Teledyne 3000TA operating instructions Zero Settling Man ENT To Begin

Page 57

Trace Oxygen Analyzer

Operation

 

 

 

The zeroing process will automatically conclude when the output is within the acceptable range for a good zero. Then the analyzer automatically returns to the Analyze mode.

4.4.1.2MANUAL MODE ZEROING

Press Zero to enter the Zero function. The screen that appears allows you to select between automatic or manual zero calibration. Use the ▲/▼ keys to toggle between AUTO and MAN zero settling. Stop when MAN appears, blinking, on the display.

Zero: Settling: Man

<ENT> To Begin

Press Enter to begin the zero calibration. After a few seconds the first of five zeroing screens appears. The number in the upper left hand corner is the first-stage zero offset. The microprocessor samples the output at a predetermined rate. It calculates the differences between successive samplings and displays the rate of change as Slope= a value in parts per million per second (ppm/s).

####ppm Zero

Slope=#### ppm/s

Note: It takes several seconds for the true Slope value to display. Wait about 10 seconds. Then, wait until Slope is sufficiently close to zero before pressing Enter to finish zeroing.

Generally, you have a good zero when Slope is less than 0.05 ppm/s for about 30 seconds. When Slope is close enough to zero, press Enter. In a few seconds, the screen will update.

Once span settling completes, the information is stored in the microprocessor, and the instrument automatically returns to the Analyze mode.

4.4.1.3CELL FAILURE

Cell failure in the 3000TA is usually associated with inability to zero the instrument down to a satisfactorily low ppm reading. When this occurs, the 3000TA system alarm trips, and the LCD displays a failure message.

 

 

 

Teledyne Analytical Instruments

45

Image 57
Contents Teledyne Analytical Instruments Model 3000TACopyright 2011 Teledyne Analytical Instruments 3000TA- EUTrace Oxygen Analyzer Specific Model InformationImportant Notice Safety Messages 3000TA- EU Vii Table of Contents Operation MaintenanceAppendix Model 3000TA Front Panel List of FiguresList of Tables Introduction Main Features of the AnalyzerOverview Typical ApplicationsIntroduction 3000TA- EU Model DesignationsModel 3000TA Front Panel Front Panel Operator InterfaceRecognizing Difference Between LCD & VFD ∙ 50-Pin Equipment Interface Port Rear Panel Equipment InterfaceIntroduction 3000TA- EU Introduction Operational TheoryMicro-Fuel Cell Sensor Trace Oxygen Analyzer Operational TheoryAnatomy of a Micro-Fuel Cell Operational Theory 3000TA- EUElectrochemical Reactions Effect of Pressure Calibration CharacteristicsSample System Characteristic Input/Output Curve for a Micro-Fuel CellPiping Layout and Flow Diagram for Standard Model Flow Diagram Electronics and Signal Processing3000TA Internal Electronic Component Location Block Diagram of the Model 3000TA-EU Electronics Operational Theory 3000TA- EU Trace Oxygen Analyzer Installation InstallationUnpacking the Analyzer Mounting the AnalyzerFront Panel of the Model 3000TA Installation 3000TA- EUGas Connections Rear Panel ConnectionsSample Electrical Connections Exhaust OUTEquipment Interface Connector Pin Arrangement ∙ Threshold Alarm Alarm Relay Contact Pins Pin Function Range ID Relay Connections 2.3 RS-232 Port Remote Probe ConnectionsCommands via RS-232 Input Testing the System Installing the Micro-Fuel CellPage Using the Data Entry and Function Buttons OperationTrace Oxygen Analyzer Operation Operation 3000TA- EU Hierarchy of Functions and Sub functions System FunctionTracking Oxygen Readings During Calibration and Alarm Delay TRAK/HLD Auto-Cal Pswd Logout More Setting up an Auto-Cal Password Protection A a a Characters Available for Password Definition Logout System Self-Diagnostic Test Showing Negative Oxygen Readings Version ScreenZero and Span Functions Zero Cal Zero Settling Man ENT To Begin Span Cal Span Val 000008.00 ENTSpan UPMod # #### % Span Slope=#### ppm/s Span Failure Alarms FunctionAL-1AL-2 Choose Alarm Range Function Setting the Analog Output Ranges Fixed Range Analysis Analyze Function Signal OutputMED Operation 3000TA- EU Teledyne Analytical Instruments Routine Maintenance MaintenanceTrace Oxygen Analyzer Maintenance Storing and Handling Replacement CellsMaintenance 3000TA- EU When to Replace a CellRemoving the Micro-Fuel Cell Removing the Micro-Fuel Installing a New Micro-Fuel CellMaintenance 3000TA- EU Cell Warranty Fuse ReplacementInstalling Fuses System Self Diagnostic TestMajor Internal Components Troubleshooting CleaningTrace Oxygen Analyzer Maintenance Maintenance 3000TA- EU Teledyne Analytical Instruments Model 3000TA Specifications AppendixTrace Oxygen Analyzer Appendix Appendix 3000TA- EU Recommended 2-Year Spare Parts ListOrders should be sent to 19-inch Relay Rack Panel Mount Drawing ListFlow Rate Recommendations Application notes3000TA Examples Bypass Conversions Material Safety Data Sheet Section I Product IdentificationSection II Physical and Chemical Data Section IV Health Hazard Data Appendix 3000TA- EU Section III -Physical HazardsSection VI Handling Information
Related manuals
Manual 19 pages 17.56 Kb

3000TA specifications

The Teledyne 3000TA is an advanced telemetry system designed for high-performance applications in various industries such as aerospace, automotive, and research. This innovative device combines cutting-edge technologies with user-friendly features, making it an essential tool for engineers and scientists alike.

One of the standout features of the Teledyne 3000TA is its robust data acquisition capabilities. It offers a high sampling rate, which allows users to capture rapid changes in measurements accurately. This is particularly beneficial for applications that require real-time data analysis and decision-making, such as testing the performance of new aircraft components or monitoring engine behavior under different loads.

The 3000TA integrates multiple sensor interfaces, enabling it to connect seamlessly with various types of sensors, including temperature, pressure, and strain gauges. This versatility makes it suitable for a wide range of testing scenarios, from structural analysis to environmental monitoring. Users can customize the system to fit their specific needs, significantly enhancing its functionality.

Another significant advantage of the Teledyne 3000TA is its advanced wireless communication technology. By employing protocols like Bluetooth and Wi-Fi, it allows for remote data monitoring and access, which improves safety and convenience during testing processes. Engineers can easily gather data from hazardous environments without being physically present, ensuring both efficiency and safety.

The device is also equipped with an intuitive user interface, which simplifies the setup and operation processes. The touchscreen display provides real-time data visualizations and easy navigation through various menus, making it accessible even to those new to telemetry systems. This user-centric design reduces the learning curve and enhances overall productivity.

In terms of data integrity, the Teledyne 3000TA features robust error-checking and validation protocols. These built-in safeguards ensure that the data collected is accurate and reliable, which is crucial for making informed decisions based on telemetry data.

The system's compact and lightweight design ensures portability, allowing for use in various fields and environments. This flexibility enhances its appeal for field applications, where space and weight can be significant constraints.

In summary, the Teledyne 3000TA stands out as a versatile and reliable telemetry solution, combining high-performance data acquisition, advanced communication technologies, and user-friendly features. Its application across multiple industries makes it an invaluable tool for professionals seeking to optimize their testing and analysis processes.