带有细线传感元件的热电偶动态特性预测

IF 0.2 Q4 INSTRUMENTS & INSTRUMENTATION
I. A. Safina, S. A. Artemyeva
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An approximate formula is also given for calculating the internal resistance of wire sensing elements of thermocouples, which must be considered when calculating the time constant of a thermocouple. In consideration of the obtained formulas, a multi-parameter relation linking the current or expected time constant of fine-wire thermocouples with the known time constant set at the known parameters of the measured media has been formed.It is suggested to simplify the formed multi-parameter relation and make it dependent, for example, on the “expected velocity of the measured medium × expected density of the measured medium” complex (Vm2 ρm2 ). Simplified relations in the form of hyperbolic functions with constant parameters and argument in the form of Vm2 ρm2 complex were obtained for airflowat different temperatures, pressures, and velocities.On the example of airflow, it is shown that the complex multi-parametric relation linking the expectedand known time constants of thermocouples can be simplified to a hyperbolic dependence, where the argument can be the Vm2 ρm2 complex. Moreover, the degree of approximation of hyperbolic dependencies to the exact values of the multi-parametric relation can reach the R-square = 0.9592 criterion.A multi-parametric relation has been proposed. That relates the known time constant of a thermocouple to the expected or current time constant of the same thermocouple at other parameters of the measured medium from the point of view of the heat exchange and thermal conduction theory. 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引用次数: 0

摘要

热电偶动态特性预测是液体和气体介质非稳态温度动态测量领域的相关方向之一。热电偶动态特性的预测可以为非平稳温度的自动控制系统提供有效的连续校正。本文的目的是建立一种理论上合理的关系,将细线热电偶的电流或预期时间常数与已知的液体和气体介质参数下的已知时间常数联系起来。推导了细线热电偶时间常数与被测介质热交换条件和热电偶感测元件热物理特性之间的关系式。给出了计算热电偶线感测元件内阻的近似公式,这是计算热电偶时间常数时必须考虑的问题。根据所得公式,建立了细线热电偶电流或期望时间常数与被测介质已知参数下的已知时间常数之间的多参数关系。建议将形成的多参数关系简化,使其依赖于“被测介质的期望速度×被测介质的期望密度”复数(Vm2 ρm2)。在不同温度、压力和速度下,得到了常参数双曲函数形式和Vm2 ρm2复形形式的简化关系。以气流为例,表明热电偶的期望时间常数和已知时间常数之间的复杂多参数关系可以简化为双曲关系,其中参数可以是Vm2 ρm2复合体。此外,双曲依赖性对多参数关系精确值的逼近程度可以达到r方= 0.9592准则。提出了一种多参数关系。从热交换和热传导理论的角度,将已知热电偶的时间常数与同一热电偶在被测介质的其他参数下的期望或电流时间常数联系起来。该关系式可用于各种液体或气体介质的非稳态温度自动控制系统,以提供对热电偶动态特性的连续校正。根据被测介质参数的数量,建议的多参数关系可以被包含被测介质的密度、速度、流量和压力等其他复合物的简化关系所取代。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Prediction of Dynamic Characteristics of Thermocouples with Thin-Wire Sensing Elements
Thermocouples dynamic characteristicsʼ prediction is one of the relevant directions in the field of dynamic measurements of non-stationary temperatures of liquid and gaseous media. Thermocouples dynamic characteristicsʼ prediction makes it possible to provide effective continuous correction in automatic control systems for non-stationary temperatures. The purpose of this paper was to develop a theoretically justified relation linking the current or expected time constant of fine-wire thermocouples with the known time constant established at known parameters of liquid and gaseous media.A formula linking the time constant of fine-wire thermocouples with the conditions of heat exchange with the measured medium and the thermophysical characteristics of the thermocouple sensing elements has been deducted. An approximate formula is also given for calculating the internal resistance of wire sensing elements of thermocouples, which must be considered when calculating the time constant of a thermocouple. In consideration of the obtained formulas, a multi-parameter relation linking the current or expected time constant of fine-wire thermocouples with the known time constant set at the known parameters of the measured media has been formed.It is suggested to simplify the formed multi-parameter relation and make it dependent, for example, on the “expected velocity of the measured medium × expected density of the measured medium” complex (Vm2 ρm2 ). Simplified relations in the form of hyperbolic functions with constant parameters and argument in the form of Vm2 ρm2 complex were obtained for airflowat different temperatures, pressures, and velocities.On the example of airflow, it is shown that the complex multi-parametric relation linking the expectedand known time constants of thermocouples can be simplified to a hyperbolic dependence, where the argument can be the Vm2 ρm2 complex. Moreover, the degree of approximation of hyperbolic dependencies to the exact values of the multi-parametric relation can reach the R-square = 0.9592 criterion.A multi-parametric relation has been proposed. That relates the known time constant of a thermocouple to the expected or current time constant of the same thermocouple at other parameters of the measured medium from the point of view of the heat exchange and thermal conduction theory. The proposed relation can be used in automatic control systems of non-stationary temperature of various liquid or gaseous media to provide continuous correction of thermocouples dynamic characteristics. Depending on the number of measured medium parameters, the suggested multi-parameter relation can be replaced by simplified relations with other complexes containing, for example, density, velocity, flow rate and pressure of the measured medium.
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来源期刊
Devices and Methods of Measurements
Devices and Methods of Measurements INSTRUMENTS & INSTRUMENTATION-
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