CN214667548U - Automatic alignment test equipment for photoelectric module - Google Patents

Abstract

The utility model belongs to the field of photoelectric module testing equipment, and discloses automatic photoelectric module alignment testing equipment, which comprises a testing table and a tester; the test platform is fixedly connected with a material box for loading the photoelectric module close to the upper surface of the bearing rotating ring; the upper surface of the test board close to the material box is provided with a material pushing assembly, and the material pushing assembly is used for pushing the photoelectric module to move. The bearing rotating ring is rotated, so that the arc-shaped pushing block fixedly connected with the lower surface of the bearing rotating ring pushes the guide rod to move, and the pushing plate pushes the photoelectric module to move, so that the photoelectric module can be pushed into the placing groove to be detected by the tester; bear the swivel through rotating, can make the interior photovoltaic module of magazine promote the standing groove in, need not the continuous photovoltaic module of taking of measurement personnel to accelerate the speed of test, improve work efficiency.

Description

Automatic alignment test equipment for photoelectric module

Technical Field

The utility model belongs to photovoltaic module test equipment field, concretely relates to automatic test equipment that aligns of photovoltaic module.

Background

The photoelectric module is mainly formed by assembling a lens and an image sensor and used for detecting products in the field of product testing. The photoelectric module can output the collected test image to the central control system, and then corresponding image detection processing is carried out.

When testing the photovoltaic module to production, because need once only elect a plurality of photovoltaic modules at random and detect, when the measurement personnel detected it, need repeated continuous photoelectric module of taking how to place under the tester and detect, repeated continuous photoelectric module of taking like this leads to the tester to examine time measuring speed and slows down, influences work efficiency.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide an automatic test equipment that aligns of photovoltaic module through placing a plurality of photovoltaic modules together, only needs to rotate to bear the weight of the change and can switch different photovoltaic modules and test, improves work efficiency.

In order to achieve the above object, the utility model provides a following technical scheme: the automatic alignment test equipment for the photoelectric module comprises a test board, wherein the test board consists of a table board and supporting legs, and a tester is arranged above the table board;

the surface of the table top of the test table is rotatably connected with a bearing rotating ring, and the upper surface of the test table, which is close to the bearing rotating ring, is fixedly connected with a material box for bearing the photoelectric module;

the upper surface of the test board, which is close to the material box, is provided with a material pushing assembly, and the material pushing assembly is used for pushing the photoelectric module to move;

the pushing assembly comprises a discharge port, a pushing plate, a push rod, a baffle, an arc-shaped pushing block, a guide rod, a fixing plate and a pushing spring, the outer surface of the material box close to the bottom of the material box penetrates through the discharge port, the pushing plate is arranged in a sliding connection mode with the inner wall of the discharge port, one side of the pushing plate far away from the material box is fixedly connected with the push rod, the other end of the push rod is fixedly connected with the outer surface of the baffle, the pushing spring is sleeved on the push rod, the fixing plate is fixedly connected to the upper surface of the test board, the push rod penetrates through the fixing plate, the two ends of the pushing spring respectively abut against the outer surfaces of the baffle and the fixing plate, the arc-shaped pushing block is fixedly connected with the lower surface of the bearing rotating ring, the guide rod is fixedly connected with the guide rod at one end of the baffle, and the guide rod is slidably connected with the arc surface of the arc-shaped pushing block.

Preferably, the testboard is close to the upper surface that bears the weight of the swivel and is equipped with spacing subassembly, spacing subassembly includes limiting plate, carriage release lever, jacking spring, stopper and spacing groove, limiting plate fixed connection is in the upper surface of testboard, the one end of carriage release lever runs through the surface of limiting plate and sets up rather than sliding connection, the other end and the stopper fixed connection of carriage release lever, a plurality of spacing grooves have been seted up to the surface circumference that bears the weight of the swivel, stopper and spacing groove looks joint, the jacking spring housing is located on the carriage release lever, the both ends of jacking spring offset with the surface of limiting plate and stopper respectively.

Preferably, the inside both sides of magazine all are equipped with the alignment subassembly, the alignment subassembly includes V-arrangement baffle, bracing piece and compression spring, the inner wall sliding connection setting of V-arrangement baffle and magazine, the one end fixed connection of bracing piece is in the surface of V-arrangement baffle, the other end of bracing piece runs through the surface of magazine and sets up rather than sliding connection, the compression spring cover is located on the bracing piece, compression spring's both ends offset with the inner wall of V-arrangement baffle and magazine respectively.

Preferably, a plurality of placing grooves are formed in the circumference of the upper surface of the bearing rotating ring, and the size of the openings of the plurality of placing grooves and the size of the openings of the discharge port are equal.

Preferably, the bearing swivel is symmetrically provided with arc-shaped grooves on the upper surface close to the two sides of the placing groove.

Preferably, the limiting blocks are arranged in a triangular structure, and round corners are arranged at the end parts of the limiting blocks.

The technical scheme has the following technical effects:

1. the bearing rotating ring is rotated, so that the arc-shaped push block fixedly connected with the lower surface of the bearing rotating ring pushes the guide rod to move, the baffle fixedly connected with the guide rod pushes the push rod to move, the push plate fixedly connected with the push rod pushes the photoelectric module to move, and the photoelectric module can be pushed into a placing groove formed in the bearing rotating ring so as to be detected by a tester; bear the swivel through rotating, can make the interior photovoltaic module of magazine promote the standing groove in, need not the continuous photovoltaic module of taking of measurement personnel to accelerate the speed of test, improve work efficiency.

2. Bear the swivel through rotating, the below that the optoelectronic module that will wait to detect rotated the tester, at this moment, the stopper that sets up on the testboard will block into the spacing inslot that bears the weight of the swivel surface and set up under the thrust effect of jacking spring to carry on spacingly to bearing the weight of the swivel, prevent to take place to rock when testing the optoelectronic module, influence the accuracy of test.

Drawings

FIG. 1 is a schematic diagram of an overall structure of an automatic alignment testing apparatus for an optoelectronic module;

FIG. 2 is a schematic diagram of a top cross-sectional view of an apparatus for testing the automatic alignment of an optoelectronic module;

FIG. 3 is a schematic diagram of a cross-sectional structure of a magazine of an automatic alignment testing apparatus for optoelectronic modules;

fig. 4 is an enlarged view of a structure in fig. 2.

Wherein: 1. a test bench; 2. a tester; 3. a magazine; 4. a material pushing assembly; 401. a discharge port; 402. a material pushing plate; 403. a push rod; 404. a baffle plate; 405. an arc-shaped push block; 406. a guide bar; 407. a fixing plate; 408. a spring is supported; 5. carrying the swivel; 6. a limiting component; 601. a limiting plate; 602. a travel bar; 603. a jacking spring; 604. a limiting block; 605. a limiting groove; 7. an alignment assembly; 701. a V-shaped baffle; 702. a support bar; 703. a compression spring; 8. a placement groove; 9. a photovoltaic module.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

Referring to fig. 1-4, the technical solution provided by the present invention is: the utility model provides an automatic test equipment that aligns of photovoltaic module, includes testboard 1, and testboard 1 comprises mesa and supporting legs, and tester 2 is installed to the top of mesa. Specifically, can set up the one deck roof in the top of mesa, install tester 2 on the lower surface of roof, couple together through branch between mesa and the roof, tester 2 can adopt the photovoltaic module test equipment among the prior art.

The mesa surface of testboard 1 rotates and is connected with bears swivel 5, and is concrete, bears swivel 5 and be the annular carousel structure, and its lower surface can rotate with the mesa of testboard 1 and be connected the setting, and testboard 1 is close to the last fixed surface who bears swivel 5 and is connected with magazine 3 that is used for bearing photovoltaic module 9, and magazine 3 sets up in the inboard that bears swivel 5.

The upper surface of the test board 1, which is close to the material box 3, is provided with a material pushing component 4, and the material pushing component 4 is used for pushing the photoelectric module 9 to move;

the pushing assembly 4 comprises a discharge port 401, a pushing plate 402, a push rod 403, a baffle 404, an arc-shaped pushing block 405, a guide rod 406, a fixing plate 407 and a pushing spring 408, the outer surface of the material box 3 close to the bottom of the material box penetrates through the discharge port 401, the pushing plate 402 is arranged in sliding connection with the inner wall of the discharge port 401, one side of the pushing plate 402 far away from the material box 3 is fixedly connected with the push rod 403, the other end of the push rod 403 is fixedly connected with the outer surface of the baffle 404, the pushing spring 408 is sleeved on the push rod 403, the fixing plate 407 is fixedly connected with the upper surface of the test bench 1, the push rod 403 penetrates through the fixing plate 407, two ends of the pushing spring 408 respectively abut against the outer surfaces of the baffle 404 and the fixing plate 407, the arc-shaped pushing block 405 is fixedly connected with the lower surface of the bearing swivel 5, the guide rod 406 is fixedly connected with the lower surface of one end of the baffle 404, and the guide rod 406 is arranged in sliding connection with the arc-shaped pushing block 405.

Thus, when the photoelectric module 9 is detected, the photoelectric module 9 to be detected is placed in the material box 3, the bearing rotary ring 5 is rotated, the arc-shaped push block 405 fixedly connected with the lower surface of the bearing rotary ring 5 pushes the guide rod 406 to move, the baffle 404 fixedly connected with the guide rod 406 pushes the push rod 403 to move, the push plate 402 fixedly connected with the push rod 403 pushes the photoelectric module 9 to move, and the photoelectric module 9 can be pushed into the placing groove 8 formed in the bearing rotary ring 5 so as to be detected by the tester 2; bear change 5 through rotating, can make the interior photovoltaic module 9 of magazine 3 promote in the standing groove 8, need not the continuous photovoltaic module 9 of taking of testing personnel to accelerate the speed of test, improve work efficiency.

After the test of the photoelectric module 9 on the bearing rotary ring 5 is completed, the detection personnel takes out the photoelectric module 9 which is detected in the placing groove 8 so as to detect the next photoelectric module 9; in prior art's operation process, the photoelectric module 9 that does not need continuous taking of detection personnel detects under placing the tester again, and the utility model discloses an equipment can once only pile up in magazine 3 and put a plurality of photoelectric module 9, only need after the test is accomplished to take photoelectric module 9 from standing groove 8 in can, saved the time that photoelectric module 9 that takes one by one of detection personnel placed tester 2 departments and aligned to improve detection personnel's work efficiency, the operation of aligning has also promoted the rate of accuracy.

Referring to fig. 4, the testing platform 1 is provided with a limiting component 6 near the upper surface of the bearing swivel 5, the limiting component 6 includes a limiting plate 601, a moving rod 602, a jacking spring 603, a limiting block 604 and a limiting groove 605, the limiting plate 601 is fixedly connected to the upper surface of the testing platform 1, one end of the moving rod 602 penetrates through the outer surface of the limiting plate 601 and is slidably connected to the outer surface of the limiting plate 601, the other end of the moving rod 602 is fixedly connected to the limiting block 604, the outer surface of the bearing swivel 5 is provided with a plurality of limiting grooves 605, the limiting block 604 is clamped to the limiting groove 605, the jacking spring 603 is sleeved on the moving rod 602, and two ends of the jacking spring 603 respectively abut against the outer surfaces of the limiting plate 601 and the limiting block 604.

So, bear swivel 5 through rotating, to wait to detect photovoltaic module 9 and rotate the below of tester 2, at this moment, set up stopper 604 on testboard 1 will block into the spacing groove 605 that bears the weight of 5 surface setups of swivel under the thrust effect of jacking spring 603 to carry on spacingly to bearing swivel 5, prevent to take place to rock when testing photovoltaic module 9, influence the accuracy of test.

Referring to fig. 3, alignment assemblies 7 are disposed on two sides of the interior of the material box 3, each alignment assembly 7 includes a V-shaped baffle 701, a support rod 702 and a compression spring 703, the V-shaped baffle 701 is slidably connected to the inner wall of the material box 3, one end of the support rod 702 is fixedly connected to the outer surface of the V-shaped baffle 701, the other end of the support rod 702 penetrates through the outer surface of the material box 3 and is slidably connected to the outer surface of the material box 3, the compression spring 703 is sleeved on the support rod 702, two ends of the compression spring 703 are respectively abutted against the V-shaped baffle 701 and the inner wall of the material box 3, and the height of the V-shaped baffle 701 is higher than the height of the material box 3.

So, through extrusion V-arrangement baffle 701, compression spring 703 that offsets with V-arrangement baffle 701 this moment receives the extrusion force and is compressed, treats to put into magazine 3 back with optoelectronic module 9, and V-arrangement baffle 701 will be reset by compression spring 703's elasticity, with a plurality of optoelectronic modules 9 to between promote to make a plurality of optoelectronic modules 9 can arrange neatly, so that push away material subassembly 4 and push away optoelectronic module 9 in the standing groove 8.

Referring to fig. 2 and 3, a plurality of placing slots 8 are formed on the circumference of the upper surface of the bearing ring 5, and the size of the placing slots 8 is equal to that of the opening of the discharge hole 401.

So for photovoltaic module 9 can laminate mutually with the inner wall of standing groove 8, prevent that photovoltaic module 9 from taking place to rock.

Referring to fig. 2, the upper surface of the bearing rotary ring 5 near the two sides of the placing groove 8 is symmetrically provided with arc-shaped grooves.

So, after the test to photovoltaic module 9 is accomplished, tester can be convenient take out photovoltaic module 9 from standing groove 8.

Referring to fig. 4, the limiting block 604 is a triangle, and the end of the limiting block 604 is provided with a rounded corner.

Thus, when the bearing swivel 5 is rotated, the limiting groove 605 can push the limiting block 604 to move towards the direction of the limiting plate 601, so that the limiting block 604 is separated from the limiting groove 605, so as to rotate the bearing swivel 5.

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

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims (6)

1. The automatic alignment test equipment for the photoelectric module comprises a test board (1), wherein the test board (1) consists of a table board and supporting legs, and a tester (2) is arranged above the table board; the method is characterized in that:

the surface of the table top of the test table (1) is rotatably connected with a bearing rotary ring (5), and the upper surface of the test table (1), which is close to the bearing rotary ring (5), is fixedly connected with a material box (3) bearing a photoelectric module (9);

the upper surface, close to the material box (3), of the test board (1) is provided with a material pushing assembly (4), and the material pushing assembly (4) is used for pushing the photoelectric module (9) to move;

the pushing assembly (4) comprises a discharge hole (401), a pushing plate (402), a push rod (403), a baffle (404), an arc-shaped pushing block (405), a guide rod (406), a fixing plate (407) and a top spring (408), the discharge hole (401) is formed in the outer surface, close to the bottom of the material box (3), of the material box (3) in a penetrating mode, the pushing plate (402) is arranged on the inner wall of the discharge hole (401) in a sliding connection mode, the push rod (403) is fixedly connected to one side, far away from the material box (3), of the pushing plate (402), the other end of the push rod (403) is fixedly connected with the outer surface of the baffle (404), the top spring (408) is sleeved on the push rod (403), the fixing plate (407) is fixedly connected to the upper surface of the test board (1), the push rod (403) penetrates through the fixing plate (407), and two ends of the top spring (408) are respectively abutted against the outer surfaces of the baffle (404) and the fixing plate (407), the arc-shaped push block (405) is fixedly connected with the lower surface of the bearing rotating ring (5), the lower surface of one end of the baffle (404) is fixedly connected with a guide rod (406), and the guide rod (406) is slidably connected with the arc surface of the arc-shaped push block (405).

2. The optoelectronic module automatic alignment test equipment of claim 1, wherein: the upper surface of the test bench (1) close to the bearing swivel (5) is provided with a limiting component (6), the limiting component (6) comprises a limiting plate (601), a moving rod (602), a jacking spring (603), a limiting block (604) and a limiting groove (605), the limiting plate (601) is fixedly connected to the upper surface of the test bench (1), one end of the moving rod (602) penetrates through the outer surface of the limiting plate (601) and is arranged in a sliding connection with the outer surface, the other end of the moving rod (602) is fixedly connected with a limiting block (604), a plurality of limiting grooves (605) are arranged on the circumference of the outer surface of the bearing rotating ring (5), the limiting block (604) is clamped with the limiting groove (605), the jacking spring (603) is sleeved on the moving rod (602), two ends of the jacking spring (603) are respectively abutted against the outer surfaces of the limiting plate (601) and the limiting block (604).

3. The optoelectronic module automatic alignment test equipment of claim 1, wherein: the utility model discloses a feed box, including feed box (3), inside both sides of feed box (3) all are equipped with alignment assembly (7), alignment assembly (7) include V-arrangement baffle (701), bracing piece (702) and compression spring (703), inner wall sliding connection setting of V-arrangement baffle (701) and feed box (3), the one end fixed connection in the surface of V-arrangement baffle (701) of bracing piece (702), the other end of bracing piece (702) runs through the surface of feed box (3) and sets up rather than sliding connection, compression spring (703) cover is located on bracing piece (702), the both ends of compression spring (703) offset with the inner wall of V-arrangement baffle (701) and feed box (3) respectively.

4. The optoelectronic module automatic alignment test equipment of claim 1, wherein: a plurality of placing grooves (8) are formed in the circumference of the upper surface of the bearing rotating ring (5), and the size of the openings of the plurality of placing grooves (8) and the size of the openings of the discharge hole (401) are equal.

5. The optoelectronic module automatic alignment test equipment of claim 4, wherein: the upper surfaces of the bearing rotary rings (5) close to the two sides of the placing groove (8) are symmetrically provided with arc-shaped grooves.

6. The optoelectronic module automatic alignment test equipment of claim 2, wherein: the limiting block (604) is arranged in a triangular structure, and the end part of the limiting block (604) is provided with a round angle.

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