CN219417632U - Withstand voltage testing arrangement - Google Patents

Abstract

The utility model is suitable for the technical field of electronic component electric testing, and provides a pressure-resistant testing device which comprises a shell, a feeding mechanism, a testing mechanism, a discharging mechanism, a first grabbing mechanism and a second grabbing mechanism; receiving the electronic element through the feeding mechanism and conveying the electronic element to a preset feeding position; through first grabbing mechanism, will be located the electronic component who presets the loading position and shift to testing mechanism to through second grabbing mechanism after the withstand voltage test of testing mechanism, will survey electronic component and shift to unloading mechanism, carry the unloading position in preseting through unloading mechanism at last, automatic level is high, and production efficiency can improve.

Description

Withstand voltage testing arrangement

Technical Field

The utility model belongs to the technical field of electronic component electric testing, and particularly relates to a voltage withstanding testing device.

Background

Withstand voltage test (test) is one of the main methods of checking the capability of an electric appliance, an electric device, an electric apparatus, an electric circuit, an electric safety appliance, and the like to withstand an overvoltage. The electrical equipment can find out the local defect, damp and aging of insulation through a voltage withstand test. Some common electronic components, including transformer, coil etc. generally all need carry out withstand voltage test, and current withstand voltage test equipment general simple structure needs the manual work to go up the unloading to the electronic components that needs to test, and degree of automation is relatively lower, can't realize the full-automatic test to electronic components.

Disclosure of Invention

The utility model aims to at least overcome one of the defects in the prior art, and provides a pressure-resistant testing device which can realize full-automatic pressure-resistant testing of electronic elements, has high degree of automation and improves production efficiency.

The technical scheme of the utility model is as follows: a pressure-resistant testing device comprises an installation platform, a feeding mechanism, a testing mechanism, a discharging mechanism, a first grabbing mechanism and a second grabbing mechanism; the feeding mechanism is arranged on the mounting platform and is used for receiving the electronic components and conveying the electronic components to a preset feeding position; the testing mechanism is arranged on the mounting platform and used for testing the pressure resistance of the electronic element; the blanking mechanism is arranged on the mounting platform and used for conveying the tested electronic element to a preset blanking position; the first grabbing mechanism is arranged on the mounting platform and used for transferring the electronic element positioned at the preset feeding position to the testing mechanism; the second grabbing mechanism is arranged on the mounting platform and used for transferring the tested electronic element to the blanking mechanism.

As a further improvement of the technical scheme, the first grabbing mechanism comprises a first grabbing component and a first conveying component, the first grabbing component is used for grabbing the electronic component located at the preset feeding position, and the first conveying component is used for driving the first grabbing component to reciprocate between the preset feeding position and the testing mechanism so as to transfer the electronic component located at the preset feeding position to the testing mechanism.

As a further improvement of the technical scheme, the first grabbing component comprises two clamping jaws, a first clamping cylinder, a first cylinder and a rotary cylinder, wherein the first cylinder is arranged on the first conveying component and can drive the rotary cylinder in the vertical direction, the rotary cylinder is connected with the first clamping cylinder, the two clamping jaws are oppositely arranged on the first clamping cylinder, and the first clamping cylinder is used for driving the two clamping jaws to move in opposite directions or in opposite directions.

As a further improvement of the technical scheme, an elastic piece with one end used for propping against the electronic element is arranged between the two clamping jaws, and the elastic piece applies elastic force to the clamped material to enable the clamped material to be separated from the clamping jaws.

As a further improvement of the technical scheme, the mounting platform is provided with a supporting frame, and the first conveying assembly comprises a transmission piece fixedly connected with the grabbing mechanism and a driving piece connected with the transmission piece and used for driving the transmission piece to transversely move; the driving piece is arranged on the supporting frame.

As a further improvement of the technical scheme, the feeding mechanism comprises a vibration source and a feeding guide rail which is arranged at the top of the vibration source and is driven by the vibration source to be used for transmitting electronic elements; the transmission tail end of the feeding guide rail is provided with a first inclined plane; the feeding mechanism comprises a supporting block, the supporting block is arranged on the mounting platform, a second inclined plane is arranged on the supporting block, the second inclined plane is located below the first inclined plane, the second inclined plane is attached to the first inclined plane, and a stop block for stopping an electronic element transmitted to the transmission tail end of the feeding guide rail is arranged on the supporting block.

As a further improvement of the technical scheme, the blanking mechanism comprises an induction piece, a blanking bracket, a blanking transmission piece for conveying electronic elements and a blanking driving assembly connected with the blanking transmission piece and used for driving the blanking transmission piece to move, wherein the blanking transmission piece is arranged on the blanking bracket; the two sides of the blanking transmission piece are provided with blanking guide rails; the sensing piece is arranged on the blanking guide rail and located at the transmission tail end of the blanking transmission piece, and the sensing piece is used for sensing whether an electronic element exists on the blanking guide rail.

As a further improvement of the technical scheme, the test mechanism comprises comprehensive test equipment and a thimble assembly, the electronic element is placed on the comprehensive test equipment through the test fixture and is conducted with the comprehensive test equipment, and the comprehensive test equipment is electrically connected with the thimble assembly and applies test voltage to the electronic element through the thimble assembly.

As a further improvement of the technical scheme, the blanking mechanism comprises an induction piece, a blanking bracket, a blanking transmission piece for conveying electronic elements and a blanking driving assembly connected with the blanking transmission piece and used for driving the blanking transmission piece to move, wherein the blanking transmission piece is arranged on the blanking bracket; the two sides of the blanking transmission piece are provided with blanking guide rails; the sensing piece is arranged on the blanking guide rail and is used for sensing whether an electronic element exists on the blanking guide rail or not.

As a further improvement of the technical scheme, the test mechanism comprises comprehensive test equipment and a thimble assembly, the electronic element is placed on the comprehensive test equipment through the test fixture and is conducted with the comprehensive test equipment, and the comprehensive test equipment is electrically connected with the thimble assembly and applies test voltage to the electronic element through the thimble assembly.

As a further improvement of the technical scheme, the test fixture is provided with an electric contact point electrically connected with an electronic element, and the electronic element is placed on the test fixture and is communicated with the comprehensive test device through the electric contact point; one side of the test jig is provided with a pressure-resistant test cylinder, and the pressure-resistant test cylinder drives the thimble assembly to be close to or far away from the electronic element.

As a further improvement of the technical scheme, the pressure-resistant testing device further comprises a shell and an adjusting component for adjusting the height of the testing mechanism, wherein the adjusting component comprises a plurality of guide rods, a mounting plate and a connecting rod, one end of the guide rod is fixedly connected with the shell, and the connecting height of the mounting plate relative to the guide rods is adjustable; the testing mechanism is fixedly connected to the mounting plate.

The utility model provides a pressure-resistant testing device which comprises a shell, a feeding mechanism, a testing mechanism, a discharging mechanism, a first grabbing mechanism and a second grabbing mechanism, wherein an electronic element is received through the feeding mechanism and is conveyed to a preset feeding position; through first grabbing mechanism, will be located the electronic component who presets the loading position and shift to testing mechanism to through second grabbing mechanism after the withstand voltage test of testing mechanism, will survey electronic component and shift to unloading mechanism, carry the unloading position in preseting through unloading mechanism at last, automatic level is high, and production efficiency can improve.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present utility model, the drawings that are needed in the embodiments will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the present utility model, and other drawings may be obtained according to these drawings without inventive effort for a person skilled in the art.

FIG. 1 is a schematic diagram of a pressure-resistant testing device according to an embodiment of the present utility model;

FIG. 2 is a schematic diagram of another structure of a pressure-resistant testing device according to an embodiment of the present utility model;

FIG. 3 is a schematic diagram of another structure of a pressure-resistant testing apparatus according to an embodiment of the present utility model;

FIG. 4 is an enlarged view of a portion of FIG. 2 at A;

FIG. 5 is a partial enlarged view at B in FIG. 3;

FIG. 6 is a schematic structural diagram of a testing mechanism in a pressure-resistant testing device according to an embodiment of the present utility model;

fig. 7 is a schematic structural diagram of a feeding mechanism in a pressure-resistant testing device according to an embodiment of the present utility model.

Detailed Description

The present utility model will be described in further detail with reference to the drawings and examples, in order to make the objects, technical solutions and advantages of the present utility model more apparent. It should be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the scope of the utility model.

It should be noted that the terms "disposed" and "connected" should be construed broadly, and may be, for example, directly disposed or connected, or indirectly disposed or connected through a central element or a central structure.

In addition, in the embodiments of the present utility model, terms of directions or positional relationships indicated by "longitudinal", "transverse", "length", "width", "thickness", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", etc., are directions or positional relationships based on the directions or positional relationships shown in the drawings or the conventional placement state or use state, are merely for convenience of describing the present utility model and simplifying the description, and do not indicate or imply that the structures, features, devices or elements to be referred to must have specific directions or positional relationships nor must be constructed and operated in specific directions, and thus should not be construed as limiting the present utility model. In the description of the present utility model, unless otherwise indicated, the meaning of "a plurality" is two or more.

The various features and embodiments described in the detailed description may be combined in any suitable manner, for example, different embodiments may be formed by different combinations of features/embodiments, where not contradictory, and various possible combinations of features/embodiments in the present utility model are not described further in order to avoid unnecessary repetition.

As shown in fig. 1 to 7, the pressure-resistant testing device provided by the embodiment of the utility model comprises a casing 1, a feeding mechanism 2, a testing mechanism 3, a discharging mechanism 8, a first grabbing mechanism 4 and a second grabbing mechanism 5, wherein an installation platform 11 is arranged in the casing 1; in other embodiments, the housing 1 may not be included; in this embodiment, the feeding mechanism 2 includes a first end extending out of the casing 1 and a second end extending into the casing 1, the feeding mechanism 2 is disposed on the mounting platform 11 and is used for conveying the electronic component to be tested from the first end to the second end, that is, a preset feeding position is located at the second end, and the feeding mechanism 2 is used for receiving the electronic component and conveying the electronic component to a preset feeding position; the test mechanism 3 is arranged on the mounting platform 11 and is used for testing the pressure resistance of the electronic element; the blanking mechanism 8 is arranged on the mounting platform 11 and is used for conveying the tested electronic components to a set point; the first grabbing mechanism 4 is arranged on the mounting platform 11 and is used for transferring the electronic component positioned at the preset loading position to the testing mechanism 3; the second grabbing mechanism 5 is arranged on the mounting platform 11 and is used for transferring the tested electronic component to the blanking mechanism 8. In this embodiment, the second gripping mechanism 5 has the same structure as the first gripping mechanism 4, and of course, in other embodiments, the second gripping mechanism 5 may have a different structure from the first gripping mechanism 4; according to the pressure-resistant testing device provided by the utility model, the electronic element is received by the feeding mechanism 2 and is conveyed to a preset feeding position; the electronic components located at the preset feeding position are transferred to the testing mechanism 3 through the first grabbing mechanism 4, the tested electronic components are transferred to the blanking mechanism 8 through the second grabbing mechanism 5 after the pressure resistance test of the testing mechanism 3, and finally the tested electronic components are conveyed to the preset blanking position through the blanking mechanism 8, so that the automation level is high, and the production efficiency is improved.

Further, the first grabbing mechanism 4 comprises a first grabbing component and a first conveying component 6, the first grabbing component is used for grabbing electronic components located at a preset feeding position, and the first conveying component 6 is used for driving the first grabbing component to reciprocate between the preset feeding position and the testing mechanism 3 so as to transfer the electronic components located at the preset feeding position to the testing mechanism 3.

Further, the first grabbing assembly includes two clamping jaws 451, a first clamping cylinder 452, a first cylinder 455 and a rotating cylinder 453, the first cylinder 455 is disposed on the first conveying assembly 6 and can drive the rotating cylinder 453 in a vertical direction, the rotating cylinder 453 is connected to the first clamping cylinder 452, and the two clamping jaws 451 are disposed on the first clamping cylinder 452 in opposition to each other; the first clamping cylinder 452 is connected with the two clamping jaws 451, and the two clamping jaws 451 are arranged opposite to each other, and the first clamping cylinder 452 is used for driving the two clamping jaws 451 to move towards or away from each other so as to clamp or release an electronic component; specifically, one clamping jaw 451 is fixedly connected to one side of the clamping cylinder 452, and the other clamping jaw 451 is fixedly connected to the other side of the clamping cylinder 452; in this embodiment, the second grabbing mechanism 5 has the same structure as the first grabbing mechanism 4, and the second grabbing mechanism 5 includes a second grabbing component and a second conveying component 7, where the second grabbing component has the same structure as the first grabbing component.

Further, an elastic member 454 with one end for abutting against the electronic component is arranged between the two clamping jaws 451, and the elastic member 454 applies elastic force to the clamped material (i.e. the electronic component) to separate from the clamping jaws 451; the first grabbing assembly further comprises a first air cylinder 455, wherein the first air cylinder 455 is connected to a rotary air cylinder 453 for driving the rotary air cylinder 453 to longitudinally slide so that the elastic member 454 abuts against the electronic component. Specifically, the first air cylinder 455 drives the rotary air cylinder 453 through the connecting piece to move along the longitudinal direction (Y axis), the rotary air cylinder 453 may drive the first clamping air cylinder 452 to rotate, and the first clamping air cylinder 452 may drive the two clamping jaws 451 to clamp the material through the two clamping jaws 451. In this embodiment, an elastic member 454 is disposed between the two clamping jaws 451, the elastic member 454 is fixedly connected with the first clamping cylinder 452 by a mounting bracket 457, when a material (i.e. an electronic component) is clamped, the elastic member 454 moves to a position right above the material, then moves downward under the action of the first cylinder 455 until the elastic member 454 is abutted against one end of the material and compressed under the action of the abutment until the two clamping jaws 451 are respectively located at two sides of the material, and then the two clamping jaws 451 clamp the material under the action of the first clamping cylinder 452. When the material needs to be released, for example, the material needs to be placed on the testing mechanism 3 for pressure resistance testing, the two clamping jaws 451 move back to back and release the material, and then the elastic piece 454 supports the material under the action of resilience force, so that the material can be effectively prevented from being adhered to the clamping jaws 451.

Further, the mounting platform 11 is provided with a supporting frame 12, and the first conveying assembly 6 comprises a transmission member 671 fixedly connected with the grabbing mechanism, and a driving member 672 connected with the transmission member 671 and used for driving the transmission member 671 to move transversely; the driving member 672 is disposed on the support frame 12. The second gripping means 5 may comprise a second gripping assembly and a second transfer assembly 7, the second transfer assembly 7 being structurally identical to the first transfer assembly 6; specifically, the driving member 672 may be a driving motor, the first conveying component 6 is a belt wheel transmission mechanism, the driving member 671 is a belt, and the belt is fixedly connected with a first grabbing component, so as to drive the grabbing mechanism grabbing the electronic component to slide laterally. Of course, in another embodiment, the electronic components may be transported by a sprocket drive or other drive.

Further, the support frame 12 is further provided with a sliding guide rail 673 parallel to the transmission member 671, the grabbing mechanism comprises a fixed component 456 with one side fixedly connected to the first cylinder 455, and one end of the fixed component 456 is fixedly connected to the transmission member 671; the other end of the fixing member 456 is slidably disposed on the sliding rail 673, and the other end of the fixing member 456 is fixedly connected to the driving member 671. The fixing member 456 includes a slider 456a for sliding along the slide rail 673 so that the first gripper assembly gripping the electronic component can slide laterally along the slide rail 673.

Further, the feeding mechanism 2 comprises a vibration feeder; the vibration feeder comprises a vibration source 21 and a feeding guide rail 22 which is arranged at the top of the vibration source 21 and is driven by the vibration source 21 to be used for conveying electronic elements. The conveying end of the feeding guide rail 22 is provided with a first inclined plane 221; the end of the feeding guide rail 22 is provided with a supporting block 23, and one end of the supporting block 23, which is close to the feeding guide rail 22, is provided with a second inclined plane 231 which is connected with the first inclined plane 221; the supporting block 23 is arranged on the mounting platform 11; when the feeding guide rail is installed, the second inclined plane 231 is positioned below the first inclined plane 221, the second inclined plane 231 is attached to the first inclined plane 221 and supports the first inclined plane 221, so that the deformation of the transmission tail end of the feeding guide rail 22, which extends out of the vibration source 21, is prevented under the action of gravity; the support block 23 is provided with a stop block 24, which can stop the electronic component conveyed to the conveying end of the feeding guide rail 22, specifically, one end of the support block 23 away from the feeding guide rail 22 is provided with a stop block 24 for stopping the electronic component, and the stop block 24 is fixed on the support block 23, so that the first grabbing component can grab the electronic component to be detected at the station. In this embodiment, the electronic component is placed at one end of the feeding rail 22, and the vibration source 21 drives the feeding rail 22 to vibrate, so that the electronic component placed on the feeding rail 22 is conveyed to the other end located in the casing 1.

Further, the blanking mechanism 8 includes a sensing member 85, a blanking bracket 81, a blanking transmission member 82 for conveying electronic components, and a blanking driving assembly 83 connected to the blanking transmission member 82 for driving the blanking transmission member 82 to move, wherein the blanking transmission member 82 is disposed on the blanking bracket 81; the two sides of the blanking transmission member 82 are provided with blanking guide rails 84; the sensing element 85 is disposed on the discharging guide rail 84 and located at the transmission end of the discharging transmission element 82, and the sensing element 85 is used for sensing whether an electronic element exists on the discharging guide rail 84; specifically, the discharging mechanism 8 is a belt driving mechanism, the discharging driving member 82 is a belt, the electronic component is located on the belt, and the sensing member 85 may be a photoelectric sensor, for detecting whether the electronic component is placed on the belt.

Further, the test mechanism 3 includes a comprehensive test device 32 and a thimble assembly 31, the thimble assembly 31 is used for being abutted against an electronic component, the comprehensive test device 32 is electrically connected to the thimble assembly 31 for applying voltage to the electronic component, the electronic component is placed on the comprehensive test device 32 through a test fixture 33 and is conducted with the comprehensive test device 32, and the comprehensive test device 32 is electrically connected with the thimble assembly 31 and applies test voltage to the electronic component through the thimble assembly 31. Specifically, the test mechanism 3 may be provided with more than two test units for further testing and ensuring the validity, or a plurality of test procedures may improve the test efficiency.

Further, the test fixture 33 is provided with an electrical contact point electrically connected with an electronic component, and the electronic component is placed on the test fixture 33 and is conducted with the comprehensive test device 32 through the electrical contact point; one side of the test fixture 33 is provided with a pressure-resistant test cylinder 34, and the pressure-resistant test cylinder 34 drives the thimble assembly 31 to approach or separate from the electronic component. In a specific application, the test mechanism 3 further includes a test fixture 33 electrically connected to the comprehensive test device 32, and a pressure-resistant test cylinder 34 for driving the thimble assembly 31 to slide; the test fixture 33 is provided with a conducting plug-in unit for conducting contact with the electronic element; the comprehensive testing equipment 32 is provided with a mounting position for mounting the testing jig 33; the pressure-resistant test cylinder 34 is located at one side of the test jig 33; the test mechanism 3 further comprises a positioning cylinder assembly 35 arranged at the top of the comprehensive testing device 32 and used for propping against one side of the test fixture 33; the pressure-resistant testing device also comprises an adjusting component 9 for adjusting the height of the testing mechanism 3, wherein the adjusting component 9 comprises a plurality of guide rods, a mounting plate and a pressure-resistant device, wherein one end of each guide rod is fixedly connected with the casing 1, the mounting plate is connected with the guide rods, and the connecting height of the mounting plate relative to the guide rods is adjustable; the test mechanism 3 is fixedly connected to the mounting plate. In a specific application, the test fixture 33 may be electrically connected to the comprehensive test device 32 through the conductive plug-in. In this embodiment, the test fixture 33 may be replaced according to the materials to be tested, so as to ensure the applicability of the pressure-resistant test device; the end of the positioning cylinder assembly 35 is provided with a jacking block, and the positioning cylinder can prop against the testing jig 33 through the jacking block, so that the testing jig 33 moves to the corresponding position. When the first grabbing mechanism 4 places the material on the test fixture 33, the pins on the material (electronic component) can be in contact conduction with the test fixture 33, so that conduction between the material and the comprehensive testing equipment 32 is realized, and the comprehensive testing equipment 32 can detect the material. The thimble assembly 31 includes two withstand voltage test thimbles, the withstand voltage test cylinder can drive the withstand voltage test thimbles to move, is close to or far away from the material, the quantity of withstand voltage test thimbles is two, two withstand voltage test thimbles respectively with combine test equipment 32 switch on, two withstand voltage test thimbles correspond positive pole and negative pole respectively, when two the test thimbles contact with the material, can apply high voltage to carry out withstand voltage test to the material. One side of the test fixture 33 is also provided with a photoelectric sensor for identifying whether a material is placed on the test fixture 33.

The pressure-resistant testing device provided by the embodiment of the utility model comprises a shell 1, a feeding mechanism 2, a testing mechanism 3, a discharging mechanism 8, a first grabbing mechanism 4 and a second grabbing mechanism 5, wherein the feeding mechanism 2 is used for receiving electronic elements and conveying the electronic elements to a preset feeding position; the electronic components located at the preset feeding position are transferred to the testing mechanism 3 through the first grabbing mechanism 4, the tested electronic components are transferred to the blanking mechanism 8 through the second grabbing mechanism 5 after the pressure resistance test of the testing mechanism 3, and finally the tested electronic components are conveyed to the preset blanking position through the blanking mechanism 8, so that the automation level is high, and the production efficiency is improved.

The foregoing description of the preferred embodiments of the utility model is not intended to be limiting, but rather is intended to cover all modifications, equivalents, or alternatives falling within the spirit and principles of the utility model.

Claims (10)

1. A pressure-resistant testing device, characterized by comprising:

a mounting platform;

a feeding mechanism; the feeding mechanism is arranged on the mounting platform and is used for receiving the electronic components and conveying the electronic components to a preset feeding position;

the testing mechanism is arranged on the mounting platform and used for testing the pressure resistance of the electronic element;

the blanking mechanism is arranged on the mounting platform and used for conveying the tested electronic element to a preset blanking position;

the first grabbing mechanism is arranged on the mounting platform and used for transferring the electronic element positioned at the preset feeding position to the testing mechanism;

the second grabbing mechanism is arranged on the mounting platform and used for transferring the tested electronic element to the blanking mechanism.

2. The pressure resistance test device according to claim 1, wherein the first gripping mechanism includes a first gripping member for gripping the electronic component located at the preset loading position and a first transfer member for driving the first gripping member to reciprocate between the preset loading position and the test mechanism to transfer the electronic component located at the preset loading position to the test mechanism.

3. The pressure-resistant testing device according to claim 2, wherein the first grabbing component comprises two clamping jaws, a first clamping cylinder, a first cylinder and a rotating cylinder, the first cylinder is arranged on the first conveying component and can drive the rotating cylinder in the vertical direction, the rotating cylinder is connected with the first clamping cylinder, the two clamping jaws are oppositely arranged on the first clamping cylinder, and the first clamping cylinder is used for driving the two clamping jaws to move towards or away from each other.

4. A pressure-resistant testing device according to claim 3, wherein an elastic member having one end for abutting against the electronic component is provided between the two clamping jaws, and the elastic member applies an elastic force to the clamped material to disengage from the clamping jaws.

5. The pressure resistance testing device according to claim 4, wherein the mounting platform is provided with a supporting frame, and the first conveying assembly comprises a transmission member fixedly connected with the grabbing mechanism and a driving member connected with the transmission member and used for driving the transmission member to move transversely; the driving piece is arranged on the supporting frame.

6. The pressure resistance test device according to claim 1, wherein the feeding mechanism comprises a vibration source, a feeding guide rail which is arranged at the top of the vibration source and is driven by the vibration source for conveying electronic components;

the transmission tail end of the feeding guide rail is provided with a first inclined plane; the feeding mechanism comprises a supporting block, the supporting block is arranged on the mounting platform, a second inclined plane is arranged on the supporting block, the second inclined plane is located below the first inclined plane, the second inclined plane is attached to the first inclined plane, and a stop block for stopping an electronic element transmitted to the transmission tail end of the feeding guide rail is arranged on the supporting block.

7. The pressure-resistant testing device according to claim 1, wherein the blanking mechanism comprises an induction piece, a blanking bracket, a blanking transmission piece for conveying electronic components, and a blanking driving assembly connected with the blanking transmission piece and used for driving the blanking transmission piece to move, and the blanking transmission piece is arranged on the blanking bracket; the two sides of the blanking transmission piece are provided with blanking guide rails; the sensing piece is arranged on the blanking guide rail and located at the transmission tail end of the blanking transmission piece, and the sensing piece is used for sensing whether an electronic element exists on the blanking guide rail.

8. The pressure resistance test apparatus according to any one of claims 1 to 7, wherein the test mechanism comprises a comprehensive test device and a thimble assembly, an electronic component is placed on and conducted with the comprehensive test device through a test jig, and the comprehensive test device is electrically connected with the thimble assembly and applies a test voltage to the electronic component through the thimble assembly.

9. The pressure-resistant testing device according to claim 8, wherein the testing jig is provided with an electrical contact point electrically connected with an electronic component, the electronic component being placed on the testing jig and being conducted with the comprehensive testing device through the electrical contact point;

one side of the test jig is provided with a pressure-resistant test cylinder, and the pressure-resistant test cylinder drives the thimble assembly to be close to or far away from the electronic element.

10. The pressure resistance testing device according to claim 9, further comprising a housing, an adjusting assembly for adjusting the height of the testing mechanism, the adjusting assembly comprising a plurality of guide rods fixedly connected to the housing at one end, a mounting plate connected to the guide rods, the mounting plate being adjustable in connection height relative to the guide rods; the testing mechanism is fixedly connected to the mounting plate.