CN214621518U - Coaxial thermocouple cold junction temperature measuring device and system - Google Patents

Coaxial thermocouple cold junction temperature measuring device and system Download PDF

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Publication number
CN214621518U
CN214621518U CN202023270355.2U CN202023270355U CN214621518U CN 214621518 U CN214621518 U CN 214621518U CN 202023270355 U CN202023270355 U CN 202023270355U CN 214621518 U CN214621518 U CN 214621518U
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China
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coaxial
temperature measuring
thermocouple
cold end
coaxial thermocouple
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CN202023270355.2U
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王长峰
潘宏椂
罗太超
陈浩
邹凯
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China Academy of Aerospace Aerodynamics CAAA
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China Academy of Aerospace Aerodynamics CAAA
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Abstract

The utility model discloses a coaxial thermocouple cold junction temperature measurement device and system, include: the temperature measuring device comprises a connector, a temperature measuring sensor, a heat conducting medium and a heat insulating layer; the connector comprises a shell and a core disc, wherein the core disc is fixed in the shell; cold ends of the plurality of coaxial thermocouples are respectively connected to the core disc; the temperature sensor is connected with the core disc; the heat-conducting medium is filled in the shell and wraps the temperature measuring sensor, the cold ends of the coaxial thermocouples and the core disc, and the heat-conducting medium is wrapped by the heat-insulating layer. The utility model provides high coaxial thermocouple cold junction measurement accuracy has reduced cold junction measurement volume, can satisfy flight test environment measurement requirement.

Description

Coaxial thermocouple cold junction temperature measuring device and system
Technical Field
The utility model belongs to the technical field of measure, more specifically relates to a coaxial thermocouple cold junction temperature measurement device and system.
Background
The coaxial thermocouple temperature measurement technology has the performances of quick response, high precision and the like, and is widely applied to the fields of civil products, aviation, aerospace, ships and the like. The technology for measuring the temperature of the cold end of the coaxial thermocouple has limitations, and the technology generally uses a 0-degree ice-water mixture and a PT100 temperature sensor to indirectly measure the temperature or uses an amplification chip with cold end output to measure in the industry, so that the measurement precision is not high and the volume is large. In a flight test, data measurement is mainly concentrated in a head cabin, and two difficulties need to be overcome in measurement, namely higher measurement precision requirement and obvious temperature change of a cold end position; secondly, the installation space is limited. In the flight test, the number of environment measurement channels is hundreds, the measurement precision is extremely high, and the conventional measurement mode cannot give consideration to both precision and volume.
Therefore, the device and the system for measuring the cold end temperature of the coaxial thermocouple are expected to be developed, the limitations of low measurement precision, large cold end measurement volume, low integration and the like are overcome, and multi-channel, integrated and high-precision measurement is realized.
SUMMERY OF THE UTILITY MODEL
The utility model aims at providing a coaxial thermocouple cold junction temperature measuring device and system improves coaxial thermocouple cold junction measurement accuracy, reduces cold junction measurement volume to adapt to flight test environment measurement requirement.
In order to achieve the above object, the utility model provides a coaxial thermocouple cold junction temperature measuring device, include: the temperature measuring device comprises a connector, a temperature measuring sensor, a heat conducting medium and a heat insulating layer;
the connector comprises a shell and a core disc, the core disc is fixed in the shell, and the cold ends of the plurality of coaxial thermocouples are respectively connected to the core disc;
the temperature sensor is connected with the core disc;
the heat-conducting medium is filled in the shell and wraps the temperature measuring sensor, the cold ends of the plurality of coaxial thermocouples and the core disc, and the heat-insulating layer is arranged between the heat-conducting medium and the shell and wraps the heat-conducting medium.
Optionally, the positive electrode and the negative electrode of the cold end of the coaxial thermocouple are respectively welded on the core disc through compensation wires.
Optionally, the anode and the cathode of the temperature sensor are respectively welded on the core disc through pins, and the temperature sensor is attached to the core disc.
Optionally, the thermocouple is a nickel chromium-constantan thermocouple.
Optionally, the heat conducting medium is made of silicon rubber, and the heat insulating layer is made of epoxy resin.
The utility model also provides a coaxial thermocouple cold junction temperature measurement system, include: the coaxial thermocouple cold end temperature measuring device, the interface protection module, the conditioning acquisition module and the data processing module are arranged on the base;
the output end of the cold end temperature measuring device of the coaxial thermocouple is connected to the conditioning acquisition module through the interface protection module, and the output end of the conditioning acquisition module is connected to the data processing module;
the output end of a temperature measuring sensor of the coaxial thermocouple cold end temperature measuring device is connected to the conditioning acquisition module, and the conditioning acquisition module is connected to the temperature measuring sensor through an excitation current signal.
Optionally, the interface protection module, the conditioning acquisition module and the data processing module are integrally arranged on a circuit board, and the coaxial thermocouple cold end temperature measuring device is inserted into the circuit board through the connector.
Optionally, the conditioning acquisition module includes an integrated operational amplifier, and the interface protection module includes TC +, TC-, a resistor R1, a resistor R2, a resistor R3, a resistor R4, a capacitor C1, a capacitor C2, and a capacitor C3;
the TC + and the TC-are input ends;
the TC + is connected with the anode of the coaxial thermocouple and is connected with the anode of the integrated operational amplifier through the resistor R1;
the TC-is connected with the negative electrode of the coaxial thermocouple and is connected with the negative electrode of the integrated operational amplifier through the resistor R2;
the TC + is grounded through the capacitor C1, and the TC-is grounded through the capacitor C3 and the resistor R4 respectively;
the capacitor C2 and the resistor R3 are connected in parallel between the TC + and the TC-.
Optionally, the gain of the integrated operational amplifier is adjustable.
Optionally, the data processing module includes a signal receiver and a signal processor connected in sequence, the signal receiver is connected to the output end of the conditioning and collecting module, and the output end of the signal processor is provided with a balanced voltage digital interface.
The beneficial effects of the utility model reside in that:
1. according to the measuring device, the temperature measuring sensor, the cold ends of the multiple coaxial thermocouples and the core disc are wrapped in the heat conducting medium, so that the temperature of the temperature measuring sensor, the cold ends of the multiple coaxial thermocouples and the environment where the core disc is located are consistent, the heat conducting medium is wrapped in the heat insulating layer, the temperature of the temperature measuring sensor, the cold ends of the multiple coaxial thermocouples and the environment where the core disc is located are prevented from sudden change, the purpose that the real cold ends of the coaxial thermocouples and the measuring cold ends of the temperature measuring sensor are located in a uniform temperature environment is achieved, the temperature measuring sensor is equivalently enabled to be infinitely close to the position of the cold ends of the coaxial thermocouples, and high-precision measurement is achieved; through heat-conducting medium and heat insulation layer with a plurality of coaxial thermocouple cold junctions and temperature sensor integration in a connector and use a temperature sensor just can measure a plurality of coaxial thermocouple's cold junction temperature simultaneously, reduced cold junction measurement volume, overcome traditional coaxial thermocouple cold junction measurement accuracy not high, cold junction measuring device bulky limitation.
2. According to the measuring system, the temperature measuring sensor and the cold end of the coaxial thermocouple are integrated through the cold end temperature measuring device of the coaxial thermocouple, the traditional method of using a cold end built-in conditioning chip is replaced, the conditioning acquisition module and the data processing module are matched to realize high integration of the system, and finally high-precision cold end measurement of the coaxial thermocouple is realized, so that the measuring system is suitable for the environment measurement requirement of a flight test; the interface protection module is arranged, so that the conditioning acquisition module can be protected, and the power consumption of the conditioning acquisition circuit is reduced.
Other features and advantages of the present invention will be described in detail in the detailed description which follows.
Drawings
The above and other objects, features and advantages of the present invention will become more apparent by describing in more detail exemplary embodiments thereof with reference to the attached drawings, in which like reference numerals generally represent like parts throughout the exemplary embodiments of the present invention.
Fig. 1 shows a schematic diagram of a coaxial thermocouple cold end temperature measurement device according to an embodiment of the present invention.
Fig. 2 shows a flow diagram of a coaxial thermocouple cold end temperature measurement system according to an embodiment of the present invention.
Fig. 3 shows a schematic diagram of an interface protection module according to an embodiment of the invention.
Description of the reference numerals
1. A copper core disk; 2, measuring the temperature of the anode of the sensor; 3. a temperature measuring sensor; 4. a temperature sensor cathode; 5. A housing; 6. a heat insulating layer; 7. a heat-conducting medium; 8; the cathode of the coaxial thermocouple and the anode of the 9 coaxial thermocouple.
Detailed Description
Preferred embodiments of the present invention will be described in more detail below. While the following describes preferred embodiments of the present invention, it should be understood that the present invention may be embodied in various forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete, and will fully convey the scope of the invention to those skilled in the art.
In the description of the present invention, it is to be understood that the terms "center", "longitudinal", "lateral", "length", "width", "thickness", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", "clockwise", "counterclockwise", "axial", "radial", "circumferential", and the like, indicate the orientation or positional relationship indicated based on the drawings, and are only for convenience of description and simplicity of description, and do not indicate or imply that the device or element referred to must have a particular orientation, be constructed and operated in a particular orientation, and therefore, should not be construed as limiting the present invention.
The utility model discloses a coaxial thermocouple cold junction temperature measuring device, include: the temperature measuring device comprises a connector, a temperature measuring sensor, a heat conducting medium and a heat insulating layer;
the connector comprises a shell and a core disc, the core disc is fixed in the shell, and the cold ends of the plurality of coaxial thermocouples are respectively connected to the core disc;
the temperature sensor is connected with the core disc;
the heat-conducting medium is filled in the shell and wraps the temperature measuring sensor, the cold ends of the coaxial thermocouples and the core disc, and the heat-insulating layer is arranged between the heat-conducting medium and the shell and wraps the heat-conducting medium.
Specifically, the measuring device of the application wraps the temperature measuring sensor, the cold ends of the multiple coaxial thermocouples and the core disc by using the heat conducting medium, the temperature measuring sensor, the positive and negative electrodes of the cold ends of the multiple coaxial thermocouples, the core disc and the heat conducting medium form heat conducting heat balance, so that the cold ends of the temperature measuring sensor, the multiple coaxial thermocouples and the core disc are in the same environmental temperature, the heat conducting medium is wrapped in the heat conducting medium by using the heat insulating layer, the heat insulating layer and the shell form heat insulating heat balance, the temperature of the cold ends of the temperature measuring sensor, the multiple coaxial thermocouples and the environmental temperature of the core disc are prevented from sudden change, the purpose that the true cold ends of the coaxial thermocouples and the cold ends of the temperature measuring sensor are in a uniform temperature environment is achieved, the temperature measuring sensor is equivalent to be infinitely close to the cold end position of the coaxial thermocouples, and high-precision measurement is achieved; through heat-conducting medium and heat insulation layer with a plurality of coaxial thermocouple cold junctions and temperature sensor integration in a connector and use a temperature sensor just can measure a plurality of coaxial thermocouple's cold junction temperature simultaneously, reduced cold junction measurement volume, overcome traditional coaxial thermocouple cold junction measurement accuracy not high, cold junction measuring device bulky limitation.
Alternatively, the positive electrode and the negative electrode of the cold end of the coaxial thermocouple are respectively welded on the core disc through compensation wires.
Particularly, the device shortens the length of the compensating lead to the maximum extent and improves the accuracy of temperature measurement.
As an alternative, the anode and the cathode of the temperature sensor are respectively welded on the core disc through pins, and the temperature sensor is attached to the core disc.
Specifically, the temperature sensor is closely attached to the core disc, and the precision of the temperature sensor is preferably ten thousandth of precision.
Alternatively, the thermocouple is a nickel chromium-constantan thermocouple.
Specifically, the nickel-chromium-constantan thermocouple is a thermocouple composed of an alloy wire with an NiCr10 as a positive electrode and an alloy wire with a CuNi45 (constantan) as a negative electrode, is an international standard thermocouple, and has a reference number of E. The maximum service temperature is 750 ℃ for a long time, 900 ℃ for a short time, the temperature of a graded surface temperature zone is-270-1000 ℃, and the thermoelectric potential of 900 ℃ is 68.783 mV. The thermocouple is characterized in that the thermocouple has the highest sensitivity in internationally standardized thermocouples within the temperature range of-250-1000 ℃, and two poles of the thermocouple are made of nonmagnetic alloy at room temperature. The thermocouple has good thermal potential-temperature difference relation linearity (above room temperature), good repeatability and good corrosion resistance, and is a middle-temperature and low-temperature thermocouple with the best working performance of 253 ℃ below zero to 800 ℃. Suitable for operation in an oxidizing, inert atmosphere, but not suitable for operation in a sulfur-containing atmosphere. It is often used in the fields of petroleum, chemical industry, aviation, nuclear industry, etc.
Further, the coaxial thermocouple may be a conventional thermocouple such as model K, T, B.
As an alternative, the heat-conducting medium is made of silicon rubber, and the heat-insulating layer is made of epoxy resin.
The utility model also provides a coaxial thermocouple cold junction temperature measurement system, include: the coaxial thermocouple cold end temperature measuring device, the interface protection module, the conditioning acquisition module and the data processing module are arranged on the base;
the output end of the coaxial thermocouple cold end temperature measuring device is connected to the conditioning acquisition module through the interface protection module, and the output end of the conditioning acquisition module is connected to the data processing module;
the output end of a temperature sensor of the coaxial thermocouple cold end temperature measuring device is connected to the conditioning acquisition module, and the conditioning acquisition module is connected to the temperature sensor through an excitation current signal.
Specifically, the measuring system integrates the temperature measuring sensor and the cold end of the coaxial thermocouple through the cold end temperature measuring device of the coaxial thermocouple, replaces the traditional method of using a conditioning chip arranged in the cold end, is matched with a conditioning acquisition module and a data processing module to realize high integration of the system, and finally realizes high-precision cold end measurement of the coaxial thermocouple, so that the measuring system is suitable for the measuring requirement of the flight test environment; the interface protection module is arranged, so that the conditioning acquisition module can be protected, and the power consumption of the conditioning acquisition circuit is reduced.
The coaxial thermocouple cold end temperature measuring device is connected with the interface protection module through an in-board copper wire.
As an alternative scheme, the interface protection module, the conditioning acquisition module and the data processing module are integrally arranged on a circuit board, and the coaxial thermocouple cold end temperature measuring device is inserted on the circuit board through a connector.
Specifically, the interface protection module, the conditioning acquisition module and the data processing module are integrally arranged on a circuit board, and the connector is used as a carrier for connecting the coaxial thermocouple cold end temperature measuring device and the circuit board, so that the wire distance between the real cold end and the data processing module is shortened to the maximum extent, the measuring precision is improved, the volume of the cold end measuring device is reduced, the hardware cost is reduced, the precision of the measured cold end is improved, and the device is convenient and reliable to detach and install.
As an alternative, the conditioning acquisition module comprises an integrated operational amplifier, and the interface protection module comprises TC +, TC-, a resistor R1, a resistor R2, a resistor R3, a resistor R4, a capacitor C1, a capacitor C2, and a capacitor C3;
TC + and TC-are input ends;
the TC + is connected with the anode of the coaxial thermocouple and is connected with the anode of the integrated operational amplifier through a resistor R1;
TC-is connected with the negative electrode of the coaxial thermocouple and is connected with the negative electrode of the integrated operational amplifier through a resistor R2;
TC + is grounded through a capacitor C1, and TC-is grounded through a capacitor C3 and a resistor R4 respectively;
the capacitor C2 and the resistor R3 are connected in parallel between TC + and TC-.
Specifically, a resistor R1, a resistor R2, a resistor R4, a capacitor C1, a capacitor C2 and a capacitor C3 in the interface protection module form a filtering and anti-interference function, and a resistor R3 forms an open-circuit thermal protection function; the multi-channel conditioning acquisition module has the advantages of being anti-interference and low in noise performance, solving the problem of electromagnetic compatibility of the multi-channel conditioning acquisition module, and avoiding reduction of measurement accuracy caused by electromagnetic interference.
Alternatively, the gain of the integrated operational amplifier is an adjustable gain.
In particular, with adjustable gain, different types of coaxial thermocouples can be adapted.
Furthermore, the acquisition part of the conditioning acquisition module adopts oversampling setting to increase sampling precision; and the acquired data is transmitted to the data processing module through the SPI bus.
As an alternative, the data processing module comprises a signal receiver and a signal processor which are connected in sequence, the signal receiver is connected to the output end of the conditioning acquisition module, and the output end of the signal processor is provided with a balanced voltage digital interface.
Specifically, the signal receiver (FPGA) is connected to the output end of the conditioning acquisition module and is responsible for receiving and sending data, and the signal processor (DSP) is responsible for decoding, calculating and encoding the data and outputting the data through a balanced voltage digital interface.
Example 1
Fig. 1 shows a schematic diagram of a cold-end temperature measuring device of a coaxial thermocouple according to the present embodiment.
As shown in fig. 1, the device for measuring the temperature of the cold end of the coaxial thermocouple in the embodiment includes: the connector, the temperature sensor 3, the heat-conducting medium 7 and the heat-insulating layer 6;
the connector comprises a shell 5 and a copper core disc 1, wherein the copper core disc 1 is fixed in the shell 5;
the coaxial thermocouple positive electrodes 9 and the coaxial thermocouple negative electrodes 8 at the cold ends of the plurality of coaxial thermocouples are respectively welded on the copper core disc 1 through compensation wires, and the welding points are the real cold ends of the coaxial thermocouples; the anode 2 and the cathode 3 of the temperature sensor 3 are respectively welded on the copper core disc 1 through pins, the temperature sensor 3 is tightly attached to the copper core disc 1, and the temperature sensing surface of the temperature sensor 3 is the measuring cold end of the coaxial thermocouple; the device can be connected with 30-100 paths of (adjustable) coaxial thermocouples, and one measuring sensor 3 can be used;
the heat-conducting medium 7 is filled in the shell 5 and wraps the temperature measuring sensor 3, the cold ends of the plurality of coaxial thermocouples and the copper core disc 1, and the heat-insulating layer 6 is arranged between the heat-conducting medium 7 and the shell 5 and wraps the heat-conducting medium 7.
In the embodiment, the thermocouple is a nickel-chromium-constantan thermocouple, the E type is E20PL11, the diameter of a compensation lead wire is smaller than 1mm, the temperature measuring sensor 3 is a ten-thousandth precision PT100 temperature sensor, the heat conducting medium 7 is Dow Corning 160 double-combination silicon rubber, the heat insulating layer 6 is made of epoxy resin DG-3S, and the connector is a J30J series 66-core connector produced by medium-navigation photoelectricity.
In the flight test environment measuring process, a temperature sensor anode 2 and a temperature sensor cathode 4 of a temperature sensor 3 are welded to a connector copper core disc 1, a coaxial thermocouple anode 9 and a coaxial thermocouple cathode 8 are welded to the connector copper core disc 1, the temperature sensor 3 is tightly attached to the connector copper core disc 1, the environment temperatures of the copper core disc 1, the temperature sensor 3, the coaxial thermocouple anode 9 and the coaxial thermocouple cathode 8 are consistent through a heat-conducting medium 7, and a heat-insulating layer 6 ensures that the wrapping part of the heat-conducting medium 7 does not generate environment temperature mutation, so that the temperature measured by the temperature sensor 3 is consistent with the temperatures of a welding spot of the coaxial thermocouple anode 9 and a welding spot of the coaxial thermocouple cathode 8, and the measuring precision is improved; through integrating a plurality of coaxial thermocouple cold junctions and temperature sensor 3 in a connector through heat-conducting medium 7 and heat insulation layer 6 and use temperature sensor 3 just can measure a plurality of coaxial thermocouple's cold junction temperature simultaneously, reduced cold junction measurement volume, overcome traditional coaxial thermocouple cold junction measurement accuracy not high, cold junction measuring device bulky limitation.
Example 2
FIG. 2 shows a schematic diagram of a coaxial thermocouple cold end temperature measurement system of the present embodiment; fig. 3 shows a schematic diagram of the interface protection module of the present embodiment.
As shown in fig. 2, the system for measuring the temperature of the cold end of the coaxial thermocouple in the embodiment includes: the device comprises a coaxial thermocouple cold end temperature measuring device, an interface protection module, a conditioning acquisition module and a data processing module in the embodiment 1; the output end of the coaxial thermocouple cold end temperature measuring device is connected to the conditioning acquisition module through the interface protection module, and the output end of the conditioning acquisition module is connected to the data processing module; the interface protection module, the conditioning acquisition module and the data processing module are integrally arranged on a Printed Circuit Board (PCB), the coaxial thermocouple cold end temperature measuring device is inserted into the PCB through a connector, and the coaxial thermocouple cold end temperature measuring device is connected with the interface protection module through an in-board copper wire.
The device for measuring the temperature of the cold end of the coaxial thermocouple is mainly used for providing a cold end temperature measuring environment and realizing the constant temperature measurement of the cold end of the coaxial thermocouple; the interface protection module has the functions of open circuit thermal protection, low power consumption, high precision and the like; the conditioning acquisition module provides current excitation for the temperature measuring sensor and amplifies/converts the temperature measuring sensor and the coaxial thermoelectric even data; the conditioned and collected data are output to a data processing module (FPGA + DSP) through an SPI bus; the FPGA acquires and conditions AD data in the acquisition module through the SPI bus, outputs the AD data to the DSP for data multi-stage formula conversion to form physical quantity data, and outputs the physical quantity data through a balanced voltage digital interface (422).
According to the method, the temperature measuring sensor and the cold end of the coaxial thermocouple are designed in an integrated mode through the cold end temperature measuring device of the coaxial thermocouple, the traditional method that a conditioning chip is arranged in the cold end is replaced, the FPGA + DSP data processing module is used for high integration, and finally high-precision cold end measurement of the coaxial thermocouple is achieved, so that the flying test environment measurement requirement is met.
The output end of a temperature sensor of the coaxial thermocouple cold end temperature measuring device is connected to the conditioning acquisition module, and the conditioning acquisition module is connected to the temperature sensor through an excitation current signal.
In the embodiment, the gain of the integrated operational amplifier of the conditioning acquisition module is adjustable, the input range of the conditioning acquisition module is 100 mv-500 mv, the integrated operational amplifier selects AD8421, and the adjusting resistor uses a high-precision resistor, so that white noise can be effectively reduced, and the acquisition precision is improved; the AD acquisition chip is AD7616, the input end is differential +/-10V, 16-path simultaneous acquisition can be realized by the single chip, oversampling is used, single-path 200kHz sampling can be realized to the maximum extent, and the sampling precision is increased; the FPGA selects Altera EP4CE22E2217N, the DSP selects a TI series ARM processor AM3358x which is a high-performance Cortex-A8 architecture processor, the highest operating frequency can reach 1GHz, the system has high performance while operating with low power consumption, and the data operation reliability is ensured.
As shown in fig. 3, the interface protection module includes TC +, TC-, a resistor R1, a resistor R2, a resistor R3, a resistor R4, a capacitor C1, a capacitor C2, and a capacitor C3; TC + and TC-are input ends; the TC + is connected with the anode of the coaxial thermocouple and is connected with the anode of the integrated operational amplifier through a resistor R1; TC-is connected with the negative electrode of the coaxial thermocouple and is connected with the negative electrode of the integrated operational amplifier through a resistor R2; TC + is grounded through a capacitor C1, and TC-is grounded through a capacitor C3 and a resistor R4 respectively; the capacitor C2 and the resistor R3 are connected in parallel between TC + and TC-.
The resistor R1, the resistor R2, the resistor R4, the capacitor C1, the capacitor C2 and the capacitor C3 form a filtering function. When the coaxial thermocouple is broken, the coaxial thermocouple wire in the closed cabin can serve as an antenna, common mode or differential mode interference is generated, electromagnetic compatibility of a system can be influenced, and a sensor channel is indirectly influenced; when the coaxial thermocouple shell is lapped with the cabin shell, the secondary power supply of the conditioning and collecting module is lapped with the cabin shell, the cabin shell can cause the power supply voltage of the amplifier to be unstable in the flying process, the precision can be obviously reduced, and the filter circuit can effectively inhibit the phenomenon;
the resistor R3 is used for circuit thermal protection, when no analog quantity is input at the input end, the resistor R3 starts to work, the temperature rise of the device caused by the backward flow current of the amplifier is prevented, the power consumption is prevented from increasing, and the heating value of the amplifier in a fault state can be effectively reduced by the resistor R3.
In this embodiment, 33 Ω is selected based on the circuit characteristic resistor R1 and the resistor R2, 0.01uF is selected for the capacitor C1 and the capacitor C3, 0.1uF is selected for the capacitor C2, 20M Ω is selected based on the amplifier suppression interference characteristic resistor R4, and 100k Ω is selected for the disconnection protection resistor R3.
While various embodiments of the present invention have been described above, the above description is intended to be illustrative, not exhaustive, and not limited to the disclosed embodiments. Many modifications and variations will be apparent to those of ordinary skill in the art without departing from the scope and spirit of the described embodiments.

Claims (10)

1. A coaxial thermocouple cold end temperature measurement device, comprising: the temperature measuring device comprises a connector, a temperature measuring sensor, a heat conducting medium and a heat insulating layer;
the connector comprises a shell and a core disc, the core disc is fixed in the shell, and the cold ends of the plurality of coaxial thermocouples are respectively connected to the core disc;
the temperature sensor is connected with the core disc;
the heat-conducting medium is filled in the shell and wraps the temperature measuring sensor, the cold ends of the plurality of coaxial thermocouples and the core disc, and the heat-insulating layer is arranged between the heat-conducting medium and the shell and wraps the heat-conducting medium.
2. The device for measuring the cold end temperature of the coaxial thermocouple according to claim 1, wherein the positive electrode and the negative electrode of the cold end of the coaxial thermocouple are respectively welded on the core disc through compensation wires.
3. The cold end temperature measuring device of the coaxial thermocouple according to claim 1, wherein the anode and the cathode of the temperature measuring sensor are respectively welded to the core disc through pins, and the temperature measuring sensor is attached to the core disc.
4. The coaxial thermocouple cold end temperature measurement device of claim 1, wherein the thermocouple is a nickel chromium-constantan thermocouple.
5. The cold end temperature measuring device of the coaxial thermocouple of claim 1, wherein the heat conducting medium is made of silicon rubber, and the heat insulating layer is made of epoxy resin.
6. A coaxial thermocouple cold end temperature measurement system, comprising: the coaxial thermocouple cold end temperature measuring device, the interface protection module, the conditioning acquisition module and the data processing module of any one of claims 1 to 5;
the output end of the cold end temperature measuring device of the coaxial thermocouple is connected to the conditioning acquisition module through the interface protection module, and the output end of the conditioning acquisition module is connected to the data processing module;
the output end of a temperature measuring sensor of the coaxial thermocouple cold end temperature measuring device is connected to the conditioning acquisition module, and the conditioning acquisition module is connected to the temperature measuring sensor through an excitation current signal.
7. The system for measuring the cold end temperature of the coaxial thermocouple according to claim 6, wherein the interface protection module, the conditioning acquisition module and the data processing module are integrally arranged on a circuit board, and the device for measuring the cold end temperature of the coaxial thermocouple is inserted into the circuit board through the connector.
8. The coaxial thermocouple cold end temperature measurement system of claim 6, wherein said conditioning acquisition module comprises an integrated operational amplifier, said interface protection module comprises TC +, TC-, resistor R1, resistor R2, resistor R3, resistor R4, capacitor C1, capacitor C2, capacitor C3;
the TC + and the TC-are input ends;
the TC + is connected with the anode of the coaxial thermocouple and is connected with the anode of the integrated operational amplifier through the resistor R1;
the TC-is connected with the negative electrode of the coaxial thermocouple and is connected with the negative electrode of the integrated operational amplifier through the resistor R2;
the TC + is grounded through the capacitor C1, and the TC-is grounded through the capacitor C3 and the resistor R4 respectively;
the capacitor C2 and the resistor R3 are connected in parallel between the TC + and the TC-.
9. The coaxial thermocouple cold end temperature measurement system of claim 8, wherein the gain of said integrated operational amplifier is adjustable.
10. The system for measuring the cold end temperature of the coaxial thermocouple according to claim 6, wherein the data processing module comprises a signal receiver and a signal processor which are connected in sequence, the signal receiver is connected to the output end of the conditioning and collecting module, and the output end of the signal processor is provided with a balanced voltage digital interface.
CN202023270355.2U 2020-12-28 2020-12-28 Coaxial thermocouple cold junction temperature measuring device and system Withdrawn - After Issue CN214621518U (en)

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* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN112577621A (en) * 2020-12-28 2021-03-30 中国航天空气动力技术研究院 Coaxial thermocouple cold junction temperature measuring device and system

Cited By (2)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN112577621A (en) * 2020-12-28 2021-03-30 中国航天空气动力技术研究院 Coaxial thermocouple cold junction temperature measuring device and system
CN112577621B (en) * 2020-12-28 2024-08-20 中国航天空气动力技术研究院 Coaxial thermocouple cold end temperature measurement device and system

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