Teledyne 2002 Pirani Sensor, Et = Es + Er + Eg, Es = K ∆T Am/L, Er = σεTh4-Ta4As

Page 24

5.2 Pirani Sensor

Figure 5.3a shows a thin film Pt resistive element on a one micron thick Si3N4 continuous mem- brane surrounded by a thin film Pt reference resistor on a Si substrate. The membrane is heated to a constant 80C above ambient temperature that is monitored by the substrate resistor. The membrane resistor is approximately 60 and a constant substrate to membrane resistance ratio is maintained at 3.86. Figure 5.3b shows the Pirani die in cross section. A parallel Si lid is eutectically bonded to the Au pads and sits 5 microns above the membrane. As shown, this dimension gives a Knudsen number of greater than 0.01 up to atmospheric pressure, which insures a molecular flow component. At 10 Torr the region above the membrane is totally in the molecular flow regime and thus provides a relatively linear output verses pressure overlapping the linear output versus pressure of the piezo.

The measurement technique is to produce an output signal that is proportional to the power supplied to the heated resistor by using the product of the current and voltage. This rejects errors introduced by resistance changes since the sensor resistance is no longer part of the power equation.

A signal proportional to the power is obtained by multiplying the voltage across the heated sensor and the voltage impressed by the direct current across a constant series resistance. The power supplied to the sensor resistor must equal the heat dissipated (Et). The three main heat loss routes from the heated sensor are thermal conduction through the silicon nitride membrane to the silicon substrate (Es) radiation losses (Er) and thermal conduction through the gas to the silicon substrate (Eg); thus, as shown in Figure 5.3c,

Et = Es + Er + Eg

The first term, Es, is dependent on the thermal conductivity of the silicon nitride (K), the tem- perature difference (T) between the heater and silicon substrate and geometric factors (AM & L). ES is given by

Es = (K T Am)/L

Am is the membrane cross sectional area through which the heat transfer occurs. This is, approxi- mately, the outer circumference of the membrane multiplied by the membrane thickness. L is the distance from the edge of (Rs) the heated sensor resistor to the silicon substrate.

For any particular sensor, all of the factors, except T, are constants dependent on its construc- tion. The T is held constant by the control circuit. The thermal loss through the silicon nitride will be a constant value independent of the thermal conductivity and pressure of the gas.

Radiation is another source of thermal losses. It can be determined from

Er = σε(Th4-Ta4)As

where

σ= Stefan-Boltzmann radiation constant

ε= thermal emissivity of the silicon nitride membrane

AS

= surface area of the heated portion of the membrane

Th

=

temperature of Rs

Ta

=

ambient temperature

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Contents Teledyne Hastings Manual Print History Table of Contents 4-20mA Interface Option Board Volt Interface12.0 Features General InformationModel 2002 Sensors Specifications Model 2002 Control UnitInstallation Receiving InspectionQuick Start Transducer Installation Control Unit Installation EnvironmentPanel Mount Instructions Transducer Cable AttachmentFront Panel Operation Overall Functional DescriptionModel Control Unit Front Panel RUN Mode Normal Operation Speed AdjustScientific Notation CAL Mode Eeprom Calibration RestorationHigh and LOW Set Point Modes Maintainance and Repair Zero Coefficient Adjustment Midrange Coefficient AdjustmentAtmosphere Coefficient Adjustment GAS ModeUnits Mode Default Calibration RestorationThis page was intentionally left blank Rear Panel Description Remote Zero InputAnalog Output Voltage to pressure conversion example Model 2002 Analog Output TTL OutputsPower Entry Module Model Rear Panel DetailTheory of Operation Piezoresistive SensorVo = SPV+V1 View A-A Pirani Sensor Et = Es + Er + EgEs = K ∆T Am/L Er = σεTh4-Ta4AsPage Eg = Kg ∆T As/∆x = a L 273/T 1/2T -T a PDual Sensor Operation Model Dual Sensor Vacuum Gauge 28 Model RS-232-E Interface Specifications Communications Option BoardInterface Connector Pin Assignments for RS-485 For RS-485 Half Duplex 2 wireCommand Syntax Interrogation CommandsParameter Modification Commands Calibration Adjustment CommandsReset / Restore Commands Device Status Digit#Relay Board Specifications Relay Interface Option BoardRelay Connector Pin Assignment Operation MA Interface Option Board Channel 0-10V Interface Connector Pin Assignmets 10V Interface Option BoardVchannel 1 = PTorr 100 Vchannel 2 = PmTorr Troubleshooting Guide 42 Model Warranty and Repair Warranty Repair PolicyNon-Warranty Repair Policy 44 Model Diagrams and Drawings Mini Conflattm HPM-2002-03 KF-16 HPM-2002-05KF-25 HPM-2002-06 NPT HPM-2002-01 O.D. Smooth Tube HPM-2002-07VCR HPM-2002-02 4 Conflattm HPM-2002-04Model Out Line Dimensions Panel Cut-Out DimensionsPanel Mounting Mounting Clip Attachment50 Model Model 2002 52 Model Model 2002 54 Model
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2002 specifications

Teledyne 2002 represents a significant advancement in the realm of sophisticated instrumentation and systems used across various industries. This innovative platform emerged as a versatile solution for a multitude of applications including environmental monitoring, industrial automation, and scientific research.

One of the most notable features of the Teledyne 2002 is its robust data analysis capability. Equipped with powerful processing units, it allows users to conduct real-time data analysis, ensuring accurate and timely results. This is particularly beneficial in fields where immediate decision-making is crucial, such as environmental assessments and industrial quality control.

The technology behind the Teledyne 2002 encompasses a variety of sensors and analytical instruments. Its modular design enables users to customize the system according to their specific needs, integrating various sensors such as gas analyzers, spectrometers, and temperature sensors. This flexibility makes the Teledyne 2002 applicable in diverse settings, from laboratory environments to rugged field conditions.

Another characteristic of the Teledyne 2002 is its user-friendly interface. The system is designed with an intuitive control panel and advanced software that provides comprehensive data visualization. This ease of use enhances productivity, allowing operators to facilitate complex analyses without extensive training.

Security and data integrity are also focal points of the Teledyne 2002. The system implements state-of-the-art encryption protocols to protect sensitive data. Moreover, it maintains compliance with industry standards, ensuring that the collected data is reliable and trustworthy.

In addition to its technological features, the Teledyne 2002 is built with durability in mind. The rugged construction allows it to withstand harsh environmental conditions, making it ideal for outdoor applications. Its compact design enables easy transportation, which is essential for fieldwork.

Moreover, the Teledyne 2002 includes connectivity options that facilitate seamless integration with existing systems. It can connect to cloud services, enabling remote monitoring and data storage. This feature not only enhances the functionality of the device but also allows for collaborative data sharing among teams.

Overall, the Teledyne 2002 symbolizes a convergence of advanced technology, user-centric design, and robust performance. With its extensive features and versatility, it stands out as a premier solution for professionals demanding precision and reliability in their analytical endeavors. Whether for environmental monitoring or industrial applications, the Teledyne 2002 is equipped to meet the challenges of modern data analysis.
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