CN220894439U - Transverse pressure-resistant testing device - Google Patents

Abstract

The utility model discloses a transverse pressure-resistant testing device which comprises a frame, a plurality of jigs, a first chute, a second chute, a third chute and a fourth chute which are arranged on the frame and are sequentially butted to form a rectangle, a pushing mechanism which is arranged on the frame and is used for driving the jigs to sequentially slide among the first chute, the second chute, the third chute and the fourth chute, a receiving mechanism which is arranged on the frame and corresponds to one side of the fourth chute, a guide pin moving mechanism which is arranged on the frame and corresponds to the other side of the fourth chute, and a pre-pressing mechanism which is arranged on the frame. The advantages are that: the jig can be enabled to reflow, a plurality of products are guaranteed to be tested at one time, meanwhile, the complexity of equipment is reduced, the testing efficiency is improved, and the production cost is reduced.

Description

Transverse pressure-resistant testing device

Technical Field

The utility model relates to the field of test equipment, in particular to a transverse pressure-resistant test device.

Background

In the existing withstand voltage test device, a product is placed on a jig, and is tested after being pressed and fixed and then is electrically conducted by contacting the probe with the product. The existing test modes mainly comprise two types, wherein the first type is that after the jig receives a product, the product is directly pushed to a test position, and after the test is finished, the product is taken out and then is fed again. And secondly, the reflow of the jig and the continuity of the test are realized by arranging the circulating pipeline on the upper side and the lower side. The first test mode has the problem of low test efficiency, and the second test mode has the problems of high manufacturing cost and large occupied area.

In view of this, it is necessary to provide a lateral withstand voltage test apparatus.

Disclosure of Invention

The transverse pressure-resistant testing device provided by the utility model effectively solves the problems of low testing efficiency, high manufacturing cost and large occupied area of the conventional testing device.

The technical proposal adopted by the utility model is that

The utility model provides a horizontal withstand voltage testing arrangement, including frame and a plurality of tool, still including setting up in the frame in proper order dock first spout, second spout, third spout and the fourth spout that constitutes the rectangle, set up in the frame be used for driving the tool in first spout, second spout, third spout and fourth spout between the gliding pushing mechanism of order, set up in the frame and with the receipts material mechanism that fourth spout one side corresponds, set up in the frame with the guide pin moving mechanism that fourth spout opposite side corresponds, set up the pre-compaction mechanism in the frame.

Further is: the pushing mechanism comprises a pushing component I for pushing the jig from the first chute to the second chute, a pushing component II for pushing the jig from the second chute to the third chute, a pushing component III for pushing the jig from the third chute to the fourth chute, and a pushing component IV for pushing the jig from the fourth chute to the first chute.

Further is: the guide pin moving mechanism comprises a first linear guide rail, a sliding plate, a plurality of first seats, a plurality of probes and a first cylinder, wherein the first linear guide rail is arranged on the frame and is horizontally perpendicular to the extending direction of the fourth sliding groove, the sliding plate is arranged on the first linear guide rail in a sliding mode, the first seats are fixedly arranged on the sliding plate, the probes are respectively fixedly arranged on the first seats, and the first cylinder is fixedly arranged on the frame and used for driving the sliding plate to slide along the first linear guide rail.

Further is: the pre-pressing mechanism comprises a support arranged on the frame, a lifting frame fixedly arranged on the support, a second air cylinder fixedly arranged on the support and used for driving the lifting frame to lift, and a plurality of pressing pieces arranged at the lower end of the lifting frame, wherein the pressing pieces correspond to the first seats one by one, each pressing piece comprises a guide pillar, a first spring, a rubber pressure head and a limiting part, the guide pillar is slidably connected with the lower end of the lifting frame, the first spring is sleeved on the guide pillar, the rubber pressure head is fixedly arranged at the lower end of the guide pillar, the limiting part is fixedly arranged at the upper end of the guide pillar, and two ends of the first spring are respectively propped against the lifting frame and the rubber pressure head.

Further is: the material receiving mechanism comprises a plurality of material receiving boxes which are arranged at equal intervals along the extending direction of the fourth sliding groove and a transfer module which is used for transferring products from the jig to the corresponding material receiving boxes, wherein the transfer module comprises a supporting seat arranged on a frame, a first linear module which is arranged on the supporting seat and parallel to the fourth sliding groove, a third air cylinder which is arranged at the output end of the first linear module and is horizontally vertical to the fourth sliding groove, a seventh air cylinder which is vertically and fixedly arranged at the output end of the third air cylinder, and an air cylinder clamping jaw which is fixedly arranged at the output end of the seventh air cylinder.

Further is: the fixture comprises a seat body and a wire clamping device arranged on the seat body, the wire clamping device comprises a limiting block arranged on the seat body, a clamping block arranged on the seat body in a sliding manner and a second spring arranged in the seat body, the clamping block is propped against the limiting block in a free state of the second spring, a first inclined surface is arranged on the clamping block opposite to one side of the limiting block, a spreading mechanism used for loosening the clamping block and the limiting block is further arranged on the frame, the spreading mechanism comprises a stand column fixedly arranged on the frame, a fifth cylinder with a downward output end and a pressing block fixedly arranged at the output end of the fifth cylinder, and the pressing block is provided with a second inclined surface which can be in sliding connection with the first inclined surface.

The utility model has the beneficial effects that: the jig can be enabled to reflow, a plurality of products are guaranteed to be tested at one time, meanwhile, the complexity of equipment is reduced, the testing efficiency is improved, and the production cost is reduced.

Drawings

Fig. 1 is an overall schematic diagram of a lateral pressure resistance test device according to an embodiment of the present application.

Fig. 2 is a schematic diagram of a pre-pressing mechanism of a transverse pressure-resistant testing device according to an embodiment of the application.

Fig. 3 is an enlarged schematic view of the area a in fig. 2.

Fig. 4 is a schematic diagram of a transfer module of the lateral voltage endurance testing apparatus according to an embodiment of the present application.

Fig. 5 is a schematic view of a spreading mechanism according to an embodiment of the present application.

Fig. 6 is a schematic view of a pushing mechanism according to an embodiment of the present application.

Fig. 7 is a schematic diagram of a guide pin moving mechanism according to an embodiment of the present application.

Fig. 8 is a schematic diagram of a fixture according to an embodiment of the application.

Marked in the figure as: 1. a frame; 2. a jig; 3. a first chute; 4. a second chute; 5. a third chute; 6. a third chute; 7. a fourth chute; 8. a pushing mechanism; 9. a material receiving mechanism; 10. a guide pin moving mechanism; 11. a pre-pressing mechanism; 81. a first pushing component; 82. a pushing component II; 83. a pushing component III; 84. a fourth pushing component; 101. a first linear guide rail; 102. a slide plate; 103. a first seat; 104. a probe; 105. a first air cylinder; 111. a support; 112. a lifting frame; 113. a second cylinder; 114. a pressing member; 1141. a guide post; 1142. a first spring; 1143. a rubber pressure head; 91. a receiving box; 92. a transfer module; 921. a support base; 923. a first straight line module; 922. a third cylinder; 924. a seventh air cylinder; 926. a cylinder clamping jaw; 21. a seat body; 22. a limiting block; 23. clamping blocks; 12. a spreading mechanism; 121. a column; 122. a fifth cylinder; 123. briquetting; 130. a second inclined plane; 230. and a first inclined plane.

Detailed Description

In order that the above objects, features and advantages of the utility model will be readily understood, a more particular description of the utility model will be rendered by reference to the appended drawings.

As shown in fig. 1 and 6, the structure of the transverse pressure-resistant testing device provided by the embodiment of the application comprises a frame 1, a plurality of jigs 2, a first chute 3, a second chute 4, a third chute 65 and a fourth chute 7 which are arranged on the frame 1 and are sequentially butted to form a rectangle, a pushing mechanism 8 which is arranged on the frame 1 and is used for driving the jigs 2 to sequentially slide among the first chute 3, the second chute 4, the third chute 65 and the fourth chute 7, a material receiving mechanism 9 which is arranged on the frame 1 and corresponds to one side of the fourth chute 7, a guide pin moving mechanism 10 which is arranged on the frame 1 and corresponds to the other side of the fourth chute 7, and a pre-pressing mechanism 11 which is arranged on the frame 1.

In actual use, the jig 2 filled with the product to be tested is placed on the first chute 3, then the jig 2 is sequentially pushed to the second chute 4 and the third chute 65 through the pushing mechanism 8 and then enters the fourth chute 7, after the jig 2 in the fourth chute 7 reaches the preset number, the prepressing mechanism 11 presses the products on a plurality of jigs 2 in the fourth chute 7, and then the guide pin moving mechanism 10 contacts the products on the jigs 2.

In the above-mentioned design, can make tool 2 backward flow, guarantee once only to test a plurality of products, reduce the complexity of equipment again simultaneously, improve efficiency of software testing and reduced manufacturing cost.

Specifically: as shown in fig. 6, the pushing mechanism 8 includes a pushing assembly 81 for pushing the jig 2 from the first chute 3 to the second chute 4, a pushing assembly 82 for pushing the jig 2 from the second chute 4 to the third chute 65, a pushing assembly 83 for pushing the jig 2 from the third chute 65 to the fourth chute 7, and a pushing assembly 84 for pushing the jig 2 from the fourth chute 7 to the first chute 3.

In actual use, the jig 2 is pushed from the first chute 3 to the second chute 4 by the pushing component 81, the jig 2 is pushed from the second chute 4 to the third chute 65 by the pushing component 82, the jig 2 is pushed from the second chute 4 to the third chute 65 by the pushing component 83, and the jig 2 is pushed from the third chute 65 to the fourth chute 7 by the pushing component 84.

In the above design, the pushing mechanism 8 can effectively ensure pushing of the jig 2.

Specifically: as shown in fig. 7, the guide pin moving mechanism 10 includes a first linear guide rail 101 disposed on the frame 1 and horizontally perpendicular to the extending direction of the fourth chute 7, a sliding plate 102 slidably disposed on the first linear guide rail 101, a plurality of first seats 103 fixedly disposed on the sliding plate 102, a plurality of probes 104 fixedly disposed on the first seats 103 respectively, and a first cylinder 105 fixedly disposed on the frame 1 for driving the sliding plate 102 to slide along the first linear guide rail 101.

In actual use, the sliding plate 102 is driven to slide along the first guide rail through the first cylinder 105, so that the probes 104 are contacted with or separated from the product positioned in the fourth chute 7.

In the above design, the structural design of the guide pin moving mechanism 10 can ensure the stability of the guide pin moving process.

Specifically: as shown in fig. 2 and 3, the pre-pressing mechanism 11 includes a support 111 disposed on the frame 1, a lifting frame 112 fixedly disposed on the support 111, a second cylinder 113 fixedly disposed on the support 111 and used for driving the lifting frame 112 to lift, and a plurality of pressing members 114 disposed at the lower end of the lifting frame 112, the pressing members 114 are in one-to-one correspondence with the first seat 103, the pressing members 114 include a guide pillar 1141 slidably connected with the lower end of the lifting frame 112, a first spring 1142 sleeved on the guide pillar 1141, a rubber pressure head 1143 fixedly disposed at the lower end of the guide pillar 1141, and a limiting portion fixedly disposed at the upper end of the guide pillar 1141, and two ends of the first spring 1142 respectively abut against the lifting frame 112 and the rubber pressure head 1143.

In actual use, when the number of the jigs 2 on the fourth chute 7 reaches the requirement, the pressing piece 114 is driven to move downwards by the second air cylinder 113, the rubber press head 1143 contacts with the product after the pressing piece 114 moves downwards, the first guide pillar 1141 moves upwards relative to the lifting frame 112, and the first spring 1142 compresses.

In the above design, the structural design of the pre-pressing mechanism 11 can effectively ensure that the product is not crushed during pre-pressing.

Specifically: as shown in fig. 1 and fig. 4, the material receiving mechanism 9 includes a plurality of material receiving boxes 91 disposed at equal intervals along the extending direction of the fourth chute 7, and a transfer module 92 for transferring products from the jig 2 to the corresponding material receiving boxes 91, the transfer module 92 includes a support base 921 disposed on the frame 1, a first linear module 923 disposed on the support base 921 and parallel to the fourth chute 7, a third air cylinder 922 disposed at the output end of the first linear module 923 and horizontally perpendicular to the fourth chute 7, a seventh air cylinder 924 vertically and fixedly disposed at the output end of the third air cylinder 922, and an air cylinder clamping jaw 926 fixedly disposed at the output end of the seventh air cylinder 924.

In actual use, the third air cylinder 922 is driven to move to a position corresponding to the product level by the first linear module 923, the seventh air cylinder 924 is driven to move to the upper side of the product by the third air cylinder 922, and the air cylinder clamping jaw 926 is driven to lift by the seventh air cylinder 924 so as to clamp or place the product.

In the above design, the structural design of the material receiving mechanism 9 is convenient for transferring and collecting the product.

Specifically: as shown in fig. 5 and 8, the fixture 2 includes a seat body 21, a wire clamping device disposed on the seat body 21, the wire clamping device includes a stopper 22 disposed on the seat body 21, a clamping block 23 slidably disposed on the seat body 21, a No. two spring disposed in the seat body 21, the clamping block 23 abuts against the stopper 22 in a free state of the No. two spring, a No. one inclined plane 230 is disposed on a side of the clamping block 23 opposite to the stopper 22, a spreading mechanism 12 for loosening the clamping block 23 and the stopper 22 is further disposed on the frame 1, the spreading mechanism 12 includes a column 121 fixedly disposed on the frame 1, a No. five cylinder 122 fixedly disposed on the column 121 and having a downward output end, and a pressing block 123 fixedly disposed on an output end of the No. five cylinder 122, and the pressing block 123 is provided with a No. two inclined planes 130 slidably connected with the No. one inclined plane 230.

In actual use, when a product is placed on the jig 2 or removed from the jig 2, the pressing block 123 is driven to move downwards by the fifth cylinder 122, so that the first inclined plane 230 and the second inclined plane 130 slide relatively, and the clamping block 23 and the limiting block 22 are relatively far away.

In the above design, the structural design of the jig 2 and the opening mechanism 12 can ensure that the product is convenient to be fixed by the wire clamping device.

It should be understood that the foregoing description is only illustrative of the present utility model and is not intended to limit the utility model to the particular forms disclosed, but on the contrary, the intention is to cover all modifications, equivalents, and alternatives falling within the spirit and scope of the utility model.

Claims (6)

1. The utility model provides a horizontal withstand voltage testing arrangement, includes frame (1) and a plurality of tool (2), its characterized in that: the device comprises a frame (1), a first chute (3), a second chute (4), a third chute (6) (5) and a fourth chute (7) which are sequentially connected in a butt joint mode to form a rectangle, a pushing mechanism (8) which is arranged on the frame (1) and used for driving a jig (2) to sequentially slide among the first chute (3), the second chute (4), the third chute (6) (5) and the fourth chute (7), a receiving mechanism (9) which is arranged on the frame (1) and corresponds to one side of the fourth chute (7), a guide pin moving mechanism (10) which is arranged on the frame (1) and corresponds to the other side of the fourth chute (7) and a pre-pressing mechanism (11) which is arranged on the frame (1).

2. The lateral pressure resistance test device according to claim 1, wherein: the pushing mechanism (8) comprises a pushing component (81) for pushing the jig (2) from the first chute (3) to the second chute (4), a pushing component (82) for pushing the jig (2) from the second chute (4) to the third chute (6) (5), a pushing component (83) for pushing the jig (2) from the third chute (6) (5) to the fourth chute (7), and a pushing component (84) for pushing the jig (2) from the fourth chute (7) to the first chute (3).

3. The lateral pressure resistance test device according to claim 1, wherein: the guide pin moving mechanism (10) comprises a first linear guide rail (101) which is arranged on the frame (1) and is horizontally perpendicular to the extending direction of the fourth sliding groove (7), a sliding plate (102) which is arranged on the first linear guide rail (101) in a sliding mode, a plurality of first seats (103) which are fixedly arranged on the sliding plate (102), a plurality of probes (104) which are respectively fixedly arranged on the first seats (103) and a first air cylinder (105) which is fixedly arranged on the frame (1) and used for driving the sliding plate (102) to slide along the first linear guide rail (101).

4. The lateral pressure resistance test device according to claim 1, wherein: the pre-pressing mechanism (11) comprises a support (111) arranged on the frame (1), a lifting frame (112) fixedly arranged on the support (111), a second air cylinder (113) fixedly arranged on the support (111) and used for driving the lifting frame (112) to lift, and a plurality of pressing pieces (114) arranged at the lower end of the lifting frame (112), wherein the pressing pieces (114) are in one-to-one correspondence with the first seats (103), each pressing piece (114) comprises a guide pillar (1141) in sliding connection with the lower end of the lifting frame (112), a first spring (1142) sleeved on the guide pillar (1141), a rubber pressing head (1143) fixedly arranged at the lower end of the guide pillar (1141) and a limiting part fixedly arranged at the upper end of the guide pillar (1141), and two ends of the first spring (1142) are respectively propped against the lifting frame (112) and the rubber pressing head (1143).

5. The lateral pressure resistance test device according to claim 1, wherein: the material receiving mechanism (9) comprises a plurality of material receiving boxes (91) which are arranged at equal intervals along the extending direction of the fourth sliding groove (7) and a transfer module (92) which is used for transferring products from the jig (2) to the corresponding material receiving boxes (91), wherein the transfer module (92) comprises a supporting seat (921) which is arranged on the frame (1), a first linear module (923) which is arranged on the supporting seat (921) and is parallel to the fourth sliding groove (7), a third air cylinder (922) which is arranged at the output end of the first linear module (923) and is perpendicular to the fourth sliding groove (7), a seventh air cylinder (924) which is vertically and fixedly arranged at the output end of the third air cylinder (922) and an air cylinder clamping jaw (926) which is fixedly arranged at the output end of the seventh air cylinder (924).

6. The lateral pressure resistance test device according to claim 1, wherein: the jig (2) comprises a seat body (21), a wire clamping device arranged on the seat body (21), wherein the wire clamping device comprises a limiting block (22) arranged on the seat body (21), a clamping block (23) arranged on the seat body (21) in a sliding manner, a second spring arranged in the seat body (21), the clamping block (23) is propped against the limiting block (22) in a free state of the second spring, a first inclined surface (230) is arranged on the clamping block (23) opposite to one side of the limiting block (22), a spreading mechanism (12) for loosening the clamping block (23) and the limiting block (22) is further arranged on the frame (1), the spreading mechanism (12) comprises a stand column (121) fixedly arranged on the frame (1), a fifth air cylinder (122) fixedly arranged on the stand column (121) and with a downward output end, and a pressing block (123) fixedly arranged at the output end of the fifth air cylinder (122), and the pressing block (123) is provided with a second inclined surface (130) which can be in sliding connection with the first inclined surface (230).