Fluke 2470 specifications Reference Plane Determination

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RUSKA 2470

Users Manual

It is common practice to associate this position directly with the piston as the datum to which all measurements made with the piston are referenced. It is called the reference plane of measurement, and its location is determined from the dimensions of the piston. If the submerged portion of the piston is of uniform cross section, the reference plane is found to lie conveniently at the lower extremity as shown in 2-4. If, however, the portion of the piston submerged is not uniform, the reference plane is chosen at a point where the piston, with its volume unchanged, would terminate if its diameter were uniform.

The reference plane of the standard is the effective bottom of the measurement piston. This location can be correlated to the index on the mass stack using the L1 dimension (found on Calibration Report for the Piston/Cylinder) and the D Dimension (found on Calibration Report for the Mass set).

glg02.bmp

Figure 2-4. Reference Plane Determination

When a pressure for the piston pressure gauge is calculated, the value obtained is valid at the reference plane. The pressure at any other plane in the system may be obtained by multiplying the distance of the other plane from the reference plane by the pressure gradient and adding (or subtracting) this value to that observed at the piston reference plane.

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Contents Ruska Limited Warranty and Limitation of Liability Table of Contents Appendices List of Tables Ruska List of Figures Ruska Introduction How to Contact FlukeSafety Information Compressed GasLubricants and Seals Symbols Used in this ManualHeavy Weights Oxygen CompatibilitySpecifications Low Range PistonAccuracy Humidity RangeGeneral Piston Pressure Gauge Considerations Types of Piston Pressure GaugesControlled Clearance Cylinder Calculations Measurement of Pressure with the Piston Pressure GaugeElastic Distortion of the Cylinder GravityBuoyant Effect of the Air Temperature Reference Plane of MeasurementsReference Plane Determination Is the density of the test media Crossfloating BibliographyGeneral Piston Pressure Gauge Considerations Ruska Description General InformationDescription of the Mass Set Description of the Gauge BaseDescription Ruska Installation IntroductionAlways remove the thermometer before shipping the gauge base Installation Ruska Precautions OperationLow Range Piston Assembly GeneralOperation 24-580 Bearing 2460-4-25 2460-5-6 Handling the Low Range Piston and Cylinder Step Low Range Piston and Cylinder Showing O-Ring Groove Mid Range Piston Assembly Section View, Mid Range Piston/Cylinder Thrust Cylinder Assembly Spacer Bearing 2460-70-2 2460-70-3 High Range Piston Assembly 11. Retaining Nut and Bearing12. Section View, High Range Piston/Cylinder 13. Parts Required for High Range Piston Operation Establishing Pressure Gauge PressuresAutomating the Calculations and Data Storage 16. Float PositionMaintenance of the Gauge LeaksRuska Piston / Cylinder Cleaning Instructions General Information and PreparationFunctional Testing of Piston/Cylinder Assemblies Cleaning the Low Range Piston/Cylinder AssemblyPiston / Cylinder Cleaning Instructions Preparations for Cleaning the Low Range Cylinder Preparing the Low Range Cleaning Tool Step Materials for Cleaning the Mid Range Piston/Cylinder Mid Range Piston/CylinderPreparing the Mid Range Cleaning Tool Cleaning the High Range Piston/Cylinder Assembly Materials for Cleaning the High Range Piston CylinderCleaning the High Range Piston/Cylinder Assembly Gmq33.bmp 13. Cleaning the High Range Cylinder 14. Drying the High Range Cylinder Explanation of Pressure Calculation Worksheet Temp. Coef. x actual temperature expected temperature For English UnitsK2 = 1/ g1 1 − ρa / ρb For SI UnitsAe t Explanation of Pressure Calculation Worksheet a Ruska Date Ruska Expected Temperature, t Ruska Nitrogen Density English Units 0 to 1000 Psig Equation A-4 Air DensityEquation A-4 Air Density Nitrogen Density English Units 1,000 to 15,000 PsigZero Air Density SI Units 0 MPa to 20.7 MPa Nitrogen Density SI Units 0 to 6.9 MPaNitrogen Density SI Units 6.9 MPa to 100 MPa Helium Density SI Units 0 to 6.9 MPaConversion Factors Table B-1. Conversion Factors To Convert From Multiply ByRuska Glossary GlossaryDUT +INF, -INF Pressure Factor Sink Rate Ruska

2470 specifications

The Fluke 2470 is a versatile and highly regarded data acquisition system designed for a wide range of applications in electrical testing and measurement. Known for its precision and reliability, the Fluke 2470 is particularly popular among professionals who require accurate data for analysis and reporting.

One of the standout features of the Fluke 2470 is its high-performance data acquisition capabilities. It supports multiple channel inputs, allowing users to monitor and log various electrical parameters simultaneously. This multi-channel functionality is essential for complex testing scenarios where multiple variables must be tracked in real time.

The Fluke 2470 utilizes advanced measurement technologies, including a high-resolution analog-to-digital converter that ensures superior measurement accuracy. This technology is crucial for applications that demand precise readings, such as research and development, quality assurance, and compliance testing.

Additionally, the device is equipped with a variety of input types, including voltage, current, and temperature, making it suitable for a wide array of testing applications. The flexibility in input compatibility allows users to customize their measurements according to specific project requirements.

Another significant characteristic of the Fluke 2470 is its user-friendly interface and software integration. The accompanying software enables users to configure measurements easily, set up logging intervals, and analyze data visually. This intuitive setup minimizes the learning curve for new users and enhances productivity.

Data storage is another critical feature of the Fluke 2470. It provides ample internal memory, allowing users to record extensive datasets over long periods without the need for continuous monitoring. The stored data can be easily exported for further analysis, making it ideal for long-term testing projects.

Moreover, the Fluke 2470 excels in terms of portability and ruggedness. Its compact design is built to withstand demanding environments, ensuring that it can deliver accurate data in the field just as reliably as in the lab.

In conclusion, the Fluke 2470 combines high-performance data acquisition, multi-channel capabilities, advanced measurement technologies, and user-friendly features, making it a top choice for professionals in a variety of fields. Its robust design ensures that it meets the demands of rigorous testing while providing accurate and reliable data, crucial for informed decision-making.
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