CN209372736U - A kind of measuring device of grapheme material interface resistance - Google Patents

A kind of measuring device of grapheme material interface resistance Download PDF

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Publication number
CN209372736U
CN209372736U CN201821663042.3U CN201821663042U CN209372736U CN 209372736 U CN209372736 U CN 209372736U CN 201821663042 U CN201821663042 U CN 201821663042U CN 209372736 U CN209372736 U CN 209372736U
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metal block
top cover
test sample
interface resistance
measuring device
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CN201821663042.3U
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杨波
黄巧贤
李爽
岳亚楠
李悦
李茂东
黄国家
王志刚
翟伟
张双红
郭华超
伍振凌
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Guangzhou Special Equipment Testing And Research Institute Guangzhou Special Equipment Accident Investigation Technology Center Guangzhou Elevator Safety Operation Monitoring Center
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Guangzhou Special Pressure Equipment Inspection and Research Institute
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Abstract

The utility model relates to a kind of measuring devices of grapheme material interface resistance.The measuring device includes upper shell, lower shell, upper top cover, press machine, water circulating cooling unit, displacement detecting unit, heating unit, temperature detecting unit and data processing unit, the first metal block and the second metal block are respectively equipped in upper and lower cylinder, test sample is set between two metal blocks, upper top cover is located above the first metal block, and press machine is connected with upper top cover.The utility model applies pressure to upper top cover using press machine, pressure is passed to test sample by upper top cover, test sample forced compression, utilize displacement detecting unit real time monitoring and shift value of the collecting test sample under different stress, the compression ratio of test sample is obtained, and realizes the measurement of interface resistance of the test sample under different compression ratios.The utility model has equipment simple, and measurement accuracy is high, good reliability, the wide advantage of measurement use scope.

Description

A kind of measuring device of grapheme material interface resistance
Technical field
The utility model relates to technical field of heat transfer more particularly to a kind of measuring devices of grapheme material interface resistance.
Background technique
Thermal conductivity is to reflect the physical quantity of material thermal conductivity ability.Interface resistance is the presence because of interface between different materials And the obstruction to heat transfer generated.Thermal conductivity and interface resistance are widely used in the engineering field for being related to heat transfer Background, in order to meet the requirement of production technology, sometimes through promotion material thermal conductivity and reduces interface heat such as in engineer application The mode of resistance is with augmentation of heat transfer.
Compressible material refers to when applying a degree of pressure, its own total volume can changed material, example Such as powdery type material or porous material, wherein grapheme material is a kind of important compressible material.Compared to incompressible material For material, the different compression ratios of compressible material have important influence to itself thermal conductivity and thermal contact resistance.In recent years, with Compressible material have an important application in electronics industry and building trade etc., study compressible material in different pressures Thermal conductivity and interface resistance under shrinkage have great importance.
Utility model content
Based on this, the purpose of the utility model is to provide a kind of measuring devices of grapheme material interface resistance, can be real The measurement of existing interface resistance of the material under different compression ratios.
The purpose of this utility model is achieved through the following technical solutions: a kind of grapheme material thermal conductivity and interface heat The measuring device of resistance, including upper shell, lower shell, upper top cover, press machine, water circulating cooling unit, displacement detecting unit, heating Unit, temperature detecting unit and data processing unit;The upper shell and lower shell are integrally formed, the upper shell and lower shell Side wall be equipped with several through-holes along axial direction;The inside of the upper shell is hollow structure to form upper test chamber, it is described on The inner wall of cylinder is equipped with sliding slot, and the upper top cover is installed in sliding slot and can slide up and down in upper test chamber along sliding slot;Institute State and be equipped with upper top cover, the first metal block and test sample in test chamber, the top and bottom of first metal block respectively with Upper top cover and test sample contact, the side wall of first metal block are equipped with protrusion corresponding with the sliding slot;Under described The inside of cylinder is hollow structure to form lower test chamber, and support portion and the second metal block are equipped in the lower test chamber, described Second metal block is fixedly arranged on support portion, and the top of second metal block is contacted with test sample, and bottom is set as rib structure And it is suspended in lower test chamber;The water circulating cooling unit is connected with lower test chamber;The press machine is connected with upper top cover;Institute Stating displacement detecting unit includes the displacement sensor being electrically connected to each other and displacement acquisition card, institute's displacement sensors and upper top cover phase Even;The heating unit includes the power supply and electric heating assembly being electrically connected to each other, and the electric heating assembly is embedded in the first metal In block;The temperature detecting unit includes the thermocouple arrays and temperature acquisition card being electrically connected to each other, and the thermocouple arrays are set In in several described through-holes;The data processing unit is electrically connected with press machine, displacement acquisition card and temperature acquisition card respectively.
The utility model applies pressure to upper top cover using press machine, and pressure is passed to test sample by upper top cover, tests Sample forced compression is obtained using displacement detecting unit real time monitoring and shift value of the collecting test sample under different stress The compression ratio of test sample.Compared with the existing technology, the utility model can be directed to compressible material, change on same covering device The compression ratio of compressible material, and realize the same pacing of thermal conductivity and interface resistance of the compressible material under different compression ratios Amount, and the utility model can also be used for the thermal conductivity and interface resistance of measurement incompressible material.In addition, utility model device Simple with equipment, measurement accuracy is high, good reliability, the wide advantage of measurement use scope.
Further, the water circulating cooling unit includes waterway, two sections of cooling water pipes and water circulating pump;The water cooling Chamber passes through two sections of cooling water pipes respectively and is connected to lower test chamber, forms inlet and outlet respectively at connection position;It is described Water circulating pump is located therein in one-step cooling water pipe.
Further, the rib structure includes several strip pieces, and the both ends of the strip piece are respectively close to water inlet And water outlet.
Further, adiabator layer is filled between the outer wall and inner wall of the upper and lower cylinder.
Further, the depth of the sliding slot is 0.1~2mm.
Further, several described through-holes are equidistantly arranged.
Further, the spacing of several through-holes is 3~15mm.
In order to better understand and implement, illustrates the utility model with reference to the accompanying drawings and examples.
Detailed description of the invention
Fig. 1 is the structural schematic diagram of the measuring device of grapheme material interface resistance.
Fig. 2 is the partial structure diagram of the measuring device of grapheme material interface resistance.
Fig. 3 is the temperature distribution history of test and the functional relation matched curve of temperature and position.
Specific embodiment
Please refer to Fig. 1 and Fig. 2, the measuring device of the grapheme material interface resistance of the present embodiment, including upper shell 10, under Cylinder 20, upper top cover 30, press machine 40, water circulating cooling unit 50, displacement detecting unit 60, heating unit 70, temperature detection Unit 80 and data processing unit 90.
The upper shell 10 is integrally formed with lower shell 20, and in the present embodiment, the upper shell 10 is interior with lower shell 20 Outer diameter is consistent, the side wall of the upper shell 10 and lower shell 20 along axial direction be equipped with several equidistantly arrange it is logical Hole.It is hollow structure between the upper shell 10 and the outer wall and inner wall of lower shell 20 in the present embodiment, it is interior to be filled with low-heat The thermal insulation material 102 of conductance.
The inside of the upper shell 10 is hollow structure to form upper test chamber, and the inner wall of the upper shell 10 is equipped with sliding slot 11, the upper top cover 30 is installed in sliding slot 11 and can slide up and down in upper test chamber along sliding slot 11.It is sliding in the present embodiment Slot 11 is the strip sliding slot along 10 axial direction of upper shell, and depth is no more than 2mm, preferably 0.1~2mm.
The first metal block 12 and test sample 13, the top and bottom of first metal block 12 are equipped in the upper test chamber Portion is contacted with upper top cover 30 and test sample 13 respectively.Preferably, first metal block 12 is standard brass material, is being risen Warm process possesses constant heat conductivity value.Further, first metal block 12 is cylindrical structure, and side wall is equipped with and cunning The corresponding protrusion of slot 11, to play fixed function, the internal diameter of diameter and upper shell 10 matches, can be 11 sets along sliding slot Enter in upper shell 10.
The inside of the lower shell 20 is hollow structure to form lower test chamber, is equipped with support portion 21 in the lower test chamber With the second metal block 22, second metal block 22 is fixedly arranged on support portion 21, the top of second metal block 22 and test Sample 13 contacts, and bottom is set as rib structure and is suspended in lower test chamber.To which the test sample 13 is clamped at first Between metal block 12 and the second metal block 22.Preferably, second metal block 22 is also standard brass material, is being heated up Cheng Yongyou constant heat conductivity value.Further, the upper half of second metal block 22 be cylindrical structure, diameter with it is upper The internal diameter of cylinder 10 matches, and can be inserted in lower shell 10.
The water circulating cooling unit 50 includes 51, two sections of cooling water pipes 52 of waterway and water circulating pump 53;The water cooling Chamber 51 is connected to by two sections of cooling water pipes 52 with lower test chamber respectively, forms inlet and outlet respectively at connection position; The water circulating pump 53 is located therein in one-step cooling water pipe.Waterway 51 is for providing a stable cold source, water circulating pump 53 for guaranteeing circulating for cooling water.Preferably, the volume of waterway 51 cannot be arranged too small, need to guarantee to follow for a long time During ring, the temperature of internal water should be typically no less than 10cm × 10cm × 10cm close to room temperature, volume.Further The rib structure on ground, 22 bottom of the second metal block is connect with water circulation cooling circuit, can guarantee to carry out with recirculated water fast The heat exchange of speed comprising several strip pieces, the both ends of the strip piece are respectively close to the inlet and outlet.
The press machine 40 is connected with upper top cover 30, and to apply pressure, pressure is passed to test sample by upper top cover 30 13, so that the deformation of 13 forced compression of test sample generates change in displacement.
The displacement detecting unit 60 includes the displacement sensor 61 and displacement acquisition card 62 being electrically connected to each other, the displacement Sensor 61 is connected with upper top cover 30, to monitor the change in displacement of test sample 13 in real time.
The heating unit 70 includes the power supply 71 and electric heating assembly 72 that are electrically connected to each other, in the electric heating assembly 72 In the first metal block 12.Preferably, the electric heating assembly 72 is an electric heating sheets, and 12 top of the first metal block is set Fluted, the electric heating sheets are set in the groove.
The temperature detecting unit 80 includes the thermocouple arrays 81 and temperature acquisition card 82 being electrically connected to each other, the thermoelectricity Even array 81 is set in upper shell and axially disposed several through-holes equidistantly arranged of lower shell side wall, and directly with the One metal block 12, test sample 13 and the second metal block 22 contact, to detect the first metal block 12, test sample 13 and Temperature of second metal block 22 along the different location of cylinder axial direction.In the present embodiment, the thermocouple arrays 81 are by several A thermocouple is equidistantly arranged, and its spacing is typically no less than 3mm, preferably 3~15mm.
The data processing unit 90 can be a computer, with press machine 40, displacement acquisition card 62 and temperature acquisition Card 82 is electrically connected, to acquire corresponding data in real time.
The interface resistance of grapheme material can be measured based on above-mentioned measuring device, specifically, the following steps are included:
(1) test sample is prepared, test sample can be porous material or powdery type material, in the present embodiment, test sample Be circular sheet-like structures for Graphene powder powder material, cross sectional dimensions and the first metal block and the second metal block it is transversal Face size is consistent, and measuring its original depth L is 30mm.
(2) one pressure F is applied to test sample with press machine, and records the shift value Δ L of displacement sensor output, passed through The volume compressibility of Δ L/L acquisition test sample.Press machine pressure applied cannot be excessive, need to guarantee that test sample is reinforcing It not being denaturalized in the process because structure is destroyed, the size of value and the material of test sample are related, and when force is ascending, by Gradually setting value is raised to from zero.Pressure size can be adjusted by press machine, to obtain the test under different compression ratios Sample, in the present embodiment, the shift value Δ L of test sample is 6.0mm, and compression ratio Δ L/L is 20%.
(3) power supply opened water circulating pump, waterway is made to be full of the cooling water of room temperature, and be connected to electric heating sheets carries out electric hair The heating power of heat, electric heating sheets cannot be too big, need to guarantee that its warming temperature is no more than the fusion temperature of cylinder, be usually no more than 180℃。
(4) after the output temperature of the thermocouple arrays in upper test chamber and lower test chamber reaches and stablizes, time span one As be greater than two hours, utilize temperature acquisition card to record the temperature value of different location point in upper test chamber and lower test chamber, wherein First metal block, test sample, the second metal block the temperature values of different test position points be listed in table 1, table 2 and table 3 respectively, with Electric heating sheets position as heat source is reference position, x indicate along cylinder axial direction downwardly direction and the reference position away from From.
The temperature value of the different test position points of 1 first metal block of table
x1(mm) T1(℃)
10 76.7
20 76.6
30 76.3
40 75.8
The temperature value of the different test position points of 2 test sample of table
The temperature value of the different test position points of 3 second metal block of table
x2(mm) T2(℃)
80 25.8
90 25.3
100 25.1
110 25.1
(5) temperature distribution history is drawn according to the test data of table 1, table 2 and table 3, as shown in phantom in Figure 3, fitted The temperature of first metal block, test sample and the second metal block and functional relation f1, f2 and f3 of test position point, in Fig. 3 It is shown in solid, it is respectively as follows: f1:T=-0.3x+77.1;F2:T=-15.62x+143;F3:T=-0.23x+27.51.Pass through Linear interpolation can get the temperature value of test sample with the first metal block, the contact interface of the second metal block.In the present embodiment, The upper interface of test sample is contacted with the first metal block bottom interface, position 45mm, which is substituted into f2 and f1 respectively, The corresponding temperature in the position is calculated;The lower interface of test sample is contacted with the second metal block top interface, position 75mm, The positional value is substituted into f2 and f3 respectively, the corresponding temperature in the position is calculated.Above-mentioned calculating data are as shown in table 4.
The corresponding temperature value of 4 interface location of table
x(mm) T(℃)
First metal block bottom interface 45 75.75
Interface in test sample 45 72.71
Interface under test sample 75 25.85
Second metal block top interface 75 25.785
(6) according to 4 data of table, the interface temperature difference T at interface and the first metal block bottom interface in test sample is calculated1For 3.04 DEG C, utilize formula ROn=Δ T1/Q0The interface resistance R at interface in test sample is calculatedOnIt is 1.12 × 10-3K·m2/ W;Calculate the interface temperature difference T at interface and the second metal block top interface under test sample2It is 0.065 DEG C, utilizes formula RUnder= ΔT2/Q0The interface resistance R at interface under test sample is calculatedUnderIt is 2.4 × 10-6K·m2/W。
Further, the average temperature gradient dT by the first metal block is calculated by the test data in table 11/ dx1For -30K/m, the average temperature gradient dT by the second metal block is calculated by the test data in table 32/dx2For- 23K/m, the first, second metal block in the present embodiment are standard brass material, and thermal conductivity k is 102W/ (mK), are utilized Formula Q1=-kdT1/dx1Calculate the heat flow density Q for passing through the first metal block1For 3060W/m2, utilize formula Q2=-k dT2/dx2Calculate the heat flow density Q for passing through the second metal block2For 2346W/m2, then pass through formula Q0=(Q1+Q2)/2, which calculate, to be passed through The heat flow density Q of test sample0For 2703W/m2
The average temperature gradient dT by test sample is calculated by the test data in table 2 again0/dx0For- 1535K/m utilizes formula k0=-Q0dx0/dT0Thermal conductivity k of the test sample under the compression ratio is calculated0For 1.76W/ (m·K)。
Compared with the existing technology, the utility model can be directed to compressible material, change compressible material on same covering device The compression ratio of material, and realize the synchro measure of thermal conductivity and interface resistance of the compressible material under different compression ratios, and this reality With the novel thermal conductivity and interface resistance that can also be used for measurement incompressible material.In addition, the utility model has equipment simple, It is easy to operate, measurement accuracy is high, good reliability, the wide advantage of measurement use scope.
Above-described embodiments merely represent several embodiments of the utility model, the description thereof is more specific and detailed, But it cannot be understood as the limitations to utility model patent range.It should be pointed out that for the common skill of this field For art personnel, without departing from the concept of the premise utility, various modifications and improvements can be made, these are belonged to The protection scope of the utility model.

Claims (7)

1. a kind of measuring device of grapheme material interface resistance, which is characterized in that including upper shell, lower shell, upper top cover, pressure Power machine, water circulating cooling unit, displacement detecting unit, heating unit, temperature detecting unit and data processing unit;The upper cylinder Body and lower shell are integrally formed, and the side wall of the upper shell and lower shell is equipped with several through-holes along axial direction;The upper shell Inside be hollow structure to form upper test chamber, the inner wall of the upper shell is equipped with sliding slot, and the upper top cover is installed on sliding slot It is interior and can be slided up and down in upper test chamber along sliding slot;Upper top cover, the first metal block and test are equipped in the upper test chamber The top and bottom of sample, first metal block are contacted with upper top cover and test sample respectively, the side of first metal block Wall is equipped with protrusion corresponding with the sliding slot;The inside of the lower shell is hollow structure to form lower test chamber, described Support portion and the second metal block are equipped in lower test chamber, second metal block is fixedly arranged on support portion, second metal block Top contacted with test sample, bottom is set as rib structure and is suspended in lower test chamber;The water circulating cooling unit with Lower test chamber is connected;The press machine is connected with upper top cover;The displacement detecting unit includes the displacement sensing being electrically connected to each other Device and displacement acquisition card, institute's displacement sensors are connected with upper top cover;The heating unit include the power supply that is electrically connected to each other and Electric heating assembly, the electric heating assembly are embedded in the first metal block;The temperature detecting unit includes being electrically connected to each other Thermocouple arrays and temperature acquisition card, the thermocouple arrays are set in several described through-holes;The data processing unit point It is not electrically connected with press machine, displacement acquisition card and temperature acquisition card.
2. the measuring device of grapheme material interface resistance according to claim 1, which is characterized in that the water circulation is cold But unit includes waterway, two sections of cooling water pipes and water circulating pump;The waterway passes through two sections of cooling water pipes and lower survey respectively Chamber connection is tried, forms inlet and outlet respectively at connection position;The water circulating pump is located therein one-step cooling water pipe In.
3. the measuring device of grapheme material interface resistance according to claim 2, which is characterized in that the rib structure Including several strip pieces, the both ends of the strip piece are respectively close to inlet and outlet.
4. the measuring device of grapheme material interface resistance according to claim 1, which is characterized in that the upper and lower cylinder Adiabator layer is filled between the outer wall and inner wall of body.
5. the measuring device of grapheme material interface resistance according to claim 1, which is characterized in that the depth of the sliding slot Degree is 0.1~2mm.
6. the measuring device of grapheme material interface resistance according to claim 1, which is characterized in that described several lead to It equidistantly arranges in hole.
7. the measuring device of grapheme material interface resistance according to claim 6, which is characterized in that described several lead to The spacing in hole is 3~15mm.
CN201821663042.3U 2018-10-12 2018-10-12 A kind of measuring device of grapheme material interface resistance Active CN209372736U (en)

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Effective date of registration: 20240611

Address after: 510663 No.9, Keke Road, Huangpu District, Guangzhou City, Guangdong Province

Patentee after: Guangzhou Special Equipment Testing and Research Institute (Guangzhou Special Equipment Accident Investigation Technology Center Guangzhou Elevator Safety Operation Monitoring Center)

Country or region after: China

Address before: 510663 No.9, Keke Road, Huangpu District, Guangzhou City, Guangdong Province

Patentee before: GUANGZHOU SPECIAL PRESSURE EQUIPMENT INSPECTION AND Research Institute

Country or region before: China