WO2011040634A1 - 熱流束計測装置、及び熱流束計測方法 - Google Patents
熱流束計測装置、及び熱流束計測方法 Download PDFInfo
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- WO2011040634A1 WO2011040634A1 PCT/JP2010/067399 JP2010067399W WO2011040634A1 WO 2011040634 A1 WO2011040634 A1 WO 2011040634A1 JP 2010067399 W JP2010067399 W JP 2010067399W WO 2011040634 A1 WO2011040634 A1 WO 2011040634A1
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- thermocouple
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- G—PHYSICS
- G01—MEASURING; TESTING
- G01K—MEASURING TEMPERATURE; MEASURING QUANTITY OF HEAT; THERMALLY-SENSITIVE ELEMENTS NOT OTHERWISE PROVIDED FOR
- G01K17/00—Measuring quantity of heat
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- G—PHYSICS
- G01—MEASURING; TESTING
- G01K—MEASURING TEMPERATURE; MEASURING QUANTITY OF HEAT; THERMALLY-SENSITIVE ELEMENTS NOT OTHERWISE PROVIDED FOR
- G01K17/00—Measuring quantity of heat
- G01K17/06—Measuring quantity of heat conveyed by flowing media, e.g. in heating systems e.g. the quantity of heat in a transporting medium, delivered to or consumed in an expenditure device
- G01K17/08—Measuring quantity of heat conveyed by flowing media, e.g. in heating systems e.g. the quantity of heat in a transporting medium, delivered to or consumed in an expenditure device based upon measurement of temperature difference or of a temperature
- G01K17/20—Measuring quantity of heat conveyed by flowing media, e.g. in heating systems e.g. the quantity of heat in a transporting medium, delivered to or consumed in an expenditure device based upon measurement of temperature difference or of a temperature across a radiating surface, combined with ascertainment of the heat transmission coefficient
Definitions
- the present invention relates to a heat flux measuring device and a heat flux measuring method for measuring a heat flux.
- Patent Document 1 describes a heat flux meter attached to an engine cylinder wall as a heat flux measuring device.
- a temperature measuring point of a pair of thermocouples is provided in a heat transfer body screwed into a screw hole in a cylinder wall of an engine.
- the temperature measuring points of the pair of thermocouples are provided at different positions in the thickness direction of the cylinder wall.
- the heat flux conducted through the cylinder wall in the thickness direction is measured by the temperature difference measured at the two temperature measuring points.
- thermocouple since the strand has a heat capacity, a response delay corresponding to the thickness of the strand occurs. Therefore, in the conventional heat flux measuring device, there are cases where sufficient time resolution cannot be obtained in the measurement of the heat flux.
- the present invention has been made in view of the above circumstances, and an object thereof is to improve time resolution in a heat flux measuring device and a heat flux measuring method for measuring a heat flux.
- a first invention uses a thermocouple to measure a temperature difference between a first measurement position and a second measurement position lower in temperature than the first measurement position, and a thermocouple of the first measurement section.
- a second is used to measure a temperature difference between a third measurement position that can be regarded as the same temperature as the first measurement position and a fourth measurement position that can be regarded as the same temperature as the second measurement position, using thermocouples having different time constants.
- thermocouple of at least one measuring unit A heat flux calculating unit that detects a time constant, calculates a temperature difference that compensates for a response delay of the measured temperature difference based on the detected time constant, and calculates a heat flux from the compensated temperature difference. It is a bundle measuring device.
- the measured temperature difference between the first measurement position and the second measurement position is obtained from the thermoelectromotive force of the thermocouple of the first measurement unit.
- An actually measured temperature difference between the third measurement position and the fourth measurement position is obtained from the thermoelectromotive force of the thermocouple of the second measurement unit.
- Each time differential value is obtained from the time change of each actually measured temperature value.
- the relational expression of the temperature difference that compensates for the response delay of each measured temperature difference (hereinafter referred to as the compensated temperature difference) is expressed using the measured temperature difference, the time differential value of the measured temperature difference, and the time constant as variables. (See Equations 1 and 2 below).
- the time constant of the thermocouple of the first measurement unit is different from the time constant of the thermocouple of the second measurement unit.
- the first measurement position and the third measurement position can be regarded as the same temperature
- the second measurement position and the fourth measurement position can be regarded as the same temperature. That is, the post-compensation temperature difference of the first thermocouple and the post-compensation temperature difference of the second thermocouple can be regarded as the same. Therefore, using these relationships, it is possible to calculate the time constant of each thermocouple. If the time constant of the thermocouple of at least one measurement unit is known, the compensated temperature difference is derived, and the heat flux is derived from the compensated temperature difference. In the first invention, the time constant can be detected by measuring at least two thermocouples having different time constants and measuring the temperature difference between the positions at which the temperature difference can be regarded as the same, so that the heat flow can be detected using the time constant. The bundle is calculated.
- the first measurement unit includes a first thermocouple in which a hot junction is provided at a first measurement position and a cold junction is provided at a second measurement position.
- the second measuring unit includes a second thermocouple in which a hot junction is provided at the third measurement position and a cold junction is provided in the fourth measurement position, and the time constants of the first thermocouple and the second thermocouple are mutually equal. Different.
- the first measurement unit includes a first high temperature side thermocouple in which a hot junction is provided at the first measurement position, and a hot junction in the second measurement position.
- the second measurement unit includes a second high temperature side thermocouple in which the hot junction is provided at the third measurement position and a second low temperature side in which the hot junction is provided at the fourth measurement position.
- a thermocouple, and the time constants of the first high temperature side thermocouple and the second high temperature side thermocouple are different from each other, and the time constants of the first low temperature side thermocouple and the second low temperature side thermocouple are different from each other.
- the first thermocouple is used to detect a temperature difference between the first measurement position and the second measurement position lower in temperature than the first measurement position, and at the same time, the first thermocouple has a time constant.
- a measurement step of detecting a temperature difference between a third measurement position that can be regarded as the same temperature as the first measurement position and a fourth measurement position that can be regarded as the same temperature as the second measurement position using a different second thermocouple Using the measured temperature difference obtained from the thermoelectromotive force of each thermocouple and the time differential value of the measured temperature difference of each thermocouple, the time constant of at least one of the thermocouples is detected.
- a heat flux measurement method comprising: a heat flux calculation step of calculating a temperature difference that compensates for a response delay of the measured temperature difference and calculating a heat flux from the compensated temperature difference.
- the time constant can be detected. I am trying to calculate.
- the value of the heat flux calculated from this time constant is an instantaneous value with no response delay. Since the response delay of the thermocouple of one measurement unit is compensated using the thermocouple of the other measurement unit, an instantaneous value of the heat flux can be obtained. Therefore, the time resolution of the heat flux measuring device or the heat flux measuring method can be improved.
- the thermal flow velocity measuring device 100 of the present embodiment includes a first measuring unit 110, a second measuring unit 120, a recording device 130, and a signal processing device 140.
- the first measurement unit 110 uses the first thermocouple 112 to measure the temperature difference between the measurement position A (first measurement position) and the measurement position B (second measurement position) lower than the measurement position A.
- the measurement positions A and B may be the surface of the measurement object or the inside of the measurement object.
- the first measurement unit 110 includes a first thermocouple 112 and a first differential thermometer 114.
- the first thermocouple 112 includes a first temperature measuring contact 116 and a second temperature measuring contact 118.
- the first temperature measuring contact 116 is arranged at the measurement position A
- the second temperature measuring contact 118 is arranged at the measurement position B.
- the first differential thermometer 114 calculates the temperature difference (measured temperature difference) between the two temperature measuring junctions A and B based on the electromotive force of the first thermocouple 112, and sequentially outputs the calculation results.
- the second measurement unit 120 uses the second thermocouple 122 having a time constant different from that of the first thermocouple 112, and uses this temperature difference between the measurement position C (third measurement position) and the measurement position D (fourth measurement position). Measure.
- the measurement position C a place where the temperature can be regarded as the same as the measurement position A is selected.
- the measurement position D a place where the temperature is the same as the measurement position B is selected.
- the measurement position C is a position very close to the measurement position A
- the measurement position D is a position very close to the measurement position B. Both the distance between the measurement position A and the measurement position C and the distance between the measurement position B and the measurement position D are extremely short relative to the distance ⁇ x of the measurement target section.
- the second measuring unit 120 includes a second thermocouple 122 and a second differential thermometer 124.
- the second measuring unit 120 is different in thermal inertia from the first measuring unit 110.
- the second thermocouple 122 is a thermocouple having a time constant different from that of the first thermocouple 112.
- the second thermocouple 122 is different in wire diameter from the first thermocouple 112.
- the second thermocouple 122 includes a third temperature measuring contact 126 and a fourth temperature measuring contact 128.
- the third temperature measuring contact 126 is arranged at the measurement position C
- the fourth temperature measuring contact 128 is arranged at the measurement position D.
- the second differential thermometer 124 calculates the temperature difference (measured temperature difference) between the two temperature measuring junctions C and D based on the electromotive force of the second thermocouple 122, and sequentially outputs the calculation result.
- the recording device 130 and the signal processing device 140 include the measured temperature difference obtained from the thermoelectromotive force of the thermocouples 112 and 122 of the measuring units 110 and 120, and the time differential value of the measured temperature difference of the measuring units 110 and 120, respectively. Is used to detect the time constants of the thermocouples 112 and 122 of at least one of the measuring units 110 and 120, calculate a temperature difference that compensates for the response delay of the actually measured temperature difference based on the detected time constant, and calculates the compensated temperature.
- the heat flux calculation units 130 and 140 that calculate the heat flux from the difference are configured.
- the recording device 130 is connected to the first measurement unit 110 and the second measurement unit 120, respectively.
- the recording device 130 records the response output of the first measurement unit 110 (measurement result of actual temperature difference) and the response output of the second measurement unit 120 (measurement result of actual temperature difference).
- the recording device 130 accumulates the response output 132 (first response output) of the first differential thermometer 114 and the response output 134 (second response output) of the second differential thermometer 124.
- the recording device 130 stores the output signal 132 of the first differential thermometer 114 and the output signal 134 of the second differential thermometer 124 in digital form.
- the first differential thermometer 114 and the second differential thermometer 124 are provided with A / D converters.
- the recording device 130 holds data 136 of the distance ⁇ x between the measurement position A and the measurement position B and data 138 of the thermal conductivity ⁇ between the measurement position A and the measurement position B in advance.
- the distance ⁇ x may be measured in advance when setting the measurement position A and the measurement position B, and stored in the recording device 130.
- the thermal conductivity ⁇ if the material of the measurement object is known, a literature value or the like related to the material may be stored in the recording device 130. Alternatively, the thermal conductivity ⁇ may be separately measured and stored in the recording device 130.
- the signal processing device 140 performs a conversion process from the measurement result recorded in the recording device 130 to the heat flux.
- the signal processing device 140 performs a heat flux calculation step described later.
- the recording device 130 and the signal processing device 140 are substantially realized by a system having computer hardware and data and programs held in the computer hardware.
- FIG. 2 shows an internal configuration of computer hardware 300 constituting this system.
- the computer hardware 300 includes a computer 310, a keyboard 350, a pointing device 352 such as a mouse, and a monitor 354.
- the computer 300 includes a removable memory port 312 for removable memory and a DVD (Digital Versatile Disc) drive 314.
- the keyboard 350 is configured to allow character information and command input operations.
- the computer 310 includes a memory port 312, a DVD drive 314, a central processing unit 316 (CPU), a bus 318, a read only memory 320 (ROM), a random access memory 322 (RAM), and a peripheral storage device 324. , An interface board 326, a graphic board 328, and a network interface card 330 (NIC).
- the bus 318 is connected to the memory port 312, the DVD drive 314, the CPU 316, the read-only memory 320, the random access memory 322, the peripheral storage device 324, the interface board 326, the graphic board 328, and the network interface card 330.
- the read only memory 320 stores a bootup program and the like.
- the random access memory 322 stores program instructions, system programs, work data, and the like.
- the peripheral storage device 324 includes a hard disk drive, a semiconductor storage device drive, or the like, and stores and stores programs, system programs, data, and the like.
- the interface board 326 is connected to the computer 310 and the keyboard 350, the pointing device 352, and other peripheral devices.
- the interface board 326 of the recording device 130 is connected to the first and second differential thermometers 114 and 124.
- the graphic board 328 performs image processing and image output to the monitor 354.
- Network interface card 330 provides a connection to a local area network 360 (LAN) for communicating with other computers.
- LAN local area network 360
- data (first response output and second response output) is stored in a removable medium inserted into the memory port 312 or the DVD drive 314.
- Data stored in the removable medium is transferred to the peripheral storage device 324.
- the data may be stored in the peripheral storage device 324 from the peripheral device connected to the interface board 326 via the interface board 326.
- a program for operating the recording device 130 and the signal processing device 140 (a program for executing a heat flux calculation step described later) is stored in the memory port 312 or a removable medium inserted into the DVD drive 314.
- the program stored in the removable medium is transferred to the peripheral storage device 324.
- the program may be transmitted to the computer 310 through the LAN 360 and stored in the peripheral storage device 324.
- the program is loaded into the RAM 322 when executed.
- the program may be loaded into the RAM 322 from a removable medium or directly via the LAN 360.
- the program includes a plurality of instructions for operating the recording device 130 and the signal processing device 140.
- Some of the basic functions necessary to operate the recording device 130 and the signal processing device 140 are provided by an operating system (OS) that runs on the computer 310 or a third-party program. Therefore, the program need not include all functions necessary for operating the recording device 130 and the signal processing device 140 of the present embodiment. Since the operation of the computer system 300 itself is well known, a description thereof is omitted here.
- OS operating system
- the first thermocouple 112 is used to detect the temperature difference between the measurement position A and the measurement position B lower than the measurement position A, and at the same time, the second thermocouple 112 has a second time constant different from that of the first thermocouple 112.
- the thermocouple 122 Using the thermocouple 122, a temperature difference between a measurement position C that can be regarded as the same temperature as the measurement position A and a measurement position D that can be regarded as the same temperature as the measurement position B is detected.
- the first measurement unit 110 and the second measurement unit 120 sequentially output the actually measured temperature difference (the first response output and the second response output), and the recording device 130 records the output actually measured temperature difference.
- FIG. 3 shows a flowchart 400 of the heat flux calculation step.
- the signal processing device 140 performs a heat flux calculation step.
- the signal processing device 140 performs a heat flux calculation step according to the installed program.
- thermocouples 112 is obtained by using the measured temperature difference obtained from the thermoelectromotive force of each thermocouple 112, 122 and the time differential value of the measured temperature difference of each thermocouple 112, 122. , 122 is detected, a temperature difference that compensates for a response delay of the actually measured temperature difference is calculated based on the detected time constant, and a heat flux is calculated from the compensated temperature difference.
- step 402 is first performed in the heat flux calculation step.
- step 402 parameters used for processing in the program are read.
- step 404 the width N of the data section used to calculate the time constants of the first response output T 1 and the second response output T 2 (see FIG. 1) of the temperature difference is set.
- step 406 the time interval ⁇ t at which the actually measured temperature difference is measured is calculated from the reciprocal of the sampling frequency during A / D conversion.
- step 408 the time differential value G 2 of the first response of the output T 1 time differential value G 1 and the second response output T 2 is calculated.
- Time derivative G 1 of the first response output T 1 is calculated by Equation 1
- the time derivative G 2 of the second response output T 2 are calculated by Equation 2.
- step 412 using the least square method, the response delay time constant ⁇ 1 of the first measurement unit 110 and the response delay time constant ⁇ 1 of the second measurement unit 120 are calculated from the relative relationship of the response delay time constants. 2 is estimated. Specifically, at each measurement time, T g1 temperature difference between the first measuring unit 110 after compensating for the response delay when the use of constant tau 1, can be expressed as Equation 3, the response delay the temperature difference T g2 of the second measuring unit 120 after the compensation, when the use of constant tau 2, can be expressed as equation 4.
- T g1 and T g2 should match after compensation. Therefore, in step 412, time constants ⁇ 1 and ⁇ 2 when the root mean square value e of the difference between T g1 and T g2 shown in Equation 5 is minimized are obtained.
- T g1 T 1 + ⁇ 1 G 1
- T g2 T 2 + ⁇ 2 G 2
- Equation 6 a variable with a horizontal line above represents an average value of the variable.
- tau 1 the tau 2 is assumed to be constant, tau 1, tau 2 of each measurement time will the average value and the same value.
- Equation 7 the average value of ⁇ 1 is expressed by Equation 7, and the average value of ⁇ 2 is expressed by Equation 8.
- step 414 the temperature difference T 1 after compensation is calculated from the measured temperature difference T 1 , the time differential value G 1 calculated in step 408, and the time constant ⁇ 1 calculated in step 412 using Equation 3. g1 is calculated.
- thermocouples 112 and 122 having different time constants are used and the temperature difference between positions where the temperature difference can be regarded as the same is measured, the time constant can be detected.
- the heat flux is calculated.
- the value of the heat flux calculated from this time constant is an instantaneous value with no response delay. Therefore, the time resolution of the heat flux measuring device 100 or the heat flux measuring method can be improved. ⁇ Other Embodiments >>
- the above embodiment may be configured as follows.
- the first measurement unit 110 includes a first high temperature side thermocouple in which a hot junction is provided at the measurement position A, and a first low temperature side thermocouple in which a hot junction is provided at the measurement position B.
- the second measuring unit 120 may include a second high temperature side thermocouple in which the hot junction is provided at the measurement position C and a second low temperature side thermocouple in which the hot junction is provided at the measurement position D.
- the time constants of the first high temperature side thermocouple and the second high temperature side thermocouple are different from each other, and the time constants of the first low temperature side thermocouple and the second low temperature side thermocouple are different from each other.
- the first high temperature side thermocouple, the first low temperature side thermocouple, the second high temperature side thermocouple, and the second low temperature side thermocouple are provided at positions where the cold junction can be regarded as the same temperature.
- an instantaneous value of the temperature difference between the measurement position A and the cold junction position can be obtained.
- the instantaneous value of the temperature difference between the measurement position B and the cold junction position is obtained.
- the temperature difference between the measurement position A and the measurement position B is obtained from the difference between these two instantaneous values, and the heat flux is further calculated.
- thermocouples 112 and 122 a temperature compensation contact point is provided, Alternatively, the temperature may be measured.
- the time constants ⁇ 1 and ⁇ 2 are calculated by calculating the value when the root mean square of the response outputs T 1 and T 2 is minimized, but the temperature difference T after the response compensation is calculated. g1, based on the assumption that similarity to fluctuation waveform of the T g2 occurs, may be obtained value when the correlation coefficient between the two is maximized.
- the relative relationship of factors related to response delay such as the wire diameter ratio and heat transfer ratio of the thermocouples 112 and 122
- the response delay may be compensated using a ratio of time constants calculated from the relative relationship.
- the present invention is useful for a heat flux measuring device and a heat flux measuring method for measuring a heat flux.
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Abstract
Description
数式1:G1=dT1/dt
数式2:G2=dT2/dt
数式3:Tg1=T1+τ1G1
数式4:Tg2=T2+τ2G2
-実施形態の効果-
《その他の実施形態》
110 第1計測部
112 第1熱電対
114 第1差温計
120 第2計測部
122 第2熱電対
124 第2差温計
130 記録装置(熱流束計測部)
140 信号処理装置(熱流束計測部)
Claims (4)
- 熱電対を用いて、第1計測位置と該第1計測位置より低温の第2計測位置との温度差を計測する第1計測部と、
上記第1計測部の熱電対とは時定数が異なる熱電対を用いて、上記第1計測位置と同じ温度とみなせる第3計測位置と上記第2計測位置と同じ温度とみなせる第4計測位置との温度差を計測する第2計測部と、
上記各計測部の熱電対の熱起電力からそれぞれ得られる実測温度差と、上記各計測部の実測温度差の時間微分値とを用いて、少なくとも一方の計測部の熱電対の時定数を検出し、検出した時定数により上記実測温度差の応答遅れを補償した温度差を算出して、該補償後の温度差から熱流束を算出する熱流束算出部とを備えている
ことを特徴とする熱流束計測装置。 - 請求項1において、
上記第1計測部は、温接点が第1計測位置に設けられ、冷接点が第2計測位置に設けられた第1熱電対を備え、
上記第2計測部は、温接点が第3計測位置に設けられ、冷接点が第4計測位置に設けられた第2熱電対を備え、
上記第1熱電対と上記第2熱電対の時定数が互いに異なる
ことを特徴とする熱流束計測装置。 - 請求項1において、
上記第1計測部は、温接点が第1計測位置に設けられた第1高温側熱電対と、温接点が第2計測位置に設けられた第1低温側熱電対とを備え、
上記第2計測部は、温接点が第3計測位置に設けられた第2高温側熱電対と、温接点が第4計測位置に設けられた第2低温側熱電対とを備え、
上記第1高温側熱電対と上記第2高温側熱電対の時定数が互いに異なり、上記第1低温側熱電対と上記第2低温側熱電対の時定数が互いに異なる
ことを特徴とする熱流束計測装置。 - 第1熱電対を用いて、第1計測位置と該第1計測位置より低温の第2計測位置との温度差を検出すると同時に、上記第1熱電対とは時定数が異なる第2熱電対を用いて、上記第1計測位置と同じ温度とみなせる第3計測位置と上記第2計測位置と同じ温度とみなせる第4計測位置との温度差を検出する計測ステップと、
上記各熱電対の熱起電力からそれぞれ得られる実測温度差と、上記各熱電対の実測温度差の時間微分値とを用いて、少なくとも一方の熱電対の時定数を検出し、検出した時定数により上記実測温度差の応答遅れを補償した温度差を算出して、該補償後の温度差から熱流束を算出する熱流束算出ステップとを備えている
ことを特徴とする熱流束計測方法。
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JP2011534357A JP5540241B2 (ja) | 2009-10-02 | 2010-10-04 | 熱流束計測装置、及び熱流束計測方法 |
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JP6799522B2 (ja) * | 2017-11-30 | 2020-12-16 | 三菱重工業株式会社 | 熱流束計測システム |
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- 2010-10-04 US US13/499,762 patent/US9127988B2/en not_active Expired - Fee Related
- 2010-10-04 EP EP10820744.0A patent/EP2485025B1/en not_active Not-in-force
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Cited By (4)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
WO2014058062A1 (ja) * | 2012-10-11 | 2014-04-17 | 京セラ株式会社 | 温度測定システムおよび温度測定装置 |
JP5869690B2 (ja) * | 2012-10-11 | 2016-02-24 | 京セラ株式会社 | 温度測定システムおよび温度測定装置 |
CN114166362A (zh) * | 2021-10-20 | 2022-03-11 | 中国航发四川燃气涡轮研究院 | 一种基于组合丝径热电偶的动态测温时频补偿方法 |
CN114166362B (zh) * | 2021-10-20 | 2023-09-01 | 中国航发四川燃气涡轮研究院 | 一种基于组合丝径热电偶的动态测温时频补偿方法 |
Also Published As
Publication number | Publication date |
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EP2485025A1 (en) | 2012-08-08 |
JP5540241B2 (ja) | 2014-07-02 |
JPWO2011040634A1 (ja) | 2013-02-28 |
EP2485025A4 (en) | 2015-05-06 |
US20120243571A1 (en) | 2012-09-27 |
US9127988B2 (en) | 2015-09-08 |
EP2485025B1 (en) | 2016-08-03 |
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