CN115389875A - Integrated spacer testing device with integrated modular structure - Google Patents

Abstract

The invention discloses an integrated spacer testing device with an integrated modular structure, belonging to the technical field of spacer testing; the problems that when the existing spacer equipment is tested, the discharging condition of the spacer equipment under different humidity is inconvenient to test, the detection area is limited, and the heating of the spacer equipment is serious during long-time power-on detection are solved; the technical scheme is as follows: the device comprises a device shell, a support plate, a controller, a humidifier, a humidity sensor, an alarm and a spacing device main body, wherein the support plate is fixedly installed inside the device shell, and the controller is connected to the top end inside the device shell; the heat absorption plate is arranged on the heat absorption plate, and the heat dissipation plate is arranged on the heat absorption plate. The beneficial effects of the invention are as follows: the invention can test the discharge condition of the spacing device under different humidity, can improve the detection area of the spacing device, and can prevent the device from generating serious heat after long-time detection.

Description

Integrated spacer testing device with integrated modular structure

Technical Field

The invention relates to the technical field of spacer testing devices, in particular to an integrated spacer testing device with an integrated modular structure.

Background

Generally, in an area with relatively high air humidity, a closed space and various power equipment intervals are affected with damp more or less, the main reason is that a large amount of condensation exists due to temperature difference, after condensation attached to the equipment is formed through temperature difference, the insulation effect of the equipment is gradually reduced gradually and little by little along with the time, and partial discharge is caused, so that partial discharge test is usually carried out on the integrated interval equipment.

When testing interval equipment, the effectual test of being not convenient for is comparatively limited to interval equipment's detection area under different humidity simultaneously when detecting, can only test the discharge condition of fixed range usually, and when interval equipment carried out the circular telegram simultaneously, the self temperature of interval equipment during operation was not convenient for reduce to lead to appearing generating heat serious phenomenon after the interval equipment long-time circular telegram detects.

We have therefore proposed an integrated spacer test apparatus with an integrated modular structure in order to solve the problems set out above.

Disclosure of Invention

The invention aims to provide an integrated spacer testing device with an integrated modular structure, which solves the problems that the prior art in the market is inconvenient to effectively test the discharge condition of spacer equipment under different humidity, the detection area of the spacer equipment is limited during detection, the spacer equipment can only be used for testing the discharge condition in a fixed range, and the self temperature of the spacer equipment during working is inconvenient to reduce during power-on detection of the spacer equipment, so that the phenomenon of serious heating occurs after the spacer equipment is electrified and detected for a long time.

In order to achieve the purpose, the invention provides the following technical scheme: an integrated spacer testing device with an integrated modular structure comprises a device shell, a supporting plate, a controller, a humidifier, a humidity sensor, an alarm and a spacer main body, wherein the supporting plate is fixedly installed inside the device shell, the top end inside the device shell is connected with the controller, the humidifier is installed on the side of the controller, the humidity sensor is installed on the left side of the humidifier, the alarm is fixedly installed on the left side and the right side inside the device shell, and the spacer main body is placed at the upper end of the supporting plate;

further comprising:

the heat absorption plate is fixedly arranged in the middle of the upper end of the supporting plate, the lower end of the heat absorption plate is fixedly connected with a heat dissipation sheet, the heat dissipation sheet extends into the water tank, and a heat conduction mechanism is arranged on the heat dissipation sheet and is used for enabling the heat dissipation sheet to rapidly exchange heat with a water source and reduce the temperature;

the disc is arranged on the left side and the right side of the water tank, the middle part of the disc is fixedly arranged on an output shaft of back driving equipment, and the driving equipment is a servo motor;

the joint rod is used for connecting the disc and the piston block, the upper end of the piston block extends into the fixed plate, and the side of the fixed plate is communicated with the water tank through the water suction pipe;

the rack, fixed mounting is in the upper end of piston piece, the gear is installed to the avris of rack, and twines in the middle part pivot of gear and is connected with the stay cord, the upper end of stay cord is connected with the lower extreme of fixture block, and the avris of fixture block installs partial discharge detection sensor.

Preferably, the heat absorbing plate is embedded in the middle of the supporting plate, the lower ends of the heat absorbing plate and the spacing device main body are attached to each other, and radiating fins are uniformly distributed at the bottom of the heat absorbing plate.

Through adopting above-mentioned technical scheme, thereby can absorb the high temperature of interval equipment main part through the setting of absorber plate to make its heat transfer outwards give off on the fin through the absorber plate.

Preferably, heat conduction mechanism comprises floater, well core rod, regulation pole, flexure strip, bulge, supplementary gasbag and through-hole, and the floater is installed in the both sides of fin, well core rod of middle part fixedly connected with of floater, and install two on the well core rod and adjust the pole, the outside of adjusting the pole is installed the flexure strip, and the inboard of flexure strip outwards arches and forms the bulge, and is adjacent fixed mounting has supplementary gasbag between the flexure strip, the through-hole has been seted up to supplementary gasbag's avris.

Through adopting above-mentioned technical scheme, thereby utilize the setting of floater to make its floater can follow the height and the change of the inside liquid level of water tank.

Preferably, the end of the adjusting rod is attached to the protruding portion of the elastic sheet, the attaching surfaces of the protruding portion and the end of the adjusting rod are arranged to be inclined edges, and the elastic sheet is made of metal.

Through adopting above-mentioned technical scheme, thereby can extrude the bulge through the removal of adjusting the pole to make the flexure strip take place deformation.

Preferably, the elastic pieces are of arc-shaped structures, the auxiliary air bags fixed between the adjacent elastic pieces are made of elastic materials, and through holes are uniformly distributed in the auxiliary air bags.

Through adopting above-mentioned technical scheme, thereby can conveniently extrude supplementary gasbag through the deformation of flexure strip, thereby can absorb and discharge the water source of water tank inside through the elastic deformation of supplementary gasbag.

Preferably, the heat conduction mechanism comprises drive ball, stand, movable block, heat transfer spring, magnetic path, propulsion pole, the chamber that holds, cushion and locating hole, and the drive ball is installed in the both sides of fin, the middle part of drive ball passes through stand and movable block interconnect, and the below of movable block installs heat transfer spring, heat transfer spring fixed mounting is at the bottom avris of fin, and heat transfer spring's upper end and the lower extreme of movable block all install the magnetic path, install the propulsion pole on the movable block, and the internal connection of spring and movable block is passed through at the middle part of propulsion pole, the inside of movable block is provided with and holds the chamber, and holds the avris in chamber and install the cushion, the locating hole has been seted up to the avris that holds the chamber.

Through adopting above-mentioned technical scheme, thereby can make it hold the volume of intracavity portion and change through the deformation of cushion, can utilize the water source of locating hole to the water tank to pump from this.

Preferably, the magnetic block on the moving block and the magnetic block at the upper end of the heat conduction spring are the same in magnetism, and the moving block is connected with the radiating fins in a sliding mode.

By adopting the technical scheme, the distance between the magnetic block on the moving block and the magnetic block at the upper end of the heat-conducting spring is changed, so that the heat-conducting spring can be deformed and restored.

Preferably, the push rod and the moving block form an elastic telescopic structure through a spring, and the push rod and the elastic pad are located on the same vertical straight line.

Through adopting above-mentioned technical scheme, thereby can extrude the cushion on the collinear after the pushing ram atress removes.

Preferably, the rack and the gear form a meshing transmission structure, and a rotating shaft in the middle of the gear is in sliding connection with the fixing plate through a clamping block and a pull rope which are mutually connected.

Through adopting above-mentioned technical scheme, thereby can make the gear that the meshing is connected carry out the rolling to the stay cord after the rack removes, and then can stimulate the fixture block to remove on the fixed plate through the rolling of stay cord.

Compared with the prior art, the invention has the beneficial effects that:

1. the integrated spacer testing device with the integrated modular structure can test the discharge condition of the spacer under different humidity, can improve the detection area of the spacer, and can prevent the device from generating serious heat after long-time detection;

2. the controller is arranged, the humidifier can be controlled to humidify the interior of the device shell through the controller, the main body of the interval device is in a damp state, the humidity sensor can be used for detecting the humidity in the device shell, the humidity environment in the interval device can be changed when the main discharging of the interval device is detected, and the local discharging detection sensor can control the alarm to make a sound when the discharging condition is detected;

3. the device is provided with a piston block, a water source in the water tank can be sucked and discharged through the reciprocating movement of the piston block, so that the flowability of the water source in the water tank is increased, meanwhile, the gear can be rotated in a reciprocating manner by utilizing a rack after the piston block moves, a clamping block can be pulled by utilizing a pull rope to move in a reciprocating manner through the reciprocating rotation of the gear, the clamping block can be driven to change the position by utilizing the reciprocating movement of the clamping block, so that the partial discharge sensor can detect the discharge conditions in different areas, and meanwhile, in order to facilitate the resetting of the clamping block after the clamping block moves, the clamping block can be connected with the inside of a fixing plate through a spring for providing resetting elasticity;

4. be provided with the floater, when self produces high temperature in the interval equipment main part testing process, the temperature can be absorbed by the absorber plate, and with its heat transfer to fin and flexure strip, contact heat transfer through fin and flexure strip and water source, thereby can reduce the temperature of interval equipment main part, when the water source liquid level of water tank inside changes, thereby can make floater reciprocating motion and drive the regulation pole through well core rod and remove, the removal that utilizes the regulation pole can be lasted the extrusion to the flexure strip, thereby deformation through the flexure strip with recover and can make its holistic heat transfer scope take place dynamic change, utilize the deformation of flexure strip simultaneously and recover and can last the extrusion to supplementary gasbag, come the water source around the flexure strip to suction through supplementary gasbag and discharge, and then come further improvement flexure strip and the heat transfer effect of fin and water source with this.

Drawings

FIG. 1 is a schematic cross-sectional front view of the present invention;

FIG. 2 is a schematic flow chart of a control system according to the present invention;

FIG. 3 is a cross-sectional view of the fixing plate and rack of the present invention;

FIG. 4 is an enlarged schematic view of the structure at A in FIG. 1 according to the present invention;

FIG. 5 is a schematic cross-sectional view of a first embodiment of a heat conducting mechanism according to the present invention;

FIG. 6 is a schematic front view of a second embodiment of a heat conducting mechanism according to the present invention;

FIG. 7 is a schematic cross-sectional front view of a second embodiment of a heat transfer mechanism according to the present invention;

FIG. 8 is a schematic cross-sectional view of the push rod and the resilient pad of the present invention.

In the figure: 1. a device housing; 2. a support plate; 3. a controller; 4. a humidifier; 5. a humidity sensor; 6. an alarm; 7. a spacer device body; 8. a heat absorbing plate; 9. a heat sink; 10. a water tank; 11. a heat conducting mechanism; 111. a floating ball; 112. a center pole; 113. adjusting a rod; 114. an elastic sheet; 115. a projection; 116. an auxiliary air bag; 117. a through hole; 1101. a drive ball; 1102. a column; 1103. a moving block; 1104. a heat conductive spring; 1105. a magnetic block; 1106. a push rod; 1107. an accommodating chamber; 1108. an elastic pad; 1109. positioning holes; 12. a disc; 13. a connecting rod; 14. a piston block; 15. a fixing plate; 16. a suction pipe; 17. a rack; 18. a gear; 19. pulling a rope; 20. a clamping block; 21. a partial discharge detection sensor.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

The first embodiment is as follows:

referring to fig. 1-8, the present embodiment provides a technical solution:

an integrated spacer testing device with an integrated modular structure is shown in fig. 1-5 and comprises a device shell 1, a support plate 2, a controller 3, a humidifier 4, a humidity sensor 5, an alarm 6 and a spacer main body 7, wherein the support plate 2 is fixedly installed inside the device shell 1, the controller 3 is connected to the top end inside the device shell 1, the humidifier 4 is installed on the side of the controller 3, the humidity sensor 5 is installed on the left side of the humidifier 4, the alarm 6 is fixedly installed on the left side and the right side inside the device shell 1, and the spacer main body 7 is placed at the upper end of the support plate 2; further comprising: the heat absorption plate 8 is fixedly arranged in the middle of the upper end of the supporting plate 2, the lower end of the heat absorption plate 8 is fixedly connected with a heat dissipation fin 9, the heat dissipation fin 9 extends into the water tank 10, and the heat conduction mechanism 11 is arranged on the heat dissipation fin 9 and used for enabling the heat dissipation fin 9 to rapidly exchange heat with a water source and reduce the temperature; the heat conducting mechanism 11 is composed of a floating ball 111, a central rod 112, adjusting rods 113, elastic sheets 114, a protruding portion 115, an auxiliary air bag 116 and a through hole 117, the floating ball 111 is installed on two sides of the heat radiating fin 9, the central rod 112 is fixedly connected to the middle of the floating ball 111, the two adjusting rods 113 are installed on the central rod 112, the elastic sheets 114 are installed on the outer sides of the adjusting rods 113, the inner sides of the elastic sheets 114 are arched outwards to form the protruding portion 115, the auxiliary air bag 116 is fixedly installed between the adjacent elastic sheets 114, and the through hole 117 is formed in the side of the auxiliary air bag 116. The end of the adjustment lever 113 and the protrusion 115 of the elastic sheet 114 are attached to each other, the attachment surface of the protrusion 115 and the end of the adjustment lever 113 is formed as a bevel edge, and the elastic sheet 114 is formed of a metal material. The elastic pieces 114 are arranged into an arc-shaped structure, the auxiliary air bags 116 fixed between the adjacent elastic pieces 114 are made of elastic materials, and through holes 117 are uniformly distributed on the auxiliary air bags 116. The disc 12 is arranged on the left side and the right side of the water tank 10, the middle part of the disc 12 is fixedly arranged on an output shaft of back driving equipment, and the driving equipment is a servo motor; the joint rod 13 is used for connecting the disc 12 and the piston block 14, the upper end of the piston block 14 extends into the fixing plate 15, and the side of the fixing plate 15 is communicated with the water tank 10 through the suction pipe 16; the rack 17 is fixedly installed at the upper end of the piston block 14, the gear 18 is installed at the side of the rack 17, the pull rope 19 is wound and connected on the rotating shaft of the middle part of the gear 18, the upper end of the pull rope 19 is connected with the lower end of the fixture block 20, and the partial discharge detection sensor 21 is installed at the side of the fixture block 20. The absorber plate 8 is embedded in the middle of the supporting plate 2, the lower ends of the absorber plate 8 and the spacing device main body 7 are attached to each other, and radiating fins 9 are uniformly distributed at the bottom of the absorber plate 8. The rack 17 and the gear 18 form a meshing transmission structure, and a rotating shaft in the middle of the gear 18 is in sliding connection with the fixing plate 15 through a fixture block 20 which is connected with each other through a pull rope 19.

The working principle of the embodiment is as follows: when the interval device main body 7 needs to be subjected to discharge detection in a damp environment, the interval device main body 7 is placed at the upper end of the supporting plate 2 and is powered on, the humidifier 4 is started through the controller 3 to humidify the environment inside the device shell 1, the humidity inside the device shell 1 can be detected through the humidity sensor 5, so that the humidity inside the device shell 1 can be controlled in real time in the detection process, then the servo motor on the back of the disc 12 is started, the disc 12 can rotate through the starting of the servo motor, the piston block 14 is pushed to reciprocate inside the fixing plate 15 through the movably connected joint rod 13, the fixedly connected rack 17 can drive the gear 18 to synchronously rotate after the piston block 14 moves downwards, the local discharge detection sensor 21 can be driven to move by the pull of the clamp block 20 through the rotation of the gear 18, the end part of the clamp block 20 can be connected with the inside of the fixing plate 15 through the spring after the piston block 14 moves upwards, the gear 18 can reversely rotate after the rack 17 moves upwards, thereby the clamp block 20 can drive the local discharge detection sensor 21 to move, when the local discharge detection sensor 21 drives the clamp block 20 to drive the local discharge detection sensor to move upwards, the high-temperature detection area, the high-temperature detection of the interval device main body 7 can be prevented from being detected by the high temperature detection area, and the high temperature detection alarm detection area can be prevented by the high temperature detection area of the interval detection device when the interval detection device 7, the absorbed temperature is transmitted to the heat radiating fins 9 and the elastic sheets 114, the temperature is reduced through the heat exchange between the heat radiating fins 9 and the elastic sheets 114 and a water source, when the piston block 14 moves in a reciprocating manner, the water source inside the water tank 10 can be sucked and discharged through the water suction pipe 16, so that the fluidity of the water source inside the water tank 10 can be increased, the overall heat exchange effect is improved, when the water source is sucked and discharged, the liquid level inside the water tank 10 can be changed, the floating ball 111 can drive the adjusting rod 113 to move up and down through the central rod 112 through the height change of the liquid level, the protruding part 115 can be extruded after the adjusting rod 113 moves down, so that the elastic sheets 114 are expanded, when the adjusting rod 113 moves up, the elastic sheets 114 are restored, the heat exchange range between the water source and the water source can be dynamically changed through the expansion and restoration of the elastic sheets 114, and the auxiliary air bags 116 can be continuously extruded after the elastic sheets 114 are expanded and restored, the water source can be sucked through the through holes 117 by the deformation and the restoration of the elastic sheets 114, so that the flow rate around the water source can be increased, and the temperature of the heat radiating fins 9 and the water source can be quickly absorbed by the auxiliary air bags 116.

The second embodiment:

the integrated spacer testing device with the integrated modular structure disclosed in the embodiment is an improvement made on the basis of the technical scheme of the first embodiment, in the first embodiment, the heat conducting mechanism 11 is composed of a floating ball 111, a central rod 112, an adjusting rod 113, elastic sheets 114, protruding portions 115, auxiliary air bags 116 and through holes 117, the floating ball 111 is installed on two sides of the radiating fin 9, the central rod 112 is fixedly connected to the middle of the floating ball 111, the two adjusting rods 113 are installed on the central rod 112, the elastic sheets 114 are installed on the outer sides of the adjusting rods 113, the inner sides of the elastic sheets 114 are arched outwards to form the protruding portions 115, the auxiliary air bags 116 are fixedly installed between the adjacent elastic sheets 114, and the through holes 117 are formed in the side edges of the auxiliary air bags 116.

In this embodiment, as shown in fig. 1 and fig. 6 to 8, the heat conducting mechanism 11 includes a driving ball 1101, a vertical column 1102, a moving block 1103, a heat conducting spring 1104, magnetic blocks 1105, a pushing rod 1106, an accommodating cavity 1107, an elastic pad 1108 and a positioning hole 1109, the driving ball 1101 is installed on two sides of the heat sink 9, the middle portion of the driving ball 1101 is connected with the moving block 1103 through the vertical column 1102, the heat conducting spring 1104 is installed below the moving block 1103, the heat conducting spring 1104 is fixedly installed on the bottom side of the heat sink 9, the magnetic blocks 1105 are installed on the upper end of the heat conducting spring 1104 and the lower end of the moving block 1103, the pushing rod 1106 is installed on the moving block 1103, the middle portion of the pushing rod 1106 is connected with the inside of the moving block 1103 through a spring, the accommodating cavity 1107 is arranged inside the moving block 1103, the elastic pad 1108 is installed on the side of the accommodating cavity 1107, and the positioning hole 1109 is opened on the side of the accommodating cavity 1107. The magnetic block 1105 on the moving block 1103 has the same magnetism as the magnetic block 1105 at the upper end of the heat conductive spring 1104, and the moving block 1103 and the heat sink 9 are connected in a sliding manner. The pushing rod 1106 and the moving block 1103 form an elastic telescopic structure, and the pushing rod 1106 and the elastic pad 1108 are positioned on the same vertical straight line.

The working principle of the embodiment is as follows: when the piston block 14 reciprocates and sucks the water source in the water tank 10 through the water suction pipe 16, so that the liquid level of the water source in the water tank 10 changes, the driving balls 1101 at the side of the radiating fins 9 move up and down along with the change of the liquid level, the vertical columns 1102 at the middle part can be used for driving the moving block 1103 to move synchronously through the up and down movement of the driving balls 1101, after the moving block 1103 moves downwards, the distance between the magnetic blocks 1105 on the moving block 1103 and the magnetic blocks 1105 on the heat conducting spring 1104 can be close, so that the heat conducting spring 1104 is compressed through repulsive magnetic force, when the moving block 1103 moves upwards, the distance between the magnetic blocks 1105 on the moving block 1103 and the magnetic blocks 1105 on the heat conducting spring 1104 is increased, the heat conducting spring 1104 is restored through the elasticity of the heat conducting spring 1104, after the moving block 1103 moves downwards, the heat exchange range between the water source and the water source can be changed dynamically, meanwhile, after the moving block 1103 moves downwards, the pushing rod 1106 and the side of the radiating fins 9 can be abutted against the elastic pad 1108 and can be pressed against the elastic pad 1108 after the pushing rod is pressed, after the pushing rod 1103 moves upwards, so that the water source and the heat conducting spring 1108 and the water source can be discharged through the elastic pad 1108, and the heat conducting spring 1104, and the heat conducting spring can be discharged through the elastic pad 1108, and the heat exchange chamber 1109, and the heat conducting spring can be increased, and the heat conducting spring 1104, and the heat conducting spring can be discharged by utilizing the heat exchange volume of the heat conducting spring 1109.

Those not described in detail in this specification are within the skill of the art.

Although the present invention has been described in detail with reference to the foregoing embodiments, it will be apparent to those skilled in the art that modifications may be made to the embodiments described in the foregoing embodiments, or equivalents may be substituted for elements thereof.

Claims (9)

1. An integrated spacer testing device with an integrated modular structure comprises a device shell (1), a supporting plate (2), a controller (3), a humidifier (4), a humidity sensor (5), an alarm (6) and a spacer main body (7), wherein the supporting plate (2) is fixedly installed inside the device shell (1), the controller (3) is connected to the top end inside the device shell (1), the humidifier (4) is installed on the side of the controller (3), the humidity sensor (5) is installed on the left side of the humidifier (4), the alarm (6) is fixedly installed on the left side and the right side inside the device shell (1), and the spacer main body (7) is placed at the upper end of the supporting plate (2);

it is characterized by also comprising:

the heat absorption plate (8) is fixedly arranged in the middle of the upper end of the supporting plate (2), the lower end of the heat absorption plate (8) is fixedly connected with a heat dissipation sheet (9), the heat dissipation sheet (9) extends into the water tank (10), and a heat conduction mechanism (11) is arranged on the heat dissipation sheet (9) and used for enabling the heat dissipation sheet (9) to rapidly exchange heat with a water source and reduce the temperature;

the disc (12) is arranged on the left side and the right side of the water tank (10), the middle part of the disc (12) is fixedly arranged on an output shaft of back driving equipment, and the driving equipment is a servo motor;

the joint rod (13) is used for connecting the disc (12) and the piston block (14), the upper end of the piston block (14) extends into the fixing plate (15), and the side of the fixing plate (15) is communicated with the water tank (10) through a water suction pipe (16);

rack (17), fixed mounting is in the upper end of piston piece (14), gear (18) are installed to the avris of rack (17), and the winding is connected with stay cord (19) in the middle part pivot of gear (18), the upper end of stay cord (19) is connected with the lower extreme of fixture block (20), and partial discharge detection sensor (21) are installed to the avris of fixture block (20).

2. An integrated spacer test apparatus with integrated modular structure as claimed in claim 1, wherein: the heat absorbing plate (8) is embedded in the middle of the supporting plate (2), the lower ends of the heat absorbing plate (8) and the spacing device main body (7) are attached to each other, and radiating fins (9) are uniformly distributed at the bottom of the heat absorbing plate (8).

3. An integrated spacer test apparatus with integrated modular structure as claimed in claim 1, wherein: heat-conducting mechanism (11) comprises floater (111), well core rod (112), regulation pole (113), flexure strip (114), bulge (115), supplementary gasbag (116) and through-hole (117), and floater (111) installs the both sides in fin (9), well core rod (112) of the middle part fixedly connected with of floater (111), and install two on well core rod (112) and adjust pole (113), adjust the outside of pole (113) and install flexure strip (114), and the inboard of flexure strip (114) outwards arches and forms bulge (115), and is adjacent fixed mounting has supplementary gasbag (116) between flexure strip (114), through-hole (117) have been seted up to the avris of supplementary gasbag (116).

4. An integrated spacer test apparatus with integrated modular structure as claimed in claim 3, wherein: the end part of the adjusting rod (113) is attached to the protruding part (115) on the elastic sheet (114), the attaching surface of the protruding part (115) and the end part of the adjusting rod (113) is arranged to be a bevel edge, and the elastic sheet (114) is arranged to be made of metal.

5. An integrated spacer test fixture with integrated modular structure as recited in claim 4 wherein: the elastic pieces (114) are arranged to be of arc-shaped structures, the auxiliary air bags (116) fixed between the adjacent elastic pieces (114) are made of elastic materials, and through holes (117) are uniformly distributed in the auxiliary air bags (116).

6. An integrated spacer test apparatus with integrated modular structure as claimed in claim 1 or 3, characterized in that: heat conduction mechanism (11) comprise drive ball (1101), stand (1102), movable block (1103), heat conduction spring (1104), magnetic path (1105), pushing ram (1106), holding chamber (1107), elastic pad (1108) and locating hole (1109), and drive ball (1101) installs the both sides at fin (9), the middle part of drive ball (1101) is through stand (1102) and movable block (1103) interconnect, and installs heat conduction spring (1104) below movable block (1103), heat conduction spring (1104) fixed mounting is in the bottom avris of fin (9), and magnetic path (1105) are all installed to the upper end of heat conduction spring (1104) and the lower extreme of movable block (1103), install pushing ram (1106) on movable block (1103), and the middle part of pushing ram (1106) passes through the internal connection of spring and movable block (1103), the inside of movable block (1103) is provided with holding chamber (1107), and holds the avris of chamber (1107), and holds avris of chamber (1107) and installs elastic pad (1109).

7. An integrated spacer test apparatus with integrated modular structure as claimed in claim 6, wherein: the magnetic blocks (1105) on the moving block (1103) are the same as the magnetic blocks (1105) at the upper end of the heat conduction spring (1104), and the moving block (1103) is in sliding connection with the radiating fins (9).

8. An integrated spacer test apparatus with integrated modular structure as claimed in claim 6, wherein: the push rod (1106) and the moving block (1103) form an elastic telescopic structure through a spring, and the push rod (1106) and the elastic pad (1108) are located on the same vertical straight line.

9. An integrated spacer test apparatus with integrated modular structure as claimed in claim 1, wherein: the rack (17) and the gear (18) form a meshing transmission structure, and a middle rotating shaft of the gear (18) is in sliding connection with the fixing plate (15) through a clamping block (20) and a pull rope (19) which are connected with each other.

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