CN216265549U

CN216265549U - Be applied to electric core and have two-way clamping function's positioning jig

Info

Publication number: CN216265549U
Application number: CN202122685464.9U
Authority: CN
Inventors: 江泽德; 李凯; 严洪桔; 沈两尼
Original assignee: Shenzhen Volnen New Energy Co ltd
Current assignee: Shenzhen Volnen New Energy Co ltd
Priority date: 2021-11-04
Filing date: 2021-11-04
Publication date: 2022-04-12
Anticipated expiration: 2031-11-04

Abstract

The utility model discloses a positioning jig with a bidirectional clamping function applied to an electric core, which comprises a chassis and a clamping assembly, wherein two baffle plates are fixedly connected above the chassis, a base plate is arranged between the baffle plates, sliding grooves are symmetrically formed in the surface of the base plate, a clamping groove is formed in the right side of the sliding groove, a moving groove is formed in the right side of the clamping groove, the clamping assembly used for clamping materials is arranged above the moving groove, a rotating plate is arranged on the left side of the clamping assembly, a bottom plate is connected below the rotating plate in an embedded and rotating mode, a slow-speed motor is fixedly connected below the bottom plate, a main plate is fixedly connected behind the bottom plate, a transverse plate is fixedly connected at the upper end of the main plate, a rotating disc is connected in an embedded and rotating mode in front of the transverse plate, a lifting rod is fixedly connected above the rotating disc, and four corners of the top plate are fixedly connected with sliding rods. According to the utility model, through the matching of parts of each part, the placing position of the jig can be positioned when the jig clamps and moves the battery cell, so that the battery cell is prevented from deviating.

Description

Be applied to electric core and have two-way clamping function's positioning jig

Technical Field

The utility model relates to the technical field of battery cell jigs, in particular to a positioning jig with a bidirectional clamping function, which is applied to a battery cell.

Background

At present, along with the continuous improvement of the processing automation requirements, the clamp and the jig are continuously developed towards the automation direction. The functions of the clamp and the jig are continuously expanded and enhanced, along with the continuous development of an intelligent control theory and the progress of modern programmable control, industrial production tends to be more and more intelligent and automatic, and manual labor is separated from heavy manual labor.

The existing battery core processing jig in the market is poor in positioning effect and easy to cause battery core deviation, and therefore a positioning jig applied to a battery core and having a bidirectional clamping function is provided.

SUMMERY OF THE UTILITY MODEL

The utility model aims to provide a positioning jig with a bidirectional clamping function, which is applied to a battery cell and aims to solve the problems in the background technology.

In order to achieve the purpose, the utility model provides the following technical scheme: a positioning jig with a bidirectional clamping function applied to a battery cell comprises a chassis and a clamping assembly, wherein two baffles are fixedly connected above the chassis, and a backing plate is arranged between the baffles, sliding grooves are symmetrically arranged on the surface of the backing plate, a clamping groove is arranged on the right of the sliding grooves, a moving groove is arranged on the right of the clamping groove, the clamping component for clamping materials is arranged above the moving groove, the rotating plate is arranged on the left of the clamping component, a bottom plate is embedded and rotationally connected below the rotating plate, a slow-speed motor is fixedly connected below the bottom plate, a main board is fixedly connected with the rear part of the bottom board, a transverse plate is fixedly connected with the upper end of the main board, a rotary disc is embedded and rotatably connected with the front part of the transverse plate, a lifting rod is fixedly connected above the rotary disc, and a top plate is fixedly connected above the lifting rod, four corners of the top plate are fixedly connected with sliding rods, and a clamping plate is fixedly connected below the sliding rods.

Preferably, the centre gripping subassembly includes push rod, loose piece, bounding wall, spring, fixture block, connecting rod, clamp splice and slider, the right-hand fixedly connected with loose piece of push rod, and loose piece below fixedly connected with bounding wall, the bounding wall inboard is provided with the spring, and spring below fixedly connected with fixture block, bilateral symmetry is rotated around the loose piece left and is connected with the connecting rod, and the connecting rod left rotates and is connected with the clamp splice, clamp splice below fixedly connected with slider.

Preferably, one end of the spring, which is far away from the clamping block, is fixedly connected with the movable block, and the clamping block and the movable block form a lifting structure through the spring.

Preferably, the clamping block and the base plate form an embedded structure through the clamping groove, and the clamping block and the base plate form a sliding structure through the moving groove.

Preferably, the sliding block is embedded with the sliding groove, and the clamping block and the base plate form a sliding structure through the sliding block and the sliding groove.

Preferably, the central axis of the rotating plate coincides with the central axis of the turntable, and the rotating plate and the slow-speed motor form a rotating structure through a belt.

Preferably, the slide rod is connected with the rotary table in a sliding manner, and the clamping plate and the rotary table form a sliding structure through the lifting rod, the top plate and the slide rod.

The utility model provides a positioning jig with a bidirectional clamping function, which is applied to a battery cell and has the following beneficial effects: the positioning jig with the bidirectional clamping function is applied to the battery cell, and through the matching of parts of each part, the jig can position the placing position when clamping and moving the battery cell, so that the battery cell is prevented from deviating;

1. according to the utility model, through the arrangement of the moving groove, when the clamping block is positioned in the moving groove, a material is placed between the clamping blocks, the push rod drives the movable block to move rightwards, the backing plate is limited by the baffle plate at the right side and cannot move, the movable block drives the clamping block to move rightwards through the enclosing plate, meanwhile, the connecting rod drives the clamping blocks to move, the clamping blocks move oppositely on the backing plate under the limitation of the sliding block and the sliding groove, after the material is clamped, the movable block is driven by the push rod to move leftwards, the clamping block is pressed in the moving groove under the action of the spring, and the movable block drives the backing plate to move leftwards through the clamping block, so that the material is moved through the clamping blocks;

2. according to the utility model, through the arrangement of the clamping groove, when the base plate is contacted with the left baffle, the push rod stops running, the material stays on the rotating plate, after the material is clamped by the clamping plate, the push rod continues running, the base plate is limited and cannot move, the movable block drives the clamping block to move leftwards, and simultaneously drives the clamping block to loosen the material, after the clamping block moves above the clamping groove, the clamping block is embedded into the clamping groove under the action of the spring, the push rod drives the movable block to move rightwards, the base plate is driven by the clamping block to move rightwards to be contacted with the right baffle, then the clamping block moves out of the clamping groove to the moving groove, and the spring is compressed;

3. according to the utility model, through the arrangement of the clamping plate, when materials reach the rotating plate, the lifting rod drives the top plate to descend, the sliding rod drives the clamping plate to descend until the clamping plate is contacted with the materials, then the clamping plate is matched with the rotating plate to clamp the materials, the slow-speed motor is started to drive the rotating plate to rotate, the rotating disc is driven by the clamping plate to rotate along with the rotating plate, and the materials are matched to rotate, so that the materials are conveniently processed.

Drawings

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

FIG. 2 is a schematic cross-sectional right side view of the present invention;

fig. 3 is a schematic perspective view of the backing plate of the present invention.

In the figure: 1. a chassis; 2. a baffle plate; 3. a base plate; 4. a chute; 5. a card slot; 6. moving the groove; 7. a clamping assembly; 701. a push rod; 702. a loose block; 703. enclosing plates; 704. a spring; 705. a clamping block; 706. a connecting rod; 707. a clamping block; 708. a slider; 8. rotating the plate; 9. a base plate; 10. a slow speed motor; 11. a main board; 12. a transverse plate; 13. a turntable; 14. a lifting rod; 15. a top plate; 16. a slide rod; 17. and (4) clamping the plate.

Detailed Description

As shown in fig. 1, 2 and 3, a positioning fixture with bidirectional clamping function for electrical cores comprises a chassis 1 and a clamping assembly 7, two baffle plates 2 are fixedly connected above the chassis 1, a backing plate 3 is arranged between the baffle plates 2, sliding grooves 4 are symmetrically arranged on the surface of the backing plate 3, clamping grooves 5 are arranged on the right of the sliding grooves 4, moving grooves 6 are arranged on the right of the clamping grooves 5, the clamping assembly 7 for clamping materials is arranged above the moving grooves 6, a rotating plate 8 is arranged on the left of the clamping assembly 7, a bottom plate 9 is embedded and rotatably connected below the rotating plate 8, a slow motor 10 is fixedly connected below the bottom plate 9, a main plate 11 is fixedly connected behind the bottom plate 9, a transverse plate 12 is fixedly connected at the upper end of the main plate 11, a rotary plate 13 is embedded and rotatably connected in front of the transverse plate 12, a lifting rod 14 is fixedly connected above the rotary plate 13, and a top plate 15 is fixedly connected above the lifting rod 14, the four corners of the top plate 15 are fixedly connected with sliding rods 16, a clamping plate 17 is fixedly connected below the sliding rods 16, the central axis of the rotating plate 8 coincides with the central axis of the rotating disc 13, the rotating plate 8 and the slow motor 10 form a rotating structure through a belt, the sliding rods 16 are slidably connected with the rotating disc 13, the clamping plate 17 and the rotating disc 13 form a sliding structure through the lifting rod 14, the top plate 15, the sliding rods 16 and the rotating disc 13, through the arrangement of the clamping plate 17, after materials reach the rotating plate 8, the lifting rod 14 drives the top plate 15 to descend, the clamping plate 17 is driven by the sliding rods 16 to descend until the clamping plate 17 is contacted with the materials, then the clamping plate 17 is matched with the rotating plate 8 to clamp the materials, the slow motor 10 is started to drive the rotating plate 8 to rotate, the rotating disc 13 is driven by the clamping plate 17 to rotate together with the rotating plate 8, and is matched with the materials to rotate, and the materials are convenient to process the materials.

As shown in fig. 1 and fig. 2, the clamping assembly 7 includes a push rod 701, a movable block 702, a surrounding plate 703, a spring 704, a clamping block 705, a connecting rod 706, a clamping block 707 and a sliding block 708, the right of the push rod 701 is fixedly connected with the movable block 702, the surrounding plate 703 is fixedly connected below the movable block 702, the spring 704 is arranged inside the surrounding plate 703, the clamping block 705 is fixedly connected below the spring 704, the connecting rod 706 is rotatably connected to the left of the movable block 702 in a front-back symmetrical manner, the clamping block 707 is rotatably connected to the left of the connecting rod 706, the sliding block 708 is fixedly connected below the clamping block 707, one end of the spring 704, which is far away from the clamping block 705, is fixedly connected with the movable block 702, the clamping block 705 forms a lifting structure with the movable block 702 through the spring 704, the clamping block 705 forms an engaging structure with the backing plate 3 through the engaging groove 5, the clamping block forms a sliding structure with the backing plate 3 through the moving groove 6, the sliding block 708 is engaged with the sliding groove 4, and the clamping block 707 forms a sliding structure with the backing plate 3 through the sliding block 708 and the sliding groove 4, through the arrangement of the moving groove 6, when the clamping block 705 is positioned in the moving groove 6, a material is placed between the clamping blocks 707, the push rod 701 drives the movable block 702 to move rightwards, because the backing plate 3 is limited by the baffle 2 at the right side and can not move, the movable block 702 drives the clamping block 705 to move rightwards through the baffle 703, simultaneously the clamping block 707 is driven by the connecting rod 706 to move, the clamping block 707 moves oppositely on the backing plate 3 under the limitation of the slide block 708 and the slide groove 4, after the material is clamped, the push rod 701 drives the movable block 702 to move leftwards, the clamping block 705 is tightly pressed in the moving groove 6 under the action of the spring 704, the movable block 702 drives the backing plate 3 to move leftwards through the clamping block 705, so as to move the material through the clamping block 707, through the arrangement of the clamping groove 5, when the backing plate 3 is in contact with the baffle 2 at the left side, the push rod 701 stops running, the material stays on the rotating plate 8, after the material is clamped by the clamping plate 17, the push rod continues to run, the backing plate 701, and the backing plate 3 can not move, the movable block 702 drives the clamping block 705 to move leftwards, meanwhile, the clamping block 707 is driven to loosen the material, when the clamping block 705 moves to the upper side of the clamping groove 5, the clamping block 705 is embedded into the clamping groove 5 under the action of the spring 704, the push rod 701 drives the movable block 702 to move rightwards, the backing plate 3 is driven by the clamping block 705 to move rightwards to be in contact with the baffle 2 on the right side, then the clamping block 705 moves out of the clamping groove 5 to the moving groove 6, and the spring 704 is compressed.

In summary, when the positioning fixture with the bidirectional clamping function applied to the battery core is used, according to the structure shown in fig. 1, fig. 2 and fig. 3, when the clamping block 705 is located in the moving groove 6, a material is placed between the clamping blocks 707, the push rod 701 drives the movable block 702 to move rightwards, because the backing plate 3 is restricted by the baffle 2 on the right side and cannot move, the movable block 702 drives the clamping block 705 to move rightwards through the enclosing plate 703, the clamping block 707 is driven to move through the connecting rod 706, the clamping block 707 moves in opposite directions on the backing plate 3 under the restriction of the sliding block 708 and the sliding groove 4, after the material is clamped, the push rod 701 drives the movable block 702 to move leftwards, the clamping block 705 is pressed in the moving groove 6 under the action of the spring 704, the movable block 702 drives the backing plate 3 to move leftwards through the clamping block 707, so as to move the material through the clamping block 707, after the backing plate 3 is contacted with the baffle 2 on the left side, the push rod 701 stops operating, the material stays on the rotating plate 8, the lifting rod 14 drives the top plate 15 to descend, the sliding rod 16 drives the clamping plate 17 to descend until the clamping plate 17 is contacted with the material, then the clamping plate 17 is matched with the rotating plate 8 to clamp the material, meanwhile, the push rod 701 continues to operate, the backing plate 3 is limited and cannot move, the movable block 702 drives the clamping block 705 to move leftwards, meanwhile, the clamping block 707 is driven to loosen the material, the slow motor 10 is started to drive the rotating plate 8 to rotate, the rotary disc 13 is driven by the clamping plate 17 to rotate along with the rotating plate 8, the movable block is matched with the material to rotate, the material is convenient to process, after the clamping block 705 moves to the upper portion of the clamping groove 5, the clamping block 705 is embedded into the clamping groove 5 under the action of the spring 704, the push rod 701 drives the movable block 702 to move rightwards, the backing plate 3 is driven by the clamping block 705 to move rightwards to be contacted with the baffle 2 on the right side, then the clamping block 705 moves out of the clamping groove 5 to the moving groove 6, and compresses the spring 704.

Claims

1. A positioning jig with a bidirectional clamping function applied to an electric core comprises a chassis (1) and a clamping assembly (7) and is characterized in that two baffles (2) are fixedly connected above the chassis (1), a base plate (3) is arranged between the baffles (2), sliding grooves (4) are symmetrically formed in the surface of the base plate (3), a clamping groove (5) is formed in the right side of each sliding groove (4), a moving groove (6) is formed in the right side of each clamping groove (5), the clamping assembly (7) used for clamping materials is arranged above the moving groove (6), a rotating plate (8) is arranged on the left side of the clamping assembly (7), a bottom plate (9) is rotatably connected below the rotating plate (8) in an embedded mode, a slow-speed motor (10) is fixedly connected below the bottom plate (9), a main plate (11) is fixedly connected behind the bottom plate (9), and a transverse plate (12) is fixedly connected to the upper end of the main plate (11), and the front of the transverse plate (12) is embedded and rotatably connected with a rotary table (13), a lifting rod (14) is fixedly connected above the rotary table (13), a top plate (15) is fixedly connected above the lifting rod (14), four corners of the top plate (15) are fixedly connected with slide rods (16), and a clamping plate (17) is fixedly connected below the slide rods (16).

2. The positioning jig with the bidirectional clamping function applied to the battery cell of claim 1, wherein the clamping assembly (7) comprises a push rod (701), a movable block (702), a surrounding plate (703), a spring (704), a clamping block (705), a connecting rod (706), a clamping block (707) and a sliding block (708), the movable block (702) is fixedly connected to the right of the push rod (701), the surrounding plate (703) is fixedly connected to the lower portion of the movable block (702), the spring (704) is arranged on the inner side of the surrounding plate (703), the clamping block (705) is fixedly connected to the lower portion of the spring (704), the connecting rod (706) is symmetrically and rotatably connected to the front side and the rear side of the left of the movable block (702), the clamping block (707) is rotatably connected to the left of the connecting rod (706), and the sliding block (708) is fixedly connected to the lower portion of the clamping block (707).

3. The positioning fixture with the bidirectional clamping function applied to the battery cell of claim 2, wherein one end of the spring (704) far away from the clamping block (705) is fixedly connected with the movable block (702), and the clamping block (705) and the movable block (702) form a lifting structure through the spring (704).

4. The positioning fixture with the bidirectional clamping function applied to the battery cell of claim 2, wherein the fixture block (705) and the base plate (3) form an embedded structure through the fixture groove (5), and the fixture block (705) and the base plate (3) form a sliding structure through the moving groove (6).

5. The positioning fixture with the bidirectional clamping function applied to the battery core according to claim 2, wherein the sliding block (708) is embedded in the sliding groove (4), and the clamping block (707) forms a sliding structure with the backing plate (3) through the sliding block (708) and the sliding groove (4).

6. The positioning jig with the bidirectional clamping function applied to the battery cell of claim 1, wherein a central axis of the rotating plate (8) coincides with a central axis of the rotating disc (13), and the rotating plate (8) and the slow-speed motor (10) form a rotating structure through a belt.

7. The positioning fixture with the bidirectional clamping function applied to the battery cell of claim 1, wherein the slide rod (16) is slidably connected to the turntable (13), and the clamping plate (17) forms a sliding structure with the turntable (13) through the lifting rod (14), the top plate (15), the slide rod (16).