rotary Shunt MetersAmplitude: 1 mV/HzFrequency Range: 3 Hz to 4 kHzc.General Purpose ac CoupledAmplitude:Fixed or variable between thelimits of 5 mV peak to peak to50 V peak to peakFrequency Range:3 Hz to4 kHz on inputs wherethe amplitude is proportionalto frequency, automatic variablegain (maximum sensitivity1 mV/Hz) can be achieved bylink positioningd.General Purpose dc CoupledFrequency Range:0.1 Hz to 4 kHzPhysical Specifications PowerVoltage Requirements:110 V (min 93 V, max 127 V), or230 V (min 195 V, max 265 V), 50or 60 Hz Alternatively 10 to 30 VdcPower Requirements: <28 VAWarm-up Time: approx. 10 sError Due to Power SupplyVoltage Fluctuation:±0.1% span for ±15% fluctuationS-135S-136Insulation:Mains to ground 2 kV rms Transmitter Power Supply Output Voltage: 25 V ±0.5 V at 0 or 60 mA (loaded with 3 transmitters)Output Ripple: 100 mV peak to peak max.Load Regulation:±0.1 V for output change 4-20 mA Output Voltage Variation with Supply Voltage:≤1 V for ±15%supply voltage Environmental Data Operating Temperature Limits:0to 55°C (32 to 130°F)Operating Humidity Limits: 0 to 80% RH (paper and ink system,0 to 95% RH electronics)Error Due to Ambient Temperature Variation (unsuppressed ranges): ±0.02%span/°C typical Mechanical DataMounting:Wall or panel by 3brackets (supplied)Dimensions:360 H x 370 W x 170 mm D(14.18x 14.58x 6.7")Panel Cutout:342 H x 348 mm W(13.5 H x 13.7" W )Panel Space Requirement:410 W x 400 H x 150 mm D(16.15 x 15.76 x 5.9")Case and Door:Sheet steel case with hingedchart plate.Foam-molded door with glasswindow (polycarbonate available as special order)Weight:10.5 kg (23.2 lb) approx.Electrical Min. Start Min.Max. Span &Input Type Value Span Range Value mV -999 5.001000V -20.00.5020.0mA -99.90.50100.0J T/C*-100°C (-148°F)100°C(180°F)900°C (1620°F)K T/C*-100°C (-148°F)150°C (270°F)1300°C (2340°F)R, S T/C*-15°C (5°F)600°C (1080°F)1700°C (3060°F)T T/C -250°C (-418·F)170°C (306°F)300°C (540°F)E T/C*-100°C (-148°F)100°C (180°F)900°C (1620°F)B T/C*-18°C (0°F)1100°C (1980°F)1800°C (3240°F)N T/C*-200°C (-328°F)180°C (324°F)1300°C (2340°F)RTD*-200°C (-328°F)50°C (90°F)600°C (1080°F)Range Limits *Temperature inputs are °C/°F switchable Options for Base UnitsOptions can be added to the base units by changing the thirdand/or fourth (i.e.: last two) digits in the part number and addingthe appropriate modules and prices.1) Flow option:change the third digit in the model number to a “5” and add $255to base price. No modules required.Example: CT1150A is a 1-pen unit with flow option,$1525 + 255 = $17802) Control option (supports control on channel 1 and/or 2):change the third digit in the model number to a “4” and add$475to base price. This option also requires you to purchaseadditional module(s) for the required output(s). Example:CT1240A-M8-M8is a two-pen recorder with control option onboth channels and two isolated analog outputs,$1875 + 475 + 325 + 325 = $30003) Ramp/soak control option (supports control on channel1 and/or 2):change the third and fourth digits to “44” and add$1030to base price. This option also requires you to purchaseadditional modules for the required output(s). Example:CT1244A-M8-ME is a two-pen recorder with ramp/soak controloption and one isolated analog output (control on 1 channel),$1875 + 1030 + 325 + 250 = $3480To Order (Specify Model Number)Model No.Price Description CT1100A $15251-pen recorder, base unit CT1200A 18752-pen recorder, base unit CT1300A 22503-pen recorder, base unit CT1205A-MB 27252-pen recorder, 1 analog, 1 event CT1305A-MB 29253-pen recorder, 2 analog, 1 event Each unit comes complete with one package of chart paper, pen(s),and complete operator’s manual.For options, see table at right.Ordering Example: CT1140A-M8is a one-pen recorder with control option, analog output and relay, + CT1000-RED , extra pens for channel 1 and CT-1000C-100/7, pkg. of 500 charts, $1525 + 475 +325 +19 +140 = $2484OMEGACARE SMextended warranty program is available for models shown on this page. Ask your sales representative for full details when placing an order.OCW-1 OMEGACARE SM extends standard 2-year warranty to a total of 3 years ($150), $2325 + 150 = $2475Ordering Add'l Suffix Price Description -M8$325Isolated analog output with relay-MB 150Event pen input -ME 250Ramp/soak digital input Note: Up to six I/O modules can be installed. The -M1, -M2 and -MAmodules can be field installed and ordered as CT1000A-M1, etc.Other modules may require options added to base recorder.Modules SModel No.Price DescriptionCT1000A-M1$240Single relay modulesCT1000A-M2480Dual relay modulesCT1000A-MA 400Transmitter power supply moduleCT1100ACustom charts available by special order. Consult Sales.Accessories Remember to Purchase Extra Pens and Paper!Model No.Price DescriptionCT-1000-RED $ 195 red pens, channel 1CT-1000-GREEN 195 green pens, channel 2CT-1000-BLUE 195 blue pens, channel 3CT-1000C-100/7140500 charts, 0-100 range, 7 dayCT-1000C-100/24140500 charts, 0-100 range, 24 hrCT-1000C-0-100/8HRS 140500 charts, 0-100 range, 8 hrCT-1000C-0-14PH/24HRS 140500 charts, 0-14 range, 24 hrCT-1000C-0-50/7140500 charts, 0-50 range, 7 dayCT-1000C-0-200/24140500 charts, 0-200 range, 24 hrCT-1000C-0-200/7140500 charts, 0-200 range, 7 dayCT-1000C-0-300/24140500 charts, 0-300 range, 24 hrCT-1000C-0-800F/1140500 charts, 0-800 range, 24 hrCT-1000C-200-400F/1140500 charts, 200-400 range, 24 hrCT-1000C--100C-100/24140500 charts, -100-100 range, 24 hrCANADAwww.omega.caLaval(Quebec)1-800-TC-OMEGAUNITED KINGDOMwww. Manchester, England 0800-488-488GERMANY www.omega.de Deckenpfronn, Germany ************FRANCE www.omega.frGuyancourt, France 088-466-342BENELUX www.omega.nl Amstelveen, NL 0800-099-33-44UNITED STATES1-800-TC-OMEGAStamford, CT.CZECH REPUBLIC www.omegaeng.cz Karviná, Czech Republic 596-311-899TemperatureCalibrators, Connectors, General Test and MeasurementInstruments, Glass Bulb Thermometers, Handheld Instrumentsfor Temperature Measurement, Ice Point References,Indicating Labels, Crayons, Cements and Lacquers, InfraredTemperature Measurement Instruments, Recorders RelativeHumidity Measurement Instruments, RTD Probes, Elementsand Assemblies, Temperature & Process Meters, Timers andCounters, Temperature and Process Controllers and PowerSwitching Devices, Thermistor Elements, Probes andAssemblies,Thermocouples Thermowells and Head and WellAssemblies, Transmitters, Wire Pressure, Strain and Force Displacement Transducers, Dynamic Measurement Force Sensors, Instrumentation for Pressure and StrainMeasurements, Load Cells, Pressure Gauges, PressureReference Section, Pressure Switches, Pressure Transducers,Proximity Transducers, Regulators,Strain Gages, Torque Transducers, Valves pH and Conductivity Conductivity Instrumentation, Dissolved Oxygen Instrumentation, Environmental Instrumentation, pH Electrodes and Instruments, Water and Soil AnalysisInstrumentationHeaters Band Heaters, Cartridge Heaters, Circulation Heaters,Comfort Heaters, Controllers, Meters and SwitchingDevices, Flexible Heaters, General Test and MeasurementInstruments, Heater Hook-up Wire, Heating CableSystems, Immersion Heaters, Process Air and Duct,Heaters, Radiant Heaters, Strip Heaters, Tubular Heaters Flow and Level Air Velocity Indicators, Doppler Flowmeters, LevelMeasurement, Magnetic Flowmeters, Mass Flowmeters,Pitot Tubes, Pumps, Rotameters, Turbine and Paddle WheelFlowmeters, Ultrasonic Flowmeters, Valves, Variable AreaFlowmeters, Vortex Shedding Flowmeters Data Acquisition Auto-Dialers and Alarm Monitoring Systems, Communication Products and Converters, Data Acquisition and Analysis Software, Data Loggers Plug-in Cards, Signal Conditioners, USB, RS232, RS485 and Parallel Port Data Acquisition Systems, Wireless Transmitters and Receivers。

QUICKSTART GUIDE800-788-5572SAFETY INSTRUCTIONSPlease review the following safety instructions before using the printer:• Toro Max is intended for indoor use only. Keep Toro Max away from humidity, corrosive environments, and prolonged exposure to direct sunlight.• Use only with the power supply originally included with the system, or a replacement specified by your DuraLabel representative.• The Toro Max Battery is a Lithium-Ion (Li-ion) battery designed specifically for use in this system; it should not be connected to other hardware, and no other battery (including those for the original Toro printing system) should be connected to your Toro Max. If the system and battery need to be shipped, they should be shipped separately. Damage to the battery, including exposure to extreme temperatures, may cause leakage or fire.• To completely disconnect power from your Toro Max, remove the battery (if present) and unplug its power supply from the wall socket.• Do not pour liquids onto the printer or its parts. For ordinary cleaning, follow the instructions included in this guide.• Only qualified service personnel should attempt to repair the printer.• Toro Max supply may build a small static charge during loading or use. Do not operate Toro Max near flammable materials.NOTE: Changes or modifications not expressly approved by the party responsible for compliance could void the user’s authority to operate the equipment.For support, please contact Graphic Products by calling 800-788-5572 or visiting . GETTING STARTEDThank you for choosing the DuraLabel Toro Max. With this standalone system, producing custom labels and signs is fast and easy. This guide will show you how to set up your new Toro Max, load supplies, and start printing labels.In the BoxIn Toro Max’s box, you will findthe following materials:• Toro Max Printer• Power Cord and AC Adapter(“brick”)• Notched Supply Spindle• Fixing Tabs• USB Cable• USB Flash Drive with PCsoftware• USB Wi-Fi Receiver• Wireless Optical Mouse• StylusThe Toro Max battery will beshipped in a separate box.Initial Setup1. Place the Toro Max printer on a secure, flat surface, with the Control Panel (buttons) facing you.2. Plug the AC Adapter (“brick”) into a standard, grounded three-prong wall outlet. Then, plug the other end of the power cord into your Toro Max. (This connector uses a slider to latch into place, preventing accidental disconnects; to unplug the connector from your Toro Max, grasp the plug slider and pull it away from the printer.)3. Slide the Keyboard Release Slider (on the Control Panel) to the right, and swing the keyboard down.4. To adjust the screen angle, push the Keyboard Release Button (to the right of the screen). The screen will pop forward, and you can lift the screen to the desired angle.5. Press the Power button (on the Control Panel) to turn on your Toro Max. Once the system powers up, use a finger or the included stylus to navigate with the touchscreen.6. (Optional) If you prefer, you can use the included wireless mouse instead of the touchscreen controls. Connect the mouse’s small USB receiver (stowed in the underside of the mouse) to one of the USB-A ports on your Toro Max. Then, slide the mouse’s power switch to ON. The wireless mouse uses one AA battery.Installing the BatteryTo use your Toro Max without an AC power supply connected, you will need the Toro Max battery installed and charged. When fully charged, the battery will provide about three hours of continuous printing.To install the battery:1. Remove the battery cover from the back of your Toro Max by pushing the slider downward and pulling the door away.2. Position the battery so the cut-outs are aligned and the contacts on the battery match up with the contacts in the Toro Max.3. Press the battery in until it locks into place.4. Return the battery cover to its position, and press it into place.The Toro Max battery will charge automatically while your Toro Max is plugged in with its AC adapter, whether the system is powered on or off. Charging will stop automatically when the battery is full.IMPORTANT: If you have a battery for the original DuraLabel Toro system, do not use it in the Toro Max, as the older batterywas designed to use a separate charging system. Contact your DuraLabel representative for more information.Supply Feed Power Button Printer Status LightSupply Status Light Battery Status LightKeyboard Release SliderControl PanelLoading SuppliesTo load your Toro Max with printing ribbon (“ink”) and label stock, you will need tofully raise the hinged cover and the attached ribbon rails.1. Lift the cover release latch and raise the cover of the printer; the ribbon railswill raise automatically. Make sure the cover and rails are fully raised beforecontinuing.2. Slide the ribbon cartridge into the slot in the rails. The cartridge will only fit thecorrect way, and a magnet will hold it in place. (To remove a ribbon cartridge,simply pull it out.)3. Place the roll of label stock onto the supply spindle; for narrower supplies, hold the label stock roughly centered on thespindle by sliding a fixing tab onto the spindle from each side. Rest the supply in the supply well, with the spindle fitting into its slots. Fresh label stock should feed toward the cutter module, with the printable surface facing upward.4. Feed the end of the roll of label stock between the two movable gray guides, and over the black rubber roller near the cuttermodule. (You can flip the cutter module down for more room; simply pull the top edge away from the body of the printer.) 5. Slide the movable gray guides together so they hold the label stock neatly centered in the printer, without bending orwrinkling the label stock.6. If you lowered the cutter module, lift it back into its ready position; it will snap into place. Finally,lower the cover until it latches closed; the ribbon rails will lower into place automatically.Your Toro Max will recognize the supplies you have loaded and automatically adjust its printsettings for the best quality. Now you’re ready to design and print custom labels!CLEANING YOUR TORO MAXThrough normal use, parts of your Toro Max may collect label adhesive or paper dust. Cleaning the system periodically (such as after every few rolls of label stock) will extend the life of the printer and help maintain optimal printing quality. IMPORTANT: Always turn the power off and disconnect Toro Max from all power sources before cleaning or performing maintenance. After cleaning, wait at least 5 seconds before turning the power on again.To clean your Toro Max:1. Turn the printer off and disconnect it from all power sources (AC power and battery, if installed).2. Lift the cover release latch and raise the cover of the printer. The cover mechanism will hold the printer open.3. Remove the ribbon cartridge and label stock (if loaded), and place them on a clean, flat surface.4. Open an individually packaged cleaning swab, or lightly moisten a clean, soft cloth with isopropyl alcohol (isopropanol).5. Gently rub the swab or cloth back and forth across the front and underside of the print head to remove any built-up adhesiveor residue.6. Run the swab or cloth between and around the gray adjustable label guides in the floor of the printer, to clear any dust oradhesive build-up.7. Lift the two black latches on either side of the black rubber roller (“platen roller”) and lift it out. (You can use the notchedend of the supply spindle to help release the latches.) Use the swab or cloth to gently wipe away any material that has stuck to the roller surface. Then, press the platen roller back into place, until the latch on each side has locked it down again.8. Finally, use the swab or cloth to clean both sides of the cutter blade by gently inserting the swab into the slot of the cuttermodule and sliding it from side to side. Repeat this process for the front and the back of the blade; the cutter module can be flipped forward to make the back easier to reach.WI-FI SETUPToro Max comes with a USB Wi-Fi adapter to allow it to be connected to your local network.To set up this connection:1. Open the Wi-Fi controls by clicking on the wireless icon in the toolbar, or navigate to the Settings menu from the main screenand choose Networking.2. Make sure the Wireless option is switched on (showing orange). A list of available wireless networks will appear. (If your ToroMax is already connected to a wireless network, there will be a checkmark next to the entry for that network.)3. Select your preferred wireless network. If the network is protected by a password, you will be prompted to enter it; then, click“Connect.”To remove saved details about a network, click the gear icon for that network’s entry in the list, and choose “Forget Network.”Graphic Products®, DuraLabel®, PathFinder®, Toro®, Toro Max®, Bronco®, Lobo® and Kodiak® are Registered Trademarks of Graphic Products, Inc. ©2021. Graphic Products, Inc. grants a limited revocable right to reuse portions of the material contained herein for non-commercial, internal, and educational/training use. Any use beyond that described here requires the written consent of Graphic Products, Inc. Licensee agrees to reproduce the Trademark, Copyright, and Legal disclaimers in all works created under this license.。

Congratulations and thank you for purchasing TORO 8 High performance sensorless 1/8 Scale Brushless Motor Electronic Speed Control. The TORO 8,1/8 scale brushless ESC represents a latest technologies, providing all the features and robust design qualities.INTRODUCTION1/8 SCALE BRUSHLESS ESCFor best results clean the bottom of the speed control and chassis. Peel off the cover on one side of the doubled-sided tape, and stick to the bottom of the speed control. DO NOT peel off the other side yet.Use a small piece of double-sided tape on the ON/OFF switch.Determine how you would prefer to connect the motor and battery pack to the speed control. For the motor, using Hi-Power connector pairs. Connectors are preferable for most applications as it allows you to easily change motors.2)SolderingTIPS & TRICKS: Place the speed control upright and use servo tape to secure it to the bench. Doing so provides a stable work area and allows easy access to the solder posts.Attaching Wires to the Speed Control:Red wires are usually used to connect the speed control to the positive battery terminal and the positive motor terminal. Black wire is typically used for the battery negative terminal. Inspect the housing on the speed control next to each post or refer to the diagrams to determine which color wire to attach to each post.Strip back the insulation of the wire by about 2.4mm to 3.2mm (3/32" to 1/8") and"pre-tin" the wire by heating the end and applying solder until it is thoroughly covered. CAUTION: Be very careful not to splash yourself with hot solder.Place the tip of the iron in the notch on top of the post and apply a small amount ofsolder to the post. When the solder has flowed, remove the soldering iron, wipe the tip clean and apply a small amount of fresh solder to it. Pre-Heat both the wire and the post.1)Plan Speed Control PlacementChoose a location for the speed control that is protected from debris. To prevent radio interference place the speed control as far away from the radio receiver as possible and keep the power wires as short as possible.BEFORE YOU BEGINrecommend removing your pinion gear for your own safety and the safety of those around you before performing calibration and programming functions with this system. Please keep your hands, hair, cloth, clear from the gear train and wheels of an armed high performance system.IMPORTANT: Take precautions if removing factory battery connectors. Connecting the battery backwards will cause damage, and will void warranty. When solderingconnectors to a battery pack, cut only one wire of the battery pack at a time to ensure that the exposed wires cannot short together.HINT: If you are using connectors for both the battery and the motor, make sure that they are not the same or that you have a male and a female attached to the speedcontrol wires. That way, you cannot accidentally connect the battery to the motor wires or vice versa.Make sure that the connector ends will be mated together correctly, male to female, and that the wire colors matchred to red and black to black.WATER & ELECTRONICS DON'T MIX !Never allow water, moisture, or other foreign materials to get inside ESC, motor, or on the PC Boards. Water damage will void the warranty!1/8 SCALE OR SMALLERThe TORO 8 is intended for 1/8 scale vehicles.INSULATE WIRESAlways insulate exposed wiring with heat shrink tubing or electrical tape to prevent short circuits, which can damage ESC.TRANSMITTER ON FIRSTTurn on the transmitter first THEN turn on the speed control.2 - 6 LI-PO CELLS ONLYNever use fewer than 2 or more than 6 LIPO cells in the vehicle's main battery pack. The TORO 8 handles up to 6S LIPO input (25.2 Volts MAX).DISCONNECT BATTERIES WHEN NOT IN USEAlways disconnect the battery pack from the speed control when not in use to avoid short circuits and possible fire hazard.NO REVERSE VOLTAGE !Reverse battery polarity can damage ESC & void warranty. Disconnect battery immediately if a reverse connection occurs.Same techniques described in the preceding section may be used to solder the wires to the battery or to battery connectors.Hold the wire so the tinned end is in contact with the notch of the post. Now touch the iron tip to the wire and the post. Wait about 4 seconds for the solder to flow, and then remove the iron while still holding the wire. You may let go of the wire after a second or two when the solder sets.Prolonged/excessive heating of solder post (motor or ESC) will damage PCB.Note: Make sure no wire strands have strayed to an adjacent solder post, this will result in short-circuiting & severe ESC damage, which will void the warranty.Brushed Motor WiringUse this mode if you U wish to use reverse. se only the blue and orange motor wires from the ESC. In most applications, the blue wire from the ESC will connect to positive + side hood on your motor, and the orange wire to the negative - side hood of the motor. The yellow motor wire is not used. After calibration, (explained below) you may need to swap the two motor wires to get the wheels to spin in the right direction.Connect all three of the ESC motor wires to the negative (-) side of the motor. You can either use a Y harness from the ESC battery input positive wire to connect to both the battery and the positive side of the motor, or use a single wire from the positive ESC input to the positive battery pole and then continue to the positive (+) side of ""How to Calibrate ESC Individual transmitter's signals for full throttle, full brake and neutral vary. You must calibrate your ESC so that it will operate more effectively with you transmitter.IMPORTANT NOTE: Calibration is necessary for the first use of the ESC, or whenever1)Programming Card(Optional Part)Programming Card allows you to modify the most commonly used settings in your TORO 8 controller all at the touch of a single button. No computer needed. Simply connect the Programming Card to the throttle lead of the controller and power the programming card as described below. Click the button to scroll through and change the indicated settings. All the settings will show on the programming card at once. Can't get any easier!Brushless Motor WiringConnect the blue, yellow and orange motor wires to the motor.There is no polarity on the three ESC-to-motor wires, so do not worry about how you connect them initially. You may find it necessary to swap two wires if the motor runs in reverse.Reversing Brushed Motor ModeTo Batt -To Batt +To Receiver Channel 2To Motor -To Motor +To Batt -To Batt +To Batt -To Batt +To Motor +(Shared)All 3 Wiresto Motor -ESC switch OFF.Turn on the Transmitter.Hold full throttle on your transmitter and turn the ESC's switch ON. Keep holding full throttle on the transmitter. The ESC will flashes LED and ring the initialization tones.Wait 2 secondsGreen LED blinks rapidly and the motor will rings 1 second indicating full throttle measured.From this point on, when you connect batteries and turn on the switch, the ESC will give the initialization tone and flash, and the arming tone will ring second or two later. If the ESC is programmed for the Auto-Lipo setting, it will beep the number of cells in you Lipo pack between the initialization tones and the arming tones. After the arming tone plays, the ESC will ACTIVE and will respond to the throttle application.Switch On/OffHigh Power Brushed Motor Modethe motor Red LED blinks whiles beeping, indicating it's time to push full brake. Move throttle trigger to full brake and wait few seconds, the ESC will blink red LED and rings 1 second indicating full brake measure.Yellow LED blinks whiles beeping, indicating it's time for neutral. Relax trigger to neutral (center). The ESC will now ring 1 second and flash the yellow LED rapidly to accept the neutral position. ESC will blink LED and ring twice indicating that it is armed.ESC PROGRAMMING2)Manual ProgrammingManual Programming TORO 8 is as simple as answering a few questions. The TORO 8 asks questing by beeping a setting number, followed by the possible setting values. There are nine settings that can be programmed in the TORO 8.You must answer yes or no to the setting values as they are presented by TORO 8. When you enter programming mode the ESC will emit a sequence of beeps and LED flashes that tell you which programming step you are in. There are two parts to the beep sequence. The first set of beeps indicates the 'Setting Number (Question), e.g. Brake/Reverse Type, and the second set of beeps indicates a Setting Value, e.g. Reverse Lockout. Answering "No" to a Setting value will cause the ESC to ask for the next value in that section. After a "Yes" answer is accepted, the ESC knows you aren't interested in any other option in that section, so it skips to the first option in the next section.""""Note: If you answer "no" to all Setting Values for a particular Setting Number, the ESC will keep whatever value had been previously programmed. Only by answering "Yes" to a Setting Value will the ESC store/change that value.At this point the TORO 8 will be flashing/beeping the following sequence:Beep-Pause-Beep... and then repeatsThis indicates that you are at Question 1 and it is asking to accept/reject value 1.Programmable FeaturesHow to Enter Programming ModeWhen answering a question, you will need to move the trigger to yes (full throttle)position or the no (full brake) position and keep it there for about 3 seconds. When the ESC has accepted your answer it will confirm your reply by flashing the LED and emitting a beeping tone. Release the trigger allowing it to go to Neutral to confirm that you are ready for ESC to ask you next question. You are not required to continue through all nine programming options. For example, if you wish only to change the Brake/Reverse Type (Option 1) then after programming that setting you can disconnect power from the ESC and you're ready to run. Disconnecting the controller in the middle of programming simply retains the values for the remaining programming options that were previously set up.The TORO 8 comes with a 30mm x 30mm x 7mm 5V Brushless fan. Should the fan need replacement,simply unplug the fans power wires from the TORO 8, remove the 4 screws that secure the fan to the shroud and slide the fan out of the shroud housing.Rev/Brk/Brk or Fwd/Fwd Brushless KV ≤2400 Brushless 2400 KV ＞ Continuous /Burst Current Switching BEC Dimensions (LxWxH)Weight (Without wires)2010 SkyRC Technology Co., Ltd. All Rights Reserved.Manufactured bySKYRC TECHNOLOGY CO., "n """Solution : Try moving the throttle trim one way, then the other (usually towards thethrottle side is best). If your transmitter has a 50/50 and 70/30 setting for the throttle, set it for 50/50 and retry calibration. Also, if you have changed the dead band to a narrower band you may want to try going back to the ormal setting.Problem : My vehicle acts like it has turbo lag (poor acceleration/punch for the first few feet or yards)Problem : My TORO ESC may or may not arm, but it will not calibrate to my transmitter Status LED1 with 3 color (Red, Green & Orange)Thermal Overload Protection YesThe TORO 8 Brushless ESC is guaranteed to be free from defects in materials orworkmanship for a period of ONE YEAR from the original date of purchase (verified by dated, itemized sales receipt). Warranty does not cover incorrect installation,components worn by use, damage to case or exposed circuit boards, damage due to timing, damage from using more than 6 Li-Po cells input voltage, cross-connection of battery/motor power wires, overheating solder tabs, reverse voltage application,improper use or installation of external BEC, damage resulting from thermal overload or short-circuiting motor, damage from incorrect installation of FET servo or receiver battery pack, tampering with internal electronics, allowing water, moisture, or any other foreign material to enter ESC or get onto the PC board, incorrect installation/wiring of input plug plastic, allowing exposed wiring or solder tabs to short-circuit, or any damage caused by a crash, flooding or natural disaster. Because SKYRC has no control over the connection & use of the speed control or other related electronics, no liability may be assumed nor will be accepted for any damage resulting from the use of this product.Every SKYRC speed control & motor is thoroughly tested & cycled before leaving our facility and is, therefore, considered operational. By the act of connecting/operating speed control , user accepts all resulting liability . In no case shall our liability exceed the product's original cost. We reserve the right to modify warranty provisions without notice. This product is not intended for use by children under 14 years of age without the strict supervision of an adult. Use of this product in an uncontrolled manner may result in physical damage or injurise take extra care when operating any remote control vehicle.48.8x57.8x35.8mm (1.29x2.28x1.41in)88g (3.1oz)PRODUCT WARRANTYSolution : Most calibration issues can be solved by changing settings on the transmitter. Make sure you have both your throttle and brake endpoints (called EPA or ATV on your radio) on the throttle channel out to between 100 to 120%. Make sure if you have a Futaba or Futaba made transmitter to have the throttle channel set to the reversed position.Problem : My ESC calibrates for the full throttle and full brake positions but won't calibrate to the neutral throttle position. (Orange LED keeps flashing)Solution : Make sure you're using high quality batteries and a battery connector capable of high amp flow (40-100 amps). This behavior is very typical of a battery pack that is having difficulty providing the power your vehicle/system requires for top performance. Use copper bars to connect cells rather than welded tabs. Copper bars have a much lower resistance.Problem : My battery pack is plugged into the ESC and nothing is workingSolution : Make sure the ESC's receiver plug is plugged into channel 2 on the receiver, and that it's plugged in with the correct orientation. Double check your solder connections on the battery plug, and make sure the battery is showing good voltage.SPECIFICATIONS ARE SUBJECT TO CHANGE WITHOUT NOTICE.Up to 6S(25.2Volt), for 1/8 monster trucks and truggies Up to 4S(16.8Volt), ideal for 1/8 buggiesControls, TORO 8Motor Limits,TORO 80.0002 Ohms per phase at 25℃(77℉)Trans.Temp 150Amp / 950Amp 5.7V 3AmpBrushless KV ＜2300On Resistance, Brushless X150X80Up to 4S(16.8Volt), ideal for 1/8 buggiesX150X8080Amp / 500Amp Input Power (Cells)X150X800.0004 Ohms per phase at 25℃(77℉)Trans.Temp。

T D C用户指导手册-图文(精)SIMATIC TDC 用户指导手册SIMATIC TDC User GuideSIEMENS A&D CS目录第一章SIMATIC TDC控制系统 (4 1.1 TDC概述和特点 (41.2 TDC的应用领域 (61.3 TDC的设计思想和优点 (8第二章 TDC系统的硬件和软件 (9 2.1 硬件架构 (92.2 组态举例 (152.3 图形化组态 (182.4 技术数据 (21第三章TDC系统的组态 (273.1软件要求 (273.2描述和使用数据传输 (273.2.1数据的连续性 (273.2.2数据传输在同一CPU中同一任务中 (283.2.3数据传输在同一CPU中不同任务中 (283.2.4同一机架上数据传输在不同CPU的循环任务中 (293.2.5数据传输在不同CPU的中断任务中 (303.2.6减少死区时间 (313.3 CPU同步的意义和应用 (333.3.1 时间同步 (343.3.2使本身的基本时钟与一个主CPU的基本时钟同步 (343.3.3使本身的基本时钟与一个主CPU的中断任务时钟同步 (36 3.3.4使本身的中断任务时钟与一个主CPU的中断任务同步 (39 3.3.5多站的同步 (403.3.6同步失败的响应 (403.4 精确计算处理器的利用率 (423.5 CPU的循环任务的工作方式 (433.6 数据传输模式 (443.6.1 握手数据传输模式 (443.6.2 刷新数据传输模式 (443.6.3 选择数据传输模式 (453.6.4 复合数据传输模式 (46第四章通讯组态 (474.1 CPU本地通讯 (474.2 CPU-CPU之间通讯 (614.3 Rack-Rack之间通讯 (654.4 MPI通讯 (764.4.1 CP50MO与WinCC通讯 (764.4.2 CP50MO与OP27通讯 (94A&D Service & Support Page 2-2354.5 PROFIBUS-DP通讯 (1094.5.1 CP50MO作为主站 (1104.5.2 CP50MO作为从站 (1204.5.3 CP50MO同时作为主站和从站 (1244.5.4 Shared Input方式 (1354.5.5 CP50MO与MM440的通讯 (1434.6 TCP/IP 通讯 (1554.6.1 CP51M1与WinCC的标准通讯 (1564.6.2 CP51M1与WinCC的PMC通讯 (170 4.6.3 CP51M1与CP343-1通讯(TCP/UDP (2014.6.4 CP51M1与第三方设备通讯 (216第五章 I/O组态 (2175.1 数字量的读入/输出 (2175.2 模拟量的读入/输出 (2215.3 检测增量型编码器的输入 (2245.4 检测绝对值型编码器的输入 (224附录 (226A.在COM PROFIBUS中安装新的.gsd文件 (226B.使用Symtrace-D7 可视化过程数据和逻辑分析 (229A&D Service & Support Page 3-235第一章SIMATIC TDC控制系统1.1 TDC概述和特点如果您是一家工厂建设单位或工程单位,需要为工厂运营单位开发高性能的自动化解决方案,像金属冶炼、加工或输配电等领域。

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Framingham, MA 01701-9168 USA AM827391 Rev. 002019 年 6月中国危险物质限用表台湾危险物质限用表设备名称：ControlCenter 数字区域控制器机型名称：808461、808928、808930限用物质及其化学符号单位铅 （Pb ）汞 （Hg ）镉 （Cd ）六价铬 （Cr+6）多溴化联苯 （PBB ）多溴二苯醚（PBDE ）印刷电路板−○○○○○金属零件−○○○○○塑料零件○○○○○○扬声器−○○○○○线缆−○○○○○备注 1：“○”表示限用物质的百分比含量未超出参考值。

备注 2：“-”表示限用物质符合豁免规定。

ControlCenter数字区域控制器CC -1D / CC -2D / CC -3D安装指南技术信息接口以太网 (R J -45)电源需要以太网供电 (P o E ) 交换机运行温度0 °C 至 40 °C （32 °F 至 104 °F ）运行湿度80%（无冷凝）尺寸请参阅另一侧的表。

净重请参阅另一侧的表。

简介C o n t r o l C e n t e r 数字区域控制器包装清单螺丝 (2)自定义标签安装指南设置信息通过 P o E 网络交换机（不随附）将一个或多个数字区域控制器连接至功放或 D S P 的N e t w o r k 端口。

有关连接要求的详细信息，请参阅功放或 D S P 安装指南。

兼容产品C o n t r o l C e n t e r 数字区域控制器与各种 B o s e 功放和D S P 兼容。

有关兼容产品的完整列表，请参阅 P R O .B O SE .C O M 上每个 C o n t r o l C e n t e r 数字区域控制器的技术参数表。

产品概述注意：有关所有可用 C o n t r o l C e n t e r 数字区控制器型号的信息，请参阅技术信息下的表格。

1PTC-13-LV-A & PTC-13-AMultifunction Digital Timer• Dual 4 digit green LCD display timer • 13 programmable timing modes• 9 time ranges from 99.99sec to 9999hrs • 7-24Vac/9-30Vdc or 90-250Vac• 1 changeover and 1 N/O relay output • 2 SSR drive outputs• Programmable start, gate and reset • EEPROM memory (minimum 10 years) • Security passcode• Standard DIN48 square size • IP65 front enclosure code • Panel mounting• CE and RoHS compliantThe Omega PTC-13-A dual 4 digit digital timer is a multifunction, multi-time range digital timer suitable for controlling operation of equipment, machinery, systems or processes in a wide range of industrial applications.Thirteen timing functions can be selected together with time ranges from 0.01 seconds to 9999 hours, to operate two independent relay output contacts which are isolated from the supply voltage.The output contacts can beconfigured as two timed outputs, or one timed and one instantaneous output.These timers are housed in a compact DIN48 square panel mounting enclosure and are powered from 7-24Vac/9-30Vdc or 90-250Vac.SpecificationsAccuracy: ±0.01% ±1ms Power Supply Voltage:PTC-13-LV-A 7-24Vac/9-30Vdc (±10%) PTC-13-A 90-250Vac (±10%) Burden: <5VA Frequency: 50/60HzTime Ranges: 0.01 to 99.99sec, 0.1 to 999.9sec, 1 to 9999sec,00:01 to 99:59min, 0.1 to 999.9min, 1 to 9999min, 00:01 to 99:59hrs, 0.1 to 999.9hrs, 1 to 9999hrs Relay Output: Single pole changeover contact and single pole N/O contact Contact Rating:OP1 10A at 250Vac/30Vdc (resistive) OP2 5A at 250Vac/30Vdc (resistive) Relay Contact Life:Electrical: 200,000 operations Mechanical: 5,000,000 operations SSR Drive Output: Open collector output, maximum 30Vdc, 100mA Start, Gate & Reset Inputs: PNP or NPN programmable minimum pulse/void durations adjustable from 5 to 100msPNP active level is a 5 to 30V pulse NPN active level is a 0 to 2V pulseMechanicalEnclosure: Panel mounting to DIN 43700, Self extinguishing plastic case Plug in connection terminals Enclosure Code: Case front IP65, Case rear IP20 Weight: 230gEnvironmentalOperating Temperature: 0°C to 50°C (32°F to 122°F) Storage Temperature:-25°C to 70°C (-13°F to 158°F)GeneralMarkings: CE marked(meets EN61010-1:2010 low voltage and EN61326-1:2013 EMC directives)Timing ModesTiming Mode Timing Function Description Start / Reset / Restart / Count Mode 0Delay on Energise, Interval or Delayed Pulse Close to Start, Reset when Start Opens Mode 1Delay on Energise, Interval or Delayed Pulse Pulse to StartMode 2Delay on Energise, Interval or Delayed Pulse Close to Start, Restarts when Start Opens Mode 3 Delay on Energise, Interval or Delayed Pulse Open to Start, Close Start to ResetPulse to Start Mode 4 Delayed Cycle or Immediate Cyclewith Equal On and Off TimeMode 5 Delayed Cycle or Immediate CycleClose to Start, Reset when Start Openswith Equal On and Off TimeMode 6 Delay on Energise, Interval or Delayed Pulse Count only with Start ClosedMode 7 Delay on Energise, Interval or Delayed Pulse Count only with Start Closed,Restarts when Start Closed againPulse to Start Mode 8 Delayed Cycle or Immediate Cyclewith Single Cycle and Equal On and Off TimeMode 9 Delayed Cycle or Immediate CyclePulse to Startwith Variable On and Off TimesClose to Start, Reset when Start Opens Mode A Delayed Cycle or Immediate Cyclewith Variable On and Off TimesPulse to Start Mode b Double Output Delayed Cycle or Immediate Cyclewith Variable On and Off TimesMode C Delay on Energise, Interval or Delayed Pulse Count only with Start Closed,Restarts when Start OpensFront Panel Display FunctionsTo OrderP/N DescriptionPTC-13-LV-A Dual Digital Timer 7-24Vac/9-30VdcPTC-13-A Dual Digital Timer 90-250Vac2。

Rosemount 3490 Series Rosemount 3490 SeriesProduct Data Sheet00813-0100-4841, Rev. AACatalog 2008 - 2009Rosemount 3490 SeriesAccessories-2INTRODUCTIONThe 3490 series of wall and panel mount control units provide comprehensive control functionality for any 4-20mA or HART compatible transmitter.Mounted in a non-hazardous area, the 3490 provides a protected (IS) 24V dc power supply to a transmitter that may be installed in a hazardous area.A back-lit display gives clear visual indication of the measured value and status of all inputs and outputs.The 3490 is configured and interrogated using an integral 6 button keypad and an easy to navigate menu structure (page Accessories-4).Many popular configurations are “Wizard assisted”, enabling fast and accurate programming (page Accessories-7).The HART digital or 4-20mA analog signal from the transmitter may be offset, dampened, scaled, and linearized as required. A range of pre-programmed linearization algorithms are user selectable.Typical measurements include level, volume and distance measurement, as well as open channel flow measurement in wide range of flumes and weirs.The 4-20mA output signal may also be scaled to re-transmit all or just part of the input signal or calculated value.Five relays are provided and are fully fieldprogrammable to perform a wide variety of control, fault indication or alarm duties.(Typical Display of Model 3491)FEATURES AND APPLICATIONS•Accepts any 4-20mA or HART compatible input, allowing standardization of control room layout.•Tough polycarbonate NEMA4X or IP65 wall mount enclosure options for internal or external mounting.•Control units are 115/230V ac powered or 24V dc powered. Both versions provide an Intrinsically Safe 24V dc power supply to the transmitter. •Supports two voltage-free contact closure inputs, allowing override of control functions on external triggers.•Pre-programmed tank shapes, flow algorithms and pump control routines simplify configuration. • A 20-point user programmable facility is provided for non-standard applications.•Real time clock allows energy saving routines and pump efficiency calculations.•Five voltage-free SPDT (SPCO) relays for alarm and control duties.•4-20mA 12-bit isolated current output proportional to calculated value.•Clear visual display of measured value with units and relay status. Also used to guide user through programming menu.•Wizard assisted programming, with password protection to prevent unauthorized access. •3492 model also accepts input from two transmitters and performs sum or differential calculations, providing a single current output proportional to the answer.•3493 model also provides on-board logging of PV and totalized flow values in flow measurementapplications4 direction keys allow navigation around the programming menu4 line back-lit displayReturn to previous screenConfirms data entryRelay statusDigital input statusDigital Communication Status On-line statusBar graph of 4-20mA outputMeasured variableProduct Data Sheet00813-0100-4841, Rev. AA Catalog 2008 - 2009Accessories-3Rosemount 3490 SeriesTRANSMITTER CAPABILITYWhen a Rosemount 3100 Series or 3300 Series (non-explosion proof version) HART transmitter is connected, the 3490 will recognize the transmitter, allow selection of variables to be processed, and allow full access to and programming of thetransmitter configuration parameters, eliminating the need for any other HART programming device.Any other HART transmitter can be connected to the 3490. In this case, the 3490 will recognize thetransmitter as an "unknown instrument" and will allow access to and programming of the Universal and Common Practice HART commands.3490 Control Units will operate with any 2 wire 4-20mA transmitter, providing power to the loop. In the case of I.S. transmitters mounted in hazardous areas, the power supply is fully protected and there is no need for any external I.S. barrier.3492 DIFFERENTIAL LEVEL SYSTEMIt is sometimes necessary to know the difference in two levels, for example, across an inlet screen where the level difference is an indicator of the state of thescreen.The Rosemount 3492 differential level system is designed to operate with two HART leveltransmitters, and can be programmed to performcalculations on the two input signals –•Level, volume, or flow under transmitter 1 •Level, volume, or flow under transmitter 2 •Level difference between transmitter 1 and 2 •Sum of the level, volume, or flow under both transmitters The control relays and current output can be driven by any of these functions, and the display can be configured to show the reading of each transmitter plus either the difference or the sum of the readings. The transmitters used in this application are fully HART compliant, and are connected in parallel on a simple two-wire bus.3493 FLOW LOGGING SYSTEMIn many instances, it is required that the flow and totalized flow be logged for download at a later date.The Rosemount 3493 flow logging system has an on-board logger which can log up to 7000 samples at user definable intervals.In the event of flow exceeding a customer specified limit value, fast logging is automatically triggered until the flow reverts to normal.In addition, 365 daily totalized flow values are also logged along with the maximum instantaneous flow during each 24 hour period.A second totalizer is provided to totalize cumulative flow through the flow structure.All data is real time stamped and stored for download via an RS232 connection on the 3493 control unit. Data can be collected using a portable PC, and is easily stored and manipulated using windows-based software.34903100Product Data Sheet00813-0100-4841, Rev. AACatalog 2008 - 2009Rosemount 3490 SeriesAccessories-4THE MENU SYSTEMThe integral menu system is entered from thePrimary Display by using the red (Enter) button on the front panel keypad.Here you will find the top-level of a hierarchical menu structure, which is organized like a tree structure.This top level menu, known as the MAIN MENU, leads to further menus (branches), and these sub-menus lead to application parameters.Navigation from menu option to menu option is by using the arrow-buttons.Selecting a menu option is by using the red (Enter) button when the option is highlighted.The MAIN MENU leads to SETUP and MONITOR menus for configuring and viewing applicationparameters of the 3490, and one or two (depending on the model) HART transmitters.The 3490’s SETUP menu leads to control unit parameters for:•Duty selection e.g. open channel flow.•Setting up inputs.•Setting up outputs.•Logging (on model 3493).•Totalizing(including daily totalizer on model 3493).•RS232 Communications(for data logging on model 3493).•Operational parameters.Menu options vary between different models of the 3490 Control Unit.Similarly, the transmitter SETUP menu leads totransmitter specific parameters. Actual menu options vary between the different HART transmitters.The 3490’s MONITOR menu leads to control unit parameters for:•Primary Value (as seen on typical 3491 display).•Secondary Value (SV), Tertiary Value (TV), andFourth Value (FV)•Totalizer Values.•Relay data.•Alarm and Fault Reports.•Diagnostic data.Similarly, the transmitter MONITOR menu leads to transmitter specific parameters. Actual menu optionsvary between the different HART transmitters.(3492 screens shown with Rosemount 3102 transmitters)(3492 screens shown with Rosemount 3102 transmitter)Product Data Sheet00813-0100-4841, Rev. AA Catalog 2008 - 2009Accessories-5Rosemount 3490 SeriesABOUT PARAMETERSUpon entering a parameter screen, it is in View Mode (Figure 1).Figure 1.Guidance for what to do now is on the Display Line 4. On parameter screens, the ESC button returns you to the previous menu, and the red (Enter) button will enter Edit Mode or start an activity.Figure 2.The “0” is highlighted (reverse video) to show this digit can now be edited (Figure 2). Also, note that on Display Line 4, "Edit" has changed to be "Save".You can press the ESC button at any time to quit editing and return to View Mode. This will also restore the original setting.Use the RIGHT-ARROW button once to highlight the digit to the right, in this case “5”. (The LEFT-ARROW button is for moving left).Use the UP-ARROW button to scroll through 0-9, and a decimal point. (The DOWN-ARROW button scrolls down through the numbers). Similarly, when a parameter has a multiple-choice list of options, the arrow buttons scroll through these options. Figure 3.Press the red (ENTER) button to save the new date and return to View Mode, and then press the ESC button to return to the menu.OTHER FEATURES On-line / Off-line ModesAn open padlock icon indicates the 3490 is presently in the off-line mode . In this mode, the unit can be programmed providing that you know the security PIN (if set-up). Additionally in off-line mode, the 4-20mA output is frozen and all relays are frozen unless allocated to totalizing and sampler duties. Fault relays are de-energized.A closed padlock icon indicates that the 3490 is presently in the on-line mode . In this mode, most of the unit cannot beprogrammed. However, you will be prompted to go off-line if you attempt to programme whilst in this mode and providing that you know the security PIN (if set-up).Additionally in on-line mode, the 4-20mA output and all relays are enabled.PIN SecurityPersonal Identification Number (PIN) securityprevents unauthorized people from programming the 3490 Series Control Unit. Typically, this is set-up when all the other programming has beencompleted. As with bankcards, there is one PIN number.Relay StatesRelay outputs 1 to 4 are normally On Point / Off Point control relays which may be used to start/stop pumps or open/close valves at different levels. Theynormally energize at one level and de-energize at a different level.Alternatively, they can be programmed as out-of-limit alarms; they de-energize between defined points and will energize outside those points. On models 3491 and 3492, they may also be programmed to perform a variety of auto-sequences and auxiliary functions, such as pump-down operations, pump rotations to equalize wear, and de-sludge/cleaning.Relay output 5 is normally a fail safe fault relay but may be re-allocated to another duty.The relay status icons on the primary display have the following meanings:o = de-energized, = energized, A = Alarm duty,S = Sampler duty, T = Totalizing duty.Product Data Sheet00813-0100-4841, Rev. AACatalog 2008 - 2009Rosemount 3490 SeriesAccessories-6Display Configuration OptionsThe factory default configuration of the display can be changed to show different graphic and text information. Three areas of the display can be re-configured:•Upper display •Middle display •Lower displayAlarmsThe 3490 can detect the following alarm conditions:•Primary Value out-of-limits.•Current Output saturated•Logging memory filling (model 3493 only).•Logging memory full (model 3493 only).•Current Input saturated.•Rising liquid level.•Relay alarms.•Low pump efficiency (models 3491/3492 only).Digital Inputs IN1 and IN2Digital inputs IN1 and IN2 can be individually set-up to perform an action whenever they are activated:•Raise an alarm.•Go Offline.•Freeze totalizer.•Freezer Primary Value.•Suppress alarms.•Display Message.•Log Input.•Start pump-down.•Lock parameters.•Protect totalizer.•Reset totalizer.Product Data Sheet00813-0100-4841, Rev. AA Catalog 2008 - 2009Accessories-7Rosemount 3490 SeriesSET-UP PROCEDUREThe set-up procedure is simplified by easy-to-use Wizards. By following a sequence of on-screenprompts, an individual function or a large applicationcan be easily set-up without fuss.TOTALIZER WIZARDLOGGING WIZARDDUTY WIZARD There is a collection of Wizards for most functions and applications. They are selected and started through the integral menu system.•DUTY Wizard.•TOTALIZER Wizard.•LOGGING Wizard.•RELAY Wizard.•TRANSMITTER (Find/Remove) Wizard.Product Data Sheet00813-0100-4841, Rev. AACatalog 2008 - 2009 Rosemount 3490 SeriesAccessories-8TECHNICAL SPECIFICATIONProduct Rosemount 3490 Series Universal Control Unit:3491 - Standard Control Unit3492 - Differential Control Unit3493 - Logging Control UnitMounting styles Wall mount or Panel mountPower options AC Mains or DCType Dot matrix LCD, 32 x 122 pixels, back litLocation Integrated into enclosureIndicators Red LED for health statusAC Mains Power Supply Input115V or 230V ac ±10% (switch selectable).Power consumption: 10VA nom., 18VA maximum.Fuse: 200mA(T), 5 x 20mm, 250VDC Power Supply Input15-30V dc, 30Vdc maximum.Power consumption: 9W maximum.Current Input4-20mA (Earth referenced in control unit) or HART digital communications (Rev. 5)Supplies 23 volts from 400 Ohm source resistance.Trigger Inputs 2 voltage-free contact closures.Current Output Signal range (nominal): 4-20mAOutput range (linear):3.8 - 20.5mA.(Alarm current of 3.6mA, 21mA, or 22.5mA - user-selectable) or3.9 - 20.8mA.(Alarm current of 3.75mA, or 21.75mA - user-selectable)Load: Rmax is 1 K OhmResolution: 12-bitRegulation: < 0.1% over load change from 0 to 600 OhmsIsolation: Isolated from other terminals to 500V dcUpdate rate (software): 5 times per secondRelays 5 SPDT (SPCO), 5A at 240V acCable entry IP-rated wall mount enclosure:5 positions pre-drilled, 2 glands and 3 blanking plugs supplied.NEMA4X-rated wall mount enclosure:Positions require drilling by user, glands/conduits and blanking plugs are not supplied.Panel enclosure:Direct wiring to terminal blocks at rear.Cable connection Wall mount enclosure:Cage clamp terminal blocks in separate terminal compartment.Panel mount enclosure:2-part cage clamp terminal blocks at rear.Materials of construction (wall mount)Polycarbonate enclosure and cover.IP-rated wall mount: 304SST cover fixing screws.NEMA4X-rated wall mount: Polyester and monel fastening.UV resistant Polycarbonate membrane keypad.Nylon cable glands and blanking plugs (IP-rated wall mount version only).Materials of construction (panel mount)Polycarbonate enclosure and cover.Carbon Steel / Zinc plated fascia fixing screwsUV resistant Polycarbonate membrane keypadNylon + PBT terminal blocks with plated fittingsDimensions See Dimensional drawings on page10, page Accessories-11, andpage Accessories-12.Product Data Sheet00813-0100-4841, Rev. AA Catalog 2008 - 2009Accessories-9Rosemount 3490 SeriesWeightIP-rated wall mount: 1.4kg (mains unit) or 1.0kg (DC unit)NEMA4X-rated wall mount: 3.5kg (mains unit) or 3.1kg (DC unit)Panel mount 1.2kg (mains unit) or 0.8kg (DC unit)Ambient temperature -40 °C to +55 °C (-40 °F to + 131°F) (1)Relative humidity Wall mount: 100%Panel mount: 90% non-condensing Electrical safety EN61010-1Ingress protectionIP-rated wall mount: IP65 indoor/outdoor.NEMA4X-rated wall mount: NEMA 4X indoor/outdoor.Panel mount: IP40 indoor mount (or IP65 if with optional hood).VibrationControl Room: 0.1 - 200Hz, 0.5g acceleration.Field Mounted: 0.1 - 200Hz, 1.0g acceleration, 200 - 2000Hz, 0.5g acceleration.Installation categoryIII : Supply voltage < 127Vac - IEC60664II : Supply voltage < 254Vac - IEC60664Pollution degree 2 - IEC60664Maximum altitude2000 metresElectromagnetic compatibility Emissions and Immunity (for IP-rated wall mount and panel mount):IEC 61326:2002 (EN61326:1997+A1+A2+A3).CertificationsCE-mark, ATEX, IECEx, CSA, or UL - dependent on order code.(1)See Product certifications on page 13 for approval temperatures ranges.Product Data Sheet00813-0100-4841, Rev. AACatalog 2008 - 2009 Rosemount 3490 SeriesAccessories-10DIMENSIONAL DRAWINGSFigure 4. Dimensions for IP-rated Wall Mount BoxFigure 5.Dimensions for NEMA4X-rated Wall Mount BoxAccessories-11Figure 6. Dimensions for Panel MountAccessories-12PRODUCT CERTIFICATIONSEuropean Directive InformationThe EC declaration of conformity for all applicable European directives for this product can be found on the Rosemount website at . A hard copy may be obtained by contacting your local sales office.ATEX Directive (94/9/EC)Complies with the ATEX Directive.Low Voltage Directive (2006/95/EC)EN61010 Part 1 : 2001Pressure Equipment Directive (PED) (97/23/EC) Control Unit is outside the scope of PED Directive. Electro Magnetic Compatibility (EMC) Directive EN61326 (1997) amendments A1, A2, and A3 (Industrial locations, Class A)CE-markComplies with applicable directives:3401, 3402, and 3403 (EMC, ATEX, LVD) Restriction of Hazardous Substances (ROHS) 3490 Series Control Unit is exempt.Hazardous Locations CertificationsATEX Intrinsically Safe ApprovalI1 Certificate Numbers:SIRA 06ATEX7128 (Wall Mount),SIRA 06ATEX7129X (Panel Mount)Intrinsically Safe for II(1) G D, [EEx ia] IICAmbient Temperature: -40°C to +55°CUo = 27.3 V, lo = 96.9 mA, Po = 0.66 W,Li = 0.22 mH, Ci = 0.6 nFSpecial conditions for safe use(Certificate SIRA 06ATEX7129X):1.Terminal 30 must be earthed in the safe area to ahigh integrity earth .Underwriters Laboratories Inc. (UL)Intrinsically Safe ApprovalI5 Project IDs: E308780, E308781Intrinsically Safe for:Class I, Division 1, Groups A, B, C, DIntrinsically Safe for:Class 1, Zone 0, Group IICAmbient Temperature: -40°C to +55°CControl Drawing: 71097/1210Uo = 27.3 V, lo = 96.9 mA, Po = 0.66 W,La = 2.26 mH, Ca = 70 nFCanadian Standards Association (CSA) Intrinsically Safe ApprovalI6 Project ID: 1834150Intrinsically Safe for:Class I, Division 1, Groups A, B, C, and DIntrinsically Safe for:Class 1, Zone 0, Group IIC [Ex ia]Ambient Temperature: -40°C to +55°CControl Drawing: 71097/1201Uo = +27.3 V, lo = 96.9 mA, Po = 0.66 W,La = 2.26 mH, Ca = 70 nFIECEx Intrinsically Safe ApprovalI7 Certificate Number: IECEx SIR 06.0104X Intrinsically Safe for:Zone 0, 20, [Ex ia] IIC, [Ex iaD 20]Ambient Temperature: -40°C to +55°CUo = +27.3 V, lo = 96.9 mA, Po = 0.66 W,Li = 0.22 mH, Ci = 0.6 nFConditions of Certification (Panel Mount):1.Terminal 30 must be earthed in the safe area to ahigh integrity earth .Accessories-13ORDERING INFORMATIONModel Code 3491, Standard Control Unit 3491Model 3491 Standard Control UnitL4-20 mA1115/230 Vac224 VdcP4Wall mounting, NEMA 4XP6Wall mounting, IP65P7Panel mountingI1ATEX Intrinsically SafeI5UL Intrinsically Safe (1)(2)I6CSA Intrinsically Safe (3)I7IEC Ex Intrinsically Safe(1)Enclosure/Mounting code P4 is required for this option.(2)Power supply code 1 is required for this option.(3)Enclosure/Mounting codes P4 or P7 are required for this option. Example model order code: 3491-L-1-P4-I5Accessories-14Model Code 3492, Differential Control Unit3492Model 3492 Differential Control UnitL4-20 mA1115/230 Vac224 VdcP4Wall mounting, NEMA 4XP6Wall mounting, IP65P7Panel mountingI1ATEX Intrinsically SafeI5UL Intrinsically Safe (1)(2)I6CSA Intrinsically Safe (3)I7IEC Ex Intrinsically Safe(1)Enclosure/Mounting code P4 is required for this option.(2)Power supply code 1 is required for this option.(3)Enclosure/Mounting codes P4 or P7 are required for this option.Example model order code: 3492-L-1-P4-I5Accessories-15Model Code 3493, Logging Control Unit 3493Model 3493 Logging Control UnitL4-20 mA1115/230 Vac224 VdcP4Wall mounting, NEMA 4XP6Wall mounting, IP65P7Panel mountingI1ATEX Intrinsically SafeI5UL Intrinsically Safe (1)(2)I6CSA Intrinsically Safe (3)I7IEC Ex Intrinsically Safe(1)Enclosure/Mounting code P4 is required for this option.(2)Power supply code 1 is required for this option.(3)Enclosure/Mounting codes P4 or P7 are required for this option. Example model order code: 3493-L-1-P4-I5Accessories-16Accessories-17Standard Terms and Conditions of Sale can be found at \terms_of_sale The Emerson logo is a trademark and service mark of Emerson Electric Co.Rosemount and the Rosemount logotype are registered trademarks of Rosemount Inc.All other marks are the property of their respective owners.。