CN209745854U - dynamic detection system for electric heating performance - Google Patents

dynamic detection system for electric heating performance Download PDF

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CN209745854U
CN209745854U CN201920309954.9U CN201920309954U CN209745854U CN 209745854 U CN209745854 U CN 209745854U CN 201920309954 U CN201920309954 U CN 201920309954U CN 209745854 U CN209745854 U CN 209745854U
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sample
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controller
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刘运牙
山东良
潘锴
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Xiangtan University
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Xiangtan University
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Abstract

The utility model discloses an electric heat performance dynamic verification system, including sample platform, excitation signal source, excitation signal amplifier, lock-in amplifier, heat probe, atomic force microscope controller and probe controller. Calibrating to obtain a relation curve between a response signal output by the probe controller and the temperature of the thermal probe; applying an alternating voltage to the sample to carry out dynamic excitation; the thermal probe and the probe controller carry out real-time dynamic detection on a sample to be detected to obtain a dynamic response signal; the phase-locked amplifier carries out real-time processing on the dynamic response signal to obtain an amplitude value of the dynamic response signal; and the atomic force microscope controller is combined with the calibrated relation curve and the amplitude value of the dynamic response signal to analyze and obtain the electric heating performance parameters of the sample. The utility model discloses can realize the accurate measurement of weak electric heat response to realized the real-time detection material electric heat response dynamic change, and the purpose of real-time detection material microscale electric heat performance spatial distribution.

Description

Dynamic detection system for electric heating performance
Technical Field
The utility model relates to an electric heat performance dynamic verification system and detection method, in particular to system of real-time direct measurement material electric heat performance.
background
With the development of the electronic industry, people have higher and higher requirements on refrigeration and heat dissipation, and the traditional refrigeration and heat dissipation mode cannot meet the increasing refrigeration requirements, so that a novel refrigeration technology is urgently developed. The electric heating effect of the temperature change of the material is caused by the fact that the dipole order of the electrolyte material is changed under the action of an external electric field, and the electric heating refrigeration device is a potential novel refrigeration mode. The refrigeration device based on the electrothermal effect has the characteristics of integration, environmental friendliness, low noise and the like, so that the refrigeration device is a promising solid-state refrigeration mode, and the research and development of materials with high electrothermal performance are the main direction of electrothermal research at present. Thus, it is necessary to directly and dynamically detect the material properties in real time.
currently, the direct detection method for electrothermal performance is mainly through the existing commercial instruments or devices, such as infrared thermometers, differential thermal analyzers, or thermocouples. However, the existing direct method mainly measures the electrothermal response in the time domain, has the disadvantages of long time consumption and large environmental influence, cannot monitor the change of the electrothermal performance of the material in real time, and cannot perform real-time dynamic in-situ measurement on the local electrothermal performance of the material. In addition, the existing electrothermal detection technology is difficult to detect weak electrothermal response signals, cannot measure dynamically-changed electrothermal response, cannot monitor the electrothermal performance in real time, and is difficult to expand to the electrothermal response detection of low-dimensional materials. This has seriously hampered the development of electrothermal refrigeration technology and the intensive study of electrothermal mechanism. Therefore, there is an urgent need to develop a new dynamic detection system and method for electrical heating performance.
SUMMERY OF THE UTILITY MODEL
The utility model provides a prior art problem, to prior art's not enough, provided an electric heat performance dynamic detection system, can carry out direct dynamic measurement to the electric heat performance of material in real time, can accurately detect the electric heat performance change of material fast, and anti environmental disturbance ability reinforce. The utility model discloses can listen weak electric heat response signal, overcome prior art and be difficult to the problem of listening to weak electric heat response signal, can promote the commercial atomic force microsystem of the type to a maximum.
the utility model provides a technical scheme does:
A dynamic detection system for electric heating performance comprises a sample stage, an excitation signal source, an excitation signal amplifier, a phase-locked amplifier, a thermal probe, an atomic force microscope controller and a probe controller;
The sample table is used for bearing a sample to be tested, and a temperature control system is arranged in the sample table and used for controlling the temperature of the sample table and the temperature of the thermal probe in the calibration process;
Two input interfaces of the excitation signal source are respectively connected with the excitation signal amplifier and the phase-locked amplifier, and output an alternating voltage signal and a reference signal required by the phase-locked amplifier;
The excitation signal amplifier is used for amplifying an alternating voltage signal generated by the excitation signal source to obtain an excitation voltage; the output end of the excitation signal amplifier is connected with the electrodes at the two ends of the sample to be tested, and excitation voltage is applied to the electrodes at the two ends of the sample to be tested to excite the sample to be tested to generate electric heating dynamic response;
The atomic force microscope controller comprises a probe driving module and a data processing module; the probe driving module is used for carrying out space positioning on the thermal probe and controlling the needle point of the thermal probe to be in contact with the sample table or a sample to be detected, and the thermal probe is used for detecting the temperature of the sample table or the sample to be detected and converting the temperature into an electric signal to be output;
The signal input end of the probe controller is connected with the thermal probe and is used for applying an electric signal required by the operation of the thermal probe to the thermal probe, detecting the electric signal output by the thermal probe and outputting a corresponding response signal; the signal output end of the probe controller is connected with a data processing module and a phase-locked amplifier in the atomic force microscope controller;
the signal output end of the phase-locked amplifier is connected with a data processing module in the atomic force microscope controller; the phase-locked amplifier is used for carrying out real-time frequency locking processing on the dynamic response signal output by the probe controller in the detection process to obtain the amplitude value of the dynamic response signal and outputting the amplitude value to the data processing module in the atomic force microscope controller;
the data processing module in the atomic force microscope controller is used for obtaining a relation curve of response signals along with temperature change based on the response signals output by the probe controller and the temperature change condition of a thermal probe (sample stage) in the calibration process, then obtaining an amplitude value output by the phase-locked amplifier in the detection process, obtaining a temperature value corresponding to the amplitude value according to the relation curve, and obtaining electric heating performance data of a sample in real time by combining the magnitude of excitation voltage.
Further, the thermal probe comprises two cantilevers, the front ends of the two cantilevers are contacted to form a probe tip of the thermal probe, and the probe tip part is formed by a thermistor.
further, the probe controller includes a signal detector and a signal amplifier;
The input end of the signal detector is connected with the heat probe and used for detecting a response signal caused by the temperature change of the heat probe, and the output end of the signal detector is connected with the input end of the signal amplifier and outputs the response signal to the signal amplifier;
the signal amplifier is used for carrying out preliminary amplification (carrying out integral amplification on the received signal) on the response signal, and the output end of the signal amplifier is connected with a data processing module and a phase-locked amplifier in the atomic force microscope controller.
The signal detector adopts a Wheatstone bridge, and the signal amplifier adopts a differential amplifier. The Wheatstone bridge comprises four bridge arms, wherein two adjacent bridge arms are respectively provided with a constant value resistor, the other bridge arm is provided with a variable resistor, the thermal probe is arranged on the rest bridge arm, the four bridge arms form four nodes, the connecting node of the bridge arms where the two constant value resistors are located is taken as a signal input end and is connected with an input signal source (the output end of a signal generation module in an atomic force microscope controller), two nodes adjacent to the node where the signal input end is located are connected with the input end of a differential signal amplifier, and the rest node is connected with a grounding end;
The output end of the differential signal amplifier is connected with the atomic force microscope controller and the phase-locked amplifier, and the signal is amplified and then output to the atomic force microscope controller data processing module and the phase-locked amplifier.
Further, the atomic force microscope controller comprises a signal generating module, and the output end of the signal generating module is connected with the probe signal controller and is used for providing an electric signal required by the operation of the probe controller.
Further, the atomic force microscope controller comprises an imaging module which is used for displaying the electrothermal performance data obtained by the data processing module in real time.
furthermore, two parallel electrodes are vertically arranged on the sample stage, and a sample to be detected is placed between the two parallel electrodes during detection.
Furthermore, an electrode is horizontally arranged on the sample table, a sample to be detected is placed on the electrode for detection, and the thermal probe in contact with the upper surface of the sample to be detected serves as the other electrode.
The working principle of the dynamic detection system for the electric heating performance is as follows:
step 1, calibrating;
setting the temperature of the sample stage; contacting the thermal probe with the sample stage, detecting the temperature of the sample stage, and converting the temperature into an electric signal; the probe controller detects the electric signal on the thermal probe and outputs a response signal to the atomic force microscope controller;
Combining the temperature change condition of the sample stage by the atomic force microscope controller to obtain a relation curve of the response signal along with the temperature change;
Step 2, detection;
Placing a sample to be detected on a sample table;
generating an alternating voltage signal by an excitation signal source, and amplifying by an excitation signal amplifier to obtain an excitation voltage; applying an excitation voltage to a sample to be tested, and exciting the sample to be tested to generate an electrothermal dynamic response;
the thermal probe senses the dynamic temperature change of the surface of the sample to be measured in real time and converts the dynamic temperature change into a dynamic electric signal; the probe controller detects the dynamic electric signal on the thermal probe and outputs a dynamic response signal to the phase-locked amplifier;
the phase-locked amplifier processes the reference signal output by the excitation signal source and the dynamic response signal output by the probe controller in real time to obtain the amplitude value of the dynamic response signal, and inputs the amplitude value to the atomic force microscope controller;
And (3) acquiring the amplitude value by the atomic force microscope controller, acquiring a temperature change value corresponding to the amplitude value according to the relation curve obtained in the step (1), and acquiring the electric heating performance data of the sample in real time by combining the size of the excitation voltage.
further, in the step 2, the excitation signal source generates an alternating voltage signal with a constant frequency, the atomic force microscope controller fixes the thermal probe at a certain point on the surface of the sample to be detected, and the dynamic change condition of the electrothermal performance of the point on the sample to be detected in the time domain is detected.
Further, the excitation signal source generates alternating voltage signals with different frequencies, the atomic force microscope controller fixes the thermal probe at a certain point on the surface of the sample to be detected, and the dynamic change condition of the electrothermal performance of the point on the sample to be detected in the frequency domain is detected.
Furthermore, the atomic force microscope controller controls the thermal probe to move on the surface of the sample to be detected, a certain area of the sample to be detected is scanned and measured, the frequency of the excitation voltage of the sample to be detected is kept unchanged, and the spatial distribution of the electrothermal performance of the sample to be detected is detected.
further, the ratio of the temperature variation of the sample to be measured to the electric field variation between the two electrodes is used as the electric heating performance parameter of the sample to be measured, wherein the electric field value is the ratio of the excitation voltage value applied to the electrodes at the two ends of the sample to be measured to the distance between the two electrodes.
the utility model has the characteristics of detectivity is high, weak point consuming time, and anti environmental disturbance ability reinforce etc, can realize the accurate measurement of weak electric heat response to realized the real-time detection material electric heat response dynamic change, and the purpose of real-time detection material microscale electric heat performance spatial distribution.
Has the advantages that:
the utility model provides a pair of electric heat performance dynamic detection system can carry out real-time direct dynamic measurement to the electric heat response of material. The weak electric heating response signal is detected by using a frequency locking technology, the weak electric heating response signal submerged by noise can be captured, the amplitude of the weak electric heating response signal can be measured, the problem that the weak electric heating response signal is difficult to detect in the prior art is solved, the problem that the dynamically-changed electric heating response cannot be tested at present is solved, the problem that the test is easily influenced by the environment is eliminated, and the problem that the electric heating response cannot be directly measured in real time in the current testing method is solved. The utility model discloses a real-time high accuracy normal position ration sign to material electric heat performance. The utility model discloses a to response signal's demarcation and use the lock phase amplification technique, realized the electric heat performance of quick accurate real-time quantitative measurement material, the utility model discloses a to the real-time dynamic measurement of material micro-region electric heat response and electric heat performance formation of image. Provides a new way and a new method for researching the dynamic change of the electric heating performance of the material for researchers in the field of electric heating effect.
Drawings
In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below. It is obvious that the drawings described below are only some embodiments of the invention, and that for a person skilled in the art, other drawings can be obtained from these drawings without inventive effort.
Fig. 1 is a schematic structural diagram of the present invention;
FIG. 2 is a schematic structural diagram of a dynamic electrothermal performance detection system according to a modification of the dynamic electrothermal performance detection system shown in FIG. 1, in which the excitation voltage is applied from the two electrodes shown in FIG. 1 to the sample bottom application shown in FIG. 2;
FIG. 3 is a flow chart of the present invention;
FIG. 4 is a graph illustrating the relationship between the response signal and the temperature calibrated by the dynamic detection system for electric heating performance shown in FIGS. 1 and 2;
FIG. 5 is a time domain graph of an electrothermal response signal of a sample to be measured under AC voltage excitation;
FIG. 6 is a frequency domain graph of the electrothermal response temperature change of a sample to be measured under AC voltage excitation;
FIG. 7 is a spatial distribution diagram of the electrothermal performance of the micro-area of the sample to be detected in real time;
Description of reference numerals:
1. the device comprises a sample table, 2, electrodes, 3, a sample, 4, a thermal probe cantilever, 5, a thermistor, 6, a thermal probe, 7, an atomic force microscope controller, 8, a probe controller, 9, a phase-locked amplifier, 10, an excitation signal source, 11, an excitation signal amplifier, 12 and a bottom electrode.
Detailed Description
in order to make the purpose, technical solution and advantages of the present invention clearer, the drawings in the embodiments of the present invention will be combined below to describe the technical solution in the embodiments of the present invention in more detail. It is to be understood that the described embodiments are merely exemplary of some, and not necessarily all, embodiments of the invention. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative efforts belong to the protection scope of the present invention.
as shown in fig. 1, fig. 1 is a schematic structural diagram of an embodiment of the dynamic detection system for electrical thermal performance of the present invention. The dynamic detection system for the electric heating performance is used for detecting the electric heating performance change of a material in real time and comprises a sample table 1, an excitation signal source 10, an excitation signal amplifier 11, a phase-locked amplifier 9, a thermal probe 6, an atomic force microscope controller 7 and a probe controller 8. The sample table 1 is used for bearing and controlling the temperature of a sample 3 to be measured; the excitation signal source 10 is used for generating an alternating voltage signal required by electrothermal dynamic excitation and a reference signal required by the phase-locked amplifier 9; the excitation signal amplifier 11 is used for amplifying an alternating voltage signal generated by the excitation signal source 10 to obtain an excitation voltage, and then the excitation voltage is applied to the electrodes 2 at the two ends of the sample 3 to be tested to excite the sample 3 to be tested to generate an electrothermal effect; the needle tip of the thermal probe 6 is in contact with the sample 3 to be detected, and is used for sensing the temperature of the sample 3 to be detected and converting the temperature into an electric signal; the lock-in amplifier 9 is used for performing frequency locking processing on the dynamic response signal output by the probe controller 8 to obtain an amplitude value of the dynamic response signal, and inputting the amplitude value to the atomic force microscope controller 7; the atomic force microscope controller 7 is used for spatially positioning the thermal probe 6, providing voltage to drive the probe controller 8 to work, and imaging the amplitude value output by the phase-locked amplifier 9; the probe controller 8 is connected with the thermal probe 6 and is used for applying an electric signal required by the operation of the thermal probe 6, detecting the electric signal on the thermal probe and outputting a response signal to the phase-locked amplifier 9; and analyzing to obtain the electric heating performance value of the sample 3 to be detected according to the relationship between the response signal and the temperature and the applied electric heating exciting voltage.
as shown in fig. 1, the excitation signal source 10 generates an ac voltage signal, which is amplified by the excitation signal amplifier 11, applied to two ends of the sample 3 to be measured through the electrodes 2, and outputs a reference signal with the same frequency to the lock-in amplifier 9.
In a modified embodiment of fig. 1, as shown in fig. 2, the electrode 2 may be disposed at the bottom of the sample 3, an ac excitation voltage is applied from the bottom of the sample 3, as shown by a bottom electrode 12, and the bottom electrode 12 is supplied with an excitation voltage signal by an excitation signal amplifier 11.
The probe controller 8 is configured to apply an electrical signal required for operation of the thermal probe 6 to the thermal probe 6, detect an electrical signal output by the thermal probe 6, generate a corresponding response signal, and output the response signal to the lock-in amplifier 9 or the atomic force microscope controller 7.
the phase-locked amplifier 9 is used for performing real-time frequency locking processing on the dynamic response signal output by the probe controller 8 in the detection process, obtaining the amplitude value of the dynamic response signal, and outputting the amplitude value to the atomic force microscope controller 7.
the atomic force microscope controller 7 comprises a probe driving module and a data processing module, the probe driving module is used for spatially positioning the thermal probe 6, the data processing module is used for obtaining a relation curve of response signals along with temperature change based on response signals output by the probe controller 8 and temperature change conditions of the sample stage 3 (thermal probe 6) in a calibration process, obtaining an amplitude value output by the phase-locked amplifier 9 in a detection process, converting the amplitude value into a corresponding temperature value by combining the relation curve of the response signals, and obtaining electric heating performance data of the sample in real time by combining the magnitude of excitation voltage.
The thermal probe 6 is composed of a thermistor needle point 5 and a probe cantilever 4, and when the sample 3 to be detected changes in temperature due to an electrothermal effect caused by electrothermal excitation, an electric signal of the thermal probe 6 changes along with the electrothermal temperature change of the sample to be detected.
In this embodiment, when the sample 3 to be measured generates an electrothermal response, the thermal probe 6 detects the electrothermal response in real time and converts the electrothermal response into an electrical signal for output, the probe controller 8 detects the signal and outputs a corresponding response signal, the lock-in amplifier 9 processes the response signal in real time to obtain an amplitude value of the response signal, and obtains a temperature value corresponding to the amplitude value on a curve of a relationship between the response signal and the temperature, and then the applied excitation voltage is combined to obtain an electrothermal performance parameter of the sample 3 to be measured.
fig. 3 is a flow chart of the dynamic detection system for electric heating performance of the present invention. The method comprises the following steps:
Step 1, calibrating, and establishing a relation curve of response signals along with temperature change;
Step 2, providing alternating voltage to carry out electric heating dynamic excitation on the sample 3 to be tested;
Step 3, the thermal probe and the probe controller carry out real-time dynamic detection on the sample 3 to be detected to obtain a dynamic response signal;
Step 4, the phase-locked amplifier 9 processes the dynamic response signal in real time to obtain the amplitude value of the dynamic response signal;
and 5, analyzing and obtaining the electric heating performance parameters of the sample 3 by combining the calibrated relation curve and the amplitude value of the dynamic response signal by the atomic force microscope controller.
specifically, in one embodiment, in step 1, the temperature of the sample stage 1 is set; contacting the thermal probe 6 with the sample table 1, sensing the temperature of the sample table 1, and converting the temperature into an electric signal; the probe controller 8 detects the electric signal on the thermal probe 6 and outputs a response signal to the atomic force microscope controller 7; adjusting the temperature of the sample table 1, and repeating the above process for multiple tests to obtain multiple groups of temperature-response signal values; the atomic force microscope controller 7 fits to obtain a curve of the response signal with respect to the temperature change as shown in fig. 4 based on a plurality of sets of temperature-response signal values.
in the step 2, the excitation signal source 9 generates an alternating voltage signal, the alternating voltage signal is amplified by the excitation signal amplifier 11 to obtain an excitation voltage, the excitation voltage is applied to the sample 3 to be tested, and the sample 3 to be tested is excited to generate an electrothermal effect.
In the step 3, the atomic force microscope controller 7 controls the thermal probe 6 to sense the temperature change of the surface of the sample 3 to be detected in real time at a certain position on the surface of the sample, and converts the temperature change into a dynamic electric signal; the probe controller 8 detects the dynamic electrical signal on the thermal probe 6 and outputs a dynamic response signal to the lock-in amplifier 9.
In step 4, the lock-in amplifier 9 processes the reference signal output by the excitation signal source 10 and the dynamic response signal output by the probe controller 8 in real time to obtain an amplitude value of the dynamic response signal, and inputs the amplitude value to the atomic force microscope controller 7.
in step 5, the atomic force microscope controller 7 analyzes the relation curve of the comparison amplitude value and the calibration to obtain an electrothermal response temperature change value. And analyzing and calculating to obtain the electric heating performance parameters of the sample 3 to be detected by combining the magnitude of the applied alternating current excitation voltage, and imaging in real time.
as shown in fig. 5, based on the utility model discloses an electric heat performance dynamic verification system and detection method, excitation signal source 10 produces the alternating voltage signal of constant frequency, fixes a position thermal probe 6 at some point on the sample 3 surface that awaits measuring through atomic force microscope controller 7, detects the dynamic change condition under the time domain of this point electric heat performance parameter on the sample 3 that awaits measuring.
As shown in fig. 6, based on the utility model discloses an electric heat performance dynamic verification system and detection method, excitation signal source 10 produces the alternating voltage signal of different frequencies, fixes a position the thermal probe at some point on the sample 3 surface that awaits measuring through atomic force microscope controller 7, detects the dynamic change condition of this point electric heat response temperature change value under the frequency domain on the sample 3 that awaits measuring.
As shown in fig. 7, based on the utility model discloses an electric heat performance dynamic verification system and detection method, through atomic force microscope controller 7 control heat probe 6 at 3 surface movements of the sample that awaits measuring, scan the certain region of the sample that awaits measuring 3 and measure, obtain the real-time electric heat performance parameter spatial distribution condition of the sample that awaits measuring 3 under dynamic excitation.
compared with the prior art, the utility model discloses can carry out real-time direct dynamic measurement to the electrothermal response of material, the utility model discloses use the lock frequency technique to listen weak electrothermal response signal, overcome prior art and be difficult to the problem of listening to weak electrothermal response signal, solve the problem of the current unable test of electrothermal response of prior art dynamic change, eliminated the problem that the prior art test easily receives environmental impact, realized the unable real-time problem to the direct dynamic measurement of electrothermal response of present test method. The utility model discloses a method, realized the real-time high accuracy normal position ration sign to material electric heat performance, realized the real-time dynamic measurement of material micro-region electric heat response and the formation of image of electric heat performance. System simple structure, it is compatible strong, be applicable to different commercial atomic force microsystems, be an easily promote with the new technology and the new method of application, be expected to obtain important application in the research field of electric heat effect.
The previous description of the preferred embodiments is provided to enable any person skilled in the art to make or use the present invention. The modification of various parameters of these examples is simple and convenient for their scientific work. Therefore, the equivalent changes made by the claims of the present invention still belong to the scope covered by the present invention.

Claims (7)

1. A dynamic detection system for electric heating performance is characterized by comprising a sample stage, an excitation signal source, an excitation signal amplifier, a phase-locked amplifier, a thermal probe, an atomic force microscope controller and a probe controller;
The sample table is used for bearing a sample to be tested, and a temperature control system is arranged in the sample table;
Two input interfaces of the excitation signal source are respectively connected with the excitation signal amplifier and the phase-locked amplifier;
The output end of the excitation signal amplifier is connected with electrodes at two ends of a sample to be detected;
The atomic force microscope controller comprises a probe driving module and a data processing module; the probe driving module is connected with the thermal probe and is used for carrying out space positioning on the thermal probe;
the signal input end of the probe controller is connected with the thermal probe, and the signal output end of the probe controller is connected with a data processing module and a phase-locked amplifier in the atomic force microscope controller;
And the signal output end of the phase-locked amplifier is connected with a data processing module in the atomic force microscope controller.
2. The dynamic electrothermal performance detection system of claim 1, wherein the thermal probe comprises two cantilevers, the front ends of the two cantilevers are in contact to form a tip of the thermal probe, and the tip of the thermal probe is formed by a thermistor.
3. the dynamic electrothermal performance detection system of claim 1, wherein the probe controller comprises a signal detector and a signal amplifier;
the input end of the signal detector is connected with the heat probe and used for detecting a response signal caused by the temperature change of the heat probe, and the output end of the signal detector is connected with the input end of the signal amplifier and outputs the response signal to the signal amplifier;
The signal amplifier is used for carrying out preliminary amplification on the response signal, and the output end of the signal amplifier is connected with a data processing module and a phase-locked amplifier in the atomic force microscope controller.
4. the dynamic electrothermal performance detection system of claim 1, wherein the atomic force microscope controller comprises a signal generating module, an output of which is connected to the probe signal controller for providing an electrical signal required by the operation of the probe controller.
5. The dynamic electrothermal performance detection system of claim 1, wherein the atomic force microscope controller comprises an imaging module for displaying the electrothermal performance data obtained by the data processing module in real time.
6. The dynamic electrothermal performance detection system of claim 1, wherein two parallel electrodes are vertically disposed on the sample stage, and a sample to be detected is placed between the two parallel electrodes during detection.
7. the dynamic electrothermal performance detection system of claim 1, wherein an electrode is horizontally disposed on the sample stage, the detection is performed by placing the sample to be detected on the electrode, and the thermal probe contacting with the upper surface of the sample to be detected serves as the other electrode.
CN201920309954.9U 2019-03-12 2019-03-12 dynamic detection system for electric heating performance Active CN209745854U (en)

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Cited By (3)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN111693565A (en) * 2019-03-12 2020-09-22 湘潭大学 Dynamic detection system and detection method for electric heating performance
CN113390919A (en) * 2021-06-24 2021-09-14 中国科学技术大学 Method for observing material phase boundary by phase-locked infrared imaging
WO2022183787A1 (en) * 2021-03-02 2022-09-09 北京纳米能源与系统研究所 Method and apparatus for measuring electrical properties of sample material, and device and medium

Cited By (5)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN111693565A (en) * 2019-03-12 2020-09-22 湘潭大学 Dynamic detection system and detection method for electric heating performance
CN111693565B (en) * 2019-03-12 2024-05-14 湘潭大学 Dynamic detection system and detection method for electrothermal performance
WO2022183787A1 (en) * 2021-03-02 2022-09-09 北京纳米能源与系统研究所 Method and apparatus for measuring electrical properties of sample material, and device and medium
CN113390919A (en) * 2021-06-24 2021-09-14 中国科学技术大学 Method for observing material phase boundary by phase-locked infrared imaging
CN113390919B (en) * 2021-06-24 2022-07-15 中国科学技术大学 Method for observing material phase boundary by phase-locked infrared imaging

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