CN116885367A

CN116885367A - Double-row module stacking device

Info

Publication number: CN116885367A
Application number: CN202310602140.5A
Authority: CN
Inventors: 邵建海
Original assignee: Shenggao Energy Technology Jiangsu Co ltd
Current assignee: Shenggao Energy Technology Jiangsu Co ltd
Priority date: 2023-05-26
Filing date: 2023-05-26
Publication date: 2023-10-13

Abstract

The invention relates to a double-row module stacking device, which comprises: a base; fixed side pressure fixing components horizontally arranged on two sides of the base; cell mounting of base both sides in addition is located to the activity, and cell mounting includes: the axial pressing plate is rotationally connected with the control motor; a stabilizing piece rotatably connected between the control motor and the axial pressing plate; and the battery core pressing plate is arranged above the base, and a welding opening is formed in the battery core pressing plate. The double-row battery cells are adopted for one-time bundling, so that the bundling efficiency is improved, and the battery cells are convenient to hoist; the highland barley paper is filled between the electric cores, so that the electric cores have better insulation and heat insulation buffer effects, and the safety of the electric cores in the use process is improved; through changing unilateral locking into two-side simultaneous locking mode, make electric core both sides inwards compress tightly simultaneously, the atress is even, avoids the atress inconsistent between the electric core, produces extrusion wearing and tearing.

Description

Double-row module stacking device

Technical Field

The invention belongs to the technical field of energy storage, and particularly relates to a double-row module stacking device.

Background

The industrial and commercial energy storage is carried out by selecting 280Ah single cells, screening by internal resistance and voltage, entering a module stacking process, stacking 12 or 13 280Ah single cells in a single row, spacing the two single cells by using an epoxy resin plate, extruding the single cells in a single row by using a jig, stopping extrusion when the extrusion force reaches a set value, sleeving a steel belt, unloading the extrusion force, stressing the steel belt, and completing the bundling of the modules. After the bundling process is finished, a special aluminum-palladium jig is sleeved on the module, aluminum-palladium is placed by hands of workers, and the laser welding process is performed.

The form of single electric core makes electric core take place difficultly in handling process, influences the stability between electric core and the electric core, influences operating efficiency.

Disclosure of Invention

In order to solve the technical problems, the invention provides a double-row module stacking device which has the advantage of high production efficiency.

In order to achieve the above purpose, the technical scheme of the invention is as follows:

a dual row module stacking apparatus comprising: a base; fixed side pressure fixing components horizontally arranged on two sides of the base; the movable electric core mounting of locating the other both sides of base, electric core mounting includes: the axial pressing plate is rotationally connected with the control motor; a stabilizing piece rotatably connected between the control motor and the axial pressing plate; and the battery cell pressing plate is arranged above the base, and a welding opening is formed in the battery cell pressing plate.

As a preferable scheme of the invention, two groups of heat dissipation grooves are horizontally arranged on the base.

According to the technical scheme, the heat dissipation of the battery cell is achieved by adopting the arrangement of the heat dissipation groove.

As a preferred aspect of the present invention, the side pressure fixing assembly includes: the first side pressing plate is far away from the second side pressing plate arranged on the first side pressing plate, and a plurality of groups of supporting plates are fixedly arranged on one side of the second side pressing plate.

According to the technical scheme, the first side pressing plate and the second side pressing plate are arranged, and the battery cell is fixed.

As a preferred solution to the present invention, the cell fixing members are symmetrically arranged, and the stabilizing member includes: the guide pressing plate is rotationally connected with the output end of the control motor, and is slidably arranged on the base.

According to the technical scheme, the stability of the axial pressing plate in the moving process is improved through the arrangement of the guide pressing plate.

As a preferable scheme of the invention, two sides of the axial pressing plate are also movably provided with electric core fixing steel belts, and two sides of each electric core fixing steel belt are fixedly provided with electric core fixing side plates.

According to the technical scheme, the electric core fixing steel belt is arranged, so that the electric core is further fixed, and the fixing stability is improved.

As a preferable scheme of the invention, two sides of the control motor are provided with holding handles, the holding handles are fixedly arranged on the base, and the holding handles are provided with four groups.

As a preferable scheme of the invention, a plurality of groups of welding ports are formed, the welding ports are movably provided with welding connecting plates, and welding sites are formed on two sides of each welding connecting plate.

By means of the technical scheme, through the arrangement of the welding sites, connection between the battery cells is facilitated.

As a preferable scheme of the invention, two sides of the axial pressing plate are provided with a displacement sensor and a pressure sensor, the displacement sensor is used for monitoring the feeding process of the control motor, and the pressure sensor is used for monitoring the feeding pressure of the control motor.

In summary, the invention has the following beneficial effects:

When the battery cell is fixed, firstly, the battery cell is placed on the base 1, an insulating and heat-insulating buffer material, namely highland barley paper, is placed between the battery cell and the battery cell, so that the battery cell is effectively isolated, the battery cell is preliminarily fixed through the first side pressing plate 7 and the second side pressing plate 8, and the battery cell fixing steel belts 13 are wrapped at two ends of the battery cell, so that the axial pressing plate 3 is convenient for fixing two sides of the battery cell; further, under the action of the guide sleeve 7, the control motor 2 drives the axial pressing plates 3 to be fixed to two sides of the battery cell, so that the battery cell fixing steel belt 13 can fix the side edges of the battery cell, and when the axial pressing plates 3 at two sides are fixed to two sides of the battery cell, under the action of the displacement sensor 18 and the pressure sensor 19, the stress is uniform, so that the binding pressure between the battery cells is kept consistent; meanwhile, the fixed sizes among the battery cores are consistent, so that the size errors are reduced, and the external sizes of the modules are ensured to be consistent; finally, the cell pressing plate 4 is pressed on the cell, the size of the cell pressing plate 4 can be kept all the time due to the outline dimension of the module, the cell pressing plate 4 with different sizes does not need to be replaced, the welding port 5 on the cell pressing plate 4 corresponds to the electrode between the cell, the welding connection plate 16 is placed in the welding port 5, the welding connection plate 16 is welded with the cell, connection between the cell and the cell is achieved, the motor 2 is controlled to release the pressing force, the cell expansion tightens the cell fixing steel belt 13, and binding operation of the cell is achieved.

To sum up:

1. the double-row battery cells are adopted for one-time bundling, so that the bundling efficiency is improved, and the battery cells are convenient to hoist;

2. the highland barley paper is filled between the electric cores, so that the electric cores have better insulation and heat insulation buffer effects, and the safety of the electric cores in the use process is improved;

3. the two sides of the battery core can be simultaneously and inwards pressed by changing the single-side locking mode into the two-side simultaneous locking mode, so that the stress is uniform, and extrusion abrasion caused by inconsistent stress among the battery cores is avoided;

4. the arrangement of the displacement sensor 18 and the pressure sensor 19 controls the feeding process of the control motor 2, so that the consistency of the external dimensions of the modules and the consistency of the binding pressure of the modules are realized, the dimensional error is reduced, and the mass production is facilitated;

5. the manual operation is changed into semi-automatic control semi-manual operation, and the production efficiency is higher.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings that are required in the embodiments or the description of the prior art will be briefly described, and it is obvious that the drawings in the following description are some embodiments of the present invention, 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 perspective view of the present invention.

Fig. 2 is a schematic view of the structure of the base plate of the present invention.

Fig. 3 is a schematic view of the structure of the cell fixing steel strip of the present invention.

Fig. 4 is a schematic structural diagram of a cell platen according to the present invention.

Corresponding part names are indicated by numerals and letters in the drawings:

1. a base; 2. controlling a motor; 3. an axial pressing plate; 4. a cell platen; 5. a welding port; 6. a heat sink; 7. a first side pressure plate; 8. a second side pressure plate; 9. a support plate; 10. a guide pressing plate; 11. a guide rail; 12. guide sleeve; 13. the cell fixing steel belt; 14. a battery cell fixing side plate; 15. a grip handle; 16. welding a connecting plate; 17. a welding site; 18. a displacement sensor; 19. a pressure sensor.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below in connection with the embodiments of the present invention. It will be apparent that the described embodiments are only some, but not all, embodiments of the invention. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

Examples

A double row module stacking apparatus, as shown in fig. 1 to 4, comprising: a base 1; side pressure fixing components horizontally arranged on two sides of the base 1 are fixed; and the cell fixing pieces are movably arranged on the other two sides of the base 1.

Wherein, electric core mounting includes: the control motor 2 and the axial pressing plate 3 are rotationally connected with the control motor 2; a stabilizing piece arranged between the control motor 2 and the axial pressing plate 3; and a cell pressing plate 4 arranged above the base 1, wherein a welding port 5 is formed on the cell pressing plate 4, and two groups of heat dissipation grooves 6 are horizontally formed on the base 1.

The side pressure fixing assembly includes: the first side board 7, keep away from the second side board 8 that first side board 7 set up, in this embodiment, backup pad 9 is provided with six groups, and backup pad 9 is fixed to be located second side board 8 one side.

Specifically, the cell fixing components are symmetrically arranged on two sides of the base 1, the stabilizing piece is composed of a guide pressing plate 10, a guide rail 11 and a guide sleeve 12, the guide rail 11 is arranged on two sides of the guide pressing plate 10, the guide pressing plate 10 is rotationally connected with the output end of the control motor 2, and the guide pressing plate 10 is slidably arranged on the base 1.

When the battery cell is placed on the base 1, the first side pressing plate 7 and the second side pressing plate 8 are used for preliminarily positioning the battery cell,

the two sides of the axial pressing plate 3 are also movably provided with the electric core fixing steel belts 13, the two sides of the electric core fixing steel belts 13 are fixedly provided with electric core fixing side plates 14, the electric core fixing steel belts 13 fix the other two sides of the electric core, and the electric core is finally fixed by controlling the motor 2 to drive the axial pressing plate 3.

Further, two sides of the control motor 2 are provided with holding handles 15, the holding handles 15 are fixedly arranged on the base 1, and the holding handles 15 are provided with four groups.

In the embodiment, the welding ports 5 are provided with 24 groups, the welding ports 5 are movably provided with welding connection plates 16, and welding sites 17 are formed on two sides of the welding connection plates 16, so that the placement and connection between 24 groups of electric cores are realized.

Finally, displacement sensors 18 and pressure sensors 19 are arranged on two sides of the axial pressing plate 3, the displacement sensors 18 are used for monitoring and controlling the feeding process of the motor 2, the displacement sensors 18 are arranged in an infrared sensor mode, and the pressure sensors 19 are used for monitoring and controlling the feeding pressure of the motor 2.

To sum up:

The previous description of the disclosed embodiments is provided to enable any person skilled in the art to make or use the present invention. Various modifications to these embodiments will be readily apparent to those skilled in the art, and the generic principles defined herein may be applied to other embodiments without departing from the spirit or scope of the invention. Thus, the present invention is not intended to be limited to the embodiments shown herein but is to be accorded the widest scope consistent with the principles and novel features disclosed herein.

Claims

1. A double row module stacking apparatus, comprising:

a base (1);

the side pressure fixing assemblies are fixedly and horizontally arranged on two sides of the base (1);

the movable battery cell fixing piece of locating base (1) other both sides, the battery cell fixing piece includes: the device comprises a control motor (2) and an axial pressing plate (3) rotationally connected with the control motor (2);

a stabilizing piece rotatably connected between the control motor (2) and the axial pressing plate (3); the method comprises the steps of,

and a battery core pressing plate (4) arranged above the base (1), wherein a welding port (5) is formed in the battery core pressing plate (4).

2. The double-row module stacking device according to claim 1, wherein two groups of heat dissipation grooves (6) are horizontally formed in the base (1).

3. The dual row module stacking device of claim 1, wherein said side pressure fixing assembly comprises: the device comprises a first side pressing plate (7) and a second side pressing plate (8) which is far away from the first side pressing plate (7), wherein a plurality of groups of supporting plates (9) are fixedly arranged on one side of the second side pressing plate (8).

4. The dual row module stacking device of claim 1, wherein said cell fixtures are symmetrically arranged, said stabilizing means comprising: the guide pressing plate (10), locate guide rail (11) of guide pressing plate (10) both sides and locate guide pin bushing (12) on guide rail (11), guide pressing plate (10) with the output of control motor (2) rotates to be connected, just guide pressing plate (10) slidingtype is located on base (1).

5. The double-row module stacking device according to claim 1, wherein two sides of the axial pressing plate (3) are further movably provided with cell fixing steel belts (13), and cell fixing side plates (14) are fixedly arranged on two sides of the cell fixing steel belts (13).

6. The double-row module stacking device according to claim 1, wherein holding handles (15) are arranged on two sides of the control motor (2), the holding handles (15) are fixedly arranged on the base (1), and four groups of holding handles (15) are arranged.

7. The double-row module stacking device according to claim 1, wherein the welding ports (5) are provided with a plurality of groups, the welding ports (5) are movably provided with welding connection plates (16), and welding sites (17) are formed on two sides of the welding connection plates (16).

8. A double row module stacking device according to claim 1, characterized in that the axial pressure plate (3) is provided with a displacement sensor (18) and a pressure sensor (19) on both sides, the displacement sensor (18) being used for monitoring the feeding process of the control motor (2), the pressure sensor (19) being used for monitoring the feeding pressure of the control motor (2).