CN209737407U - Vertical formation fixture laminate auxiliary supporting structure - Google Patents

Abstract

The utility model discloses a vertical formation clamp laminate auxiliary supporting structure, in particular to the field of battery formation machinery, which comprises a vertical supporting frame, wherein a vertical formation clamp is arranged in the supporting frame; the formation clamp comprises a first connecting plate and a second connecting plate which are arranged in parallel up and down, four support guide columns which are arranged between the first connecting plate and the second connecting plate in parallel and symmetrically, a plurality of laminated plates which can be connected with the four support guide columns in a sliding way up and down, flexible connecting pieces are connected between the adjacent laminated plates, and a pushing mechanism pushes the laminated plates to clamp and form the battery; an elastic support is arranged between adjacent laminates. The elastic support plays an auxiliary supporting role for the laminated board, so that the gravity of the electric wire can be offset, and the laminated board is prevented from inclining; therefore, the problem that the laminated board and the supporting guide post are abraded greatly and even clamped when the laminated board slides up and down along the supporting guide post is avoided.

Description

Vertical formation fixture laminate auxiliary supporting structure

Technical Field

the utility model relates to a battery ization becomes anchor clamps field, concretely relates to vertical becomes anchor clamps plywood auxiliary stay structure that becomes.

Background

In battery formation, the battery needs to be clamped in a formation clamp. In the chinese patent literature, the patent numbers are: CN201420360240.8, which discloses a lithium ion battery formation clamp and formation equipment, the technical solution describes that a plurality of battery support plates are sequentially arranged up and down and slidably sleeved on a guide post, because the batteries need to be electrified and formed when being supported on the support plates, the support plates are provided with connection terminals, the connection terminals need to be connected with a formation power supply through wires, and the wires are arranged on the back of the support plates, the support plates are unbalanced in stress, and the support plates are inclined to one side; when pushing the backup pad through power unit and pushing down the battery, can increase the wearing and tearing of backup pad and guide pillar, cause the backup pad card to die even. In view of the above drawbacks, it is necessary to design a vertical jig-forming laminate auxiliary support structure.

SUMMERY OF THE UTILITY MODEL

The utility model discloses the technical problem that will solve lies in: the utility model provides a vertical formation anchor clamps plywood auxiliary support structure to solve present vertical formation anchor clamps and because set up the lamination board and connect into the electric wire, cause the problem of lamination board slope.

In order to solve the technical problem, the technical scheme of the utility model is that: the vertical formation clamp laminate auxiliary supporting structure comprises a vertical supporting frame, wherein a vertical formation clamp is arranged in the supporting frame; the formation clamp comprises a first connecting plate and a second connecting plate which are arranged in parallel up and down, four support guide columns which are arranged between the first connecting plate and the second connecting plate in parallel and symmetrically, a plurality of laminated plates which can be connected with the four support guide columns in a sliding way up and down, flexible connecting pieces are connected between the adjacent laminated plates, and a pushing mechanism pushes the laminated plates to clamp and form the battery; an elastic support is arranged between adjacent laminates.

Furthermore, the elastic supporting piece is a supporting spring sleeved at the upper end of the supporting guide pillar.

Furthermore, two connecting pieces are arranged at one end of the laminated board, which is connected with a formation power supply in an electric mode, and the elastic supporting piece is arranged between the upper connecting piece and the lower connecting piece which are adjacent to each other.

Further, a connecting rod penetrates through the connecting piece from top to bottom, and the connecting rod is connected with the connecting piece in a sliding mode; the elastic supporting piece is a compression spring which is sleeved on the connecting rod; the upper end and the lower end of the connecting rod are fixedly connected with the first connecting plate and the second connecting plate respectively.

Further, the pushing mechanism comprises a pressing component and a power component; the power assembly drives the pressing assembly to move downwards to push the laminated board to press the battery.

Further, the pressing assembly comprises two pressure sensors arranged on the inner side of the first connecting plate, a bearing plate connected with the two pressure sensors, a moving plate and a pressing plate close to the second connecting plate, and a pressure maintaining elastic assembly arranged between the moving plate and the pressing plate; the moving plate, the pressing plate and the laminated plate are connected with four support guide columns in a sliding mode from top to bottom; the laminated board adjacent to the pressing board is fixedly connected with the pressing board;

The power assembly comprises four parallel and symmetrically arranged lead screw pairs, two ends of a lead screw of each lead screw pair are respectively rotatably connected with the first connecting plate and the second connecting plate, a nut of each lead screw pair is tightly matched and connected with the movable plate, a driven gear is tightly sleeved at the lower end of the lead screw of each lead screw pair, an installation seat is arranged at the bottom of the first connecting plate, a driving motor is arranged on the installation seat, a driving gear is tightly sleeved on a main shaft of the driving motor, transition gears are arranged on two sides of the driving gear and are meshed with the two driven gears on the same side; the driving motor drives the transition gear to operate, so that the driven gear and the screw rod rotate to drive the moving plate to move up and down.

furthermore, the pressing assembly comprises two pressure sensors arranged on the first connecting plate, a bearing plate connected with the two pressure sensors, and a lower pressing plate connected with the four supporting guide pillars in a sliding manner, and the laminated plate is positioned between the bearing plate and the lower pressing plate; the power assembly is an air cylinder arranged on the second connecting plate, and the telescopic end of the air cylinder is connected with the lower pressing plate.

Further, the flexible connecting piece is canvas, a chain or a flexible rope for connecting the adjacent laminated boards; the pushing mechanism pushes the laminated plates to release the batteries, and the distances between the adjacent laminated plates are equal.

Compared with the prior art, the vertical forming fixture laminate auxiliary supporting structure has the following beneficial effects:

1. providing a resilient support between adjacent said laminates; therefore, the elastic support plays an auxiliary supporting role for the laminated board, the gravity of the electric wire can be offset, and the laminated board is prevented from inclining; therefore, the problem that the laminated board and the supporting guide post are abraded greatly and even clamped when the laminated board slides up and down along the supporting guide post is avoided.

Drawings

FIG. 1 is a front view of the auxiliary supporting structure for the laminate of the vertical forming jig of the present invention;

FIG. 2 is a front view of the vertical forming jig of the auxiliary supporting structure for the laminate of the vertical forming jig of the present invention;

FIG. 3 is a perspective view of the vertical jig of the auxiliary supporting structure for the laminate of the vertical jig of the present invention;

FIG. 4 is a block diagram of a portion of the laminate of the vertical form jig laminate auxiliary support structure of the present invention;

FIG. 5 is a block diagram of another embodiment of the laminate of the present invention in a vertical form jig laminate auxiliary support structure;

FIG. 6 is a perspective view of the laminate portion of the modular jig deck auxiliary support structure of the present invention;

FIG. 7 is a front view of the power pushing assembly of the vertical form-jig deck plate auxiliary support structure of the present invention;

FIG. 8 is a perspective view of the pushing assembly of the auxiliary support structure for a vertical jig deck of the present invention;

FIG. 9 is a schematic diagram of the power assembly of the vertical form jig deck auxiliary support structure of the present invention;

Fig. 10 is a structural view of another embodiment of the vertical jig of the present invention.

Detailed Description

The following detailed description will be further described in conjunction with the above-identified drawings.

In the following description, numerous specific details are set forth in order to provide a thorough understanding of the concepts underlying the described embodiments. It will be apparent, however, to one skilled in the art, that the described embodiments may be practiced without some or all of these specific details. In other instances, well known process steps have not been described in detail.

as shown in fig. 1-3, the auxiliary supporting structure for the laminate of the vertical formation clamp comprises a vertical supporting frame 1, wherein a vertical formation clamp 2 is arranged in the supporting frame 1; the formation clamp 2 comprises a first connecting plate 20 and a second connecting plate 21 which are arranged in parallel up and down, four support guide columns 22 which are arranged between the first connecting plate 20 and the second connecting plate 21 in parallel and symmetrically, a plurality of laminated plates 23 which are connected with the four support guide columns 22 in a vertically sliding manner, flexible connecting pieces 24 are connected between the adjacent laminated plates 23, and a pushing mechanism pushes 3 the laminated plates 23 to clamp the formation battery; between adjacent laminate sheets 23, a resilient support 4 is provided. The elastic support piece 4 plays an auxiliary supporting role for the laminated plate 23, so that the gravity of the electric wire can be offset, and the laminated plate 23 is prevented from inclining; therefore, the problem that the laminated board 23 and the supporting guide post 22 are abraded greatly and even clamped when the laminated board 23 slides up and down along the supporting guide post 22 is avoided.

Further, referring to fig. 4, the elastic supporting member 4 is a supporting spring sleeved on the upper end of the supporting guide pillar 22.

Further, referring to fig. 5, two connectors 230 are disposed at the end of the laminated board 23 to which the formation power supply is connected, and the elastic support member 4 is disposed between the connectors 230 adjacent to each other. The wires for formation power connection are connected to the back of the laminated board 23; by providing the connection members 230 at the terminals and providing the elastic support members 4 between the connection members 230, the stress of the laminate 23 is more balanced.

Further, referring to fig. 6, a connecting rod 231 penetrates the connecting member 230 from top to bottom, and the connecting rod 231 is slidably connected to the connecting member 230. The elastic supporting member 4 is a compression spring, and the compression spring is sleeved on the connecting rod 231; the upper and lower ends of the connecting rod 231 are fixedly connected with the first connecting plate 20 and the second connecting plate 21, respectively.

Further, referring to fig. 1-2 and 10, the pushing mechanism 3 includes a pressing assembly 30 and a power assembly 31; the power assembly 31 drives the pressing assembly 30 to move downwards, and the laminated board 23 is pushed to press the battery.

Further, referring to fig. 7 to 9, the pressing assembly 30 includes two pressure sensors 300 disposed inside the first connecting plate 21, a bearing plate 301 connecting the two pressure sensors 300, a moving plate 302 and a pressing plate 303 adjacent to the second connecting plate 21, and a pressure-maintaining elastic assembly 304 disposed between the moving plate 302 and the pressing plate 303. The moving plate 302, the pressing plate 303 and the laminated plate 23 are connected with four supporting guide columns 22 in a sliding manner from top to bottom; the adjacent laminate 23 of the press plate 303 is fixedly connected thereto.

Specifically, the pressure maintaining elastic assembly 304 includes a plurality of sets of pressure maintaining springs disposed between the moving plate 302 and the pressing plate 303, and a limiting rod passing through the pressure maintaining springs, a lower end of the limiting rod is fixedly connected with the pressing plate, an upper end of the limiting rod slidably penetrates through the moving plate 302, and a limiting portion is defined by the limiting rod. So that the holding pressure spring can be confined between the moving plate 302 and the pressing plate 303. Further, the pressure maintaining spring is a compression spring.

The power assembly 31 comprises four sets of parallel and symmetrically arranged screw rod pairs 310, two ends of a screw rod of each screw rod pair 310 are respectively rotatably connected with the first connecting plate 20 and the second connecting plate 21, a nut of each screw rod pair 310 is tightly matched and connected with the moving plate 302, a driven gear 311 is tightly sleeved at the lower end of the screw rod of each screw rod pair 310, an installation seat 312 is arranged at the bottom of the first connecting plate 20, a driving motor 313 is arranged on the installation seat 312, a driving gear 314 is tightly sleeved on a main shaft of the driving motor 313, transition gears 315 are respectively meshed at two sides of the driving gear 314, and the two transition gears 315 are meshed with the two driven gears 311 at the same side; the driving motor 313 drives the transition gear 315 to operate, so that the driven gear 311 and the lead screw rotate, and the moving plate 302 is driven to move up and down. Specifically, the mounting seat 312 includes a support rod and a mounting plate, the support rod is connected between the mounting plate and the first connecting plate 20; the driving motor 313 is fixedly connected to the mounting plate, and a main shaft of the driving motor 313 penetrates through the mounting plate. The lead screw of the lead screw pair 310 extends to be rotatably connected with the mounting plate, and the transition gear 315 is rotatably connected between the first connecting plate 20 and the mounting plate.

Further, in another embodiment of the pushing mechanism 3, referring to fig. 10 and fig. 4-6 in particular, the pressing assembly 30 includes two pressure sensors 3000 disposed on the first connecting plate 20, a carrier plate 3001 connecting the two pressure sensors 3000, and a lower pressing plate 3002 slidably connecting four support guide pillars 22, wherein the pressing plate 23 is located between the carrier plate 3001 and the lower pressing plate 3002; the power assembly 31 is a cylinder arranged on the second connecting plate 21, and the telescopic end of the cylinder is connected with the lower pressing plate 3002.

Further, the flexible connecting piece 24 is a canvas, a chain or a flexible rope connecting the adjacent laminated boards 23; the pushing mechanism 3 pushes the laminated plates 23 to release the batteries, so that the distances between the adjacent laminated plates 23 are equal.

Further, the flexible connectors 24 are located on both sides of the laminate 23.

The present invention is not limited to the above specific embodiments, and those skilled in the art can make various changes without creative labor from the above conception, and all the changes fall within the protection scope of the present invention.

Claims (8)

1. the vertical formation clamp laminate auxiliary supporting structure comprises a vertical supporting frame, wherein a vertical formation clamp is arranged in the supporting frame; the forming clamp is characterized by comprising a first connecting plate and a second connecting plate which are arranged in parallel up and down, four support guide columns which are arranged between the first connecting plate and the second connecting plate in parallel and symmetrically, a plurality of laminated plates which can be connected with the four support guide columns in a vertically sliding manner, flexible connecting pieces are connected between the adjacent laminated plates, and a pushing mechanism pushes the laminated plates to be clamped into a battery; an elastic support is arranged between adjacent laminates.

2. The vertical jig forming jig deck auxiliary support structure as claimed in claim 1, wherein the elastic support member is a support spring fitted over the upper ends of the support guide posts.

3. the auxiliary supporting structure for the laminated plate of the vertical formation jig of claim 1, wherein two connecting pieces are arranged at the end of the laminated plate, which is connected with the formation power supply, and the elastic supporting piece is arranged between the connecting pieces which are adjacent up and down.

4. The auxiliary support structure for vertically forming a jig deck as claimed in claim 3, wherein a connecting rod penetrates the connecting member from top to bottom, the connecting rod being slidably connected to the connecting member; the elastic supporting piece is a compression spring which is sleeved on the connecting rod; the upper end and the lower end of the connecting rod are fixedly connected with the first connecting plate and the second connecting plate respectively.

5. The vertical built-up jig deck auxiliary support structure of any one of claims 1 to 4, wherein the pushing mechanism comprises a pressing assembly and a power assembly; the power assembly drives the pressing assembly to move downwards to push the laminated board to press the battery.

6. The auxiliary support structure for a vertically formed jig laminate according to claim 5, wherein the pressing member comprises two pressure sensors disposed inside the first connecting plate, a bearing plate connecting the two pressure sensors, a moving plate and a pressing plate adjacent to the second connecting plate, and a pressure maintaining elastic member disposed between the moving plate and the pressing plate; the moving plate, the pressing plate and the laminated plate are connected with four support guide columns in a sliding mode from top to bottom; the laminated board adjacent to the pressing board is fixedly connected with the pressing board;

the power assembly comprises four parallel and symmetrically arranged lead screw pairs, two ends of a lead screw of each lead screw pair are respectively rotatably connected with the first connecting plate and the second connecting plate, a nut of each lead screw pair is tightly matched and connected with the movable plate, a driven gear is tightly sleeved at the lower end of the lead screw of each lead screw pair, an installation seat is arranged at the bottom of the first connecting plate, a driving motor is arranged on the installation seat, a driving gear is tightly sleeved on a main shaft of the driving motor, transition gears are arranged on two sides of the driving gear and are meshed with the two driven gears on the same side; the driving motor drives the transition gear to operate, so that the driven gear and the screw rod rotate to drive the moving plate to move up and down.

7. The vertical jig forming jig deck auxiliary support structure of claim 5 wherein the hold-down assembly comprises two pressure sensors disposed on the first connecting plate, a carrier plate connecting the two pressure sensors, and a lower press plate slidably connecting the four support guide posts, the laminate plate being located between the carrier plate and the lower press plate; the power assembly is an air cylinder arranged on the second connecting plate, and the telescopic end of the air cylinder is connected with the lower pressing plate.

8. a vertical formed-clamp deck auxiliary support structure as defined in claim 1 wherein said flexible links are canvas, chains or flexible cables connecting adjacent said laminates; the pushing mechanism pushes the laminated plates to release the batteries, and the distances between the adjacent laminated plates are equal.