CN220484631U - Electric core stacking mechanism - Google Patents

Abstract

The utility model discloses a battery cell stacking mechanism, which relates to the technical field of power battery production and comprises a base, wherein a material taking mechanism is arranged at the rear end of the top of the base, two side plates are fixedly connected at the front end of the top of the base, a material containing frame is arranged between the side plates, longitudinal sliding grooves are formed in the side plates, a rotating mechanism for driving the material containing frame to rotate is slidably arranged in each sliding groove, a screw rod for driving the rotating mechanism to lift is rotatably arranged in each sliding groove of one side plate, and a power mechanism for driving the material taking mechanism and the screw rod to rotate is arranged in the base. The beneficial effects are that: according to the utility model, the feeding mechanism is driven to rotate and the material containing frame is driven to move downwards simultaneously by the power mechanism, the battery cells are stacked on the material containing frame by the feeding mechanism along with the gradual downward movement of the material containing frame, and the material containing frame is rotated ninety degrees by the rotating mechanism after the battery cells are stacked, so that the battery cell module is convenient to take out and more convenient to use.

Description

Electric core stacking mechanism

Technical Field

The utility model relates to the technical field of power battery production, in particular to a battery core stacking mechanism.

Background

The power battery is a power source for providing power for tools, and is a storage battery for providing power for electric automobiles, electric trains, electric bicycles and golf carts. The power battery is a core component of a new energy automobile and is also an important direction of energy transformation in the future.

Through retrieval, chinese patent publication No. CN217983457U discloses a battery cell stacking device and a battery module assembly line, and the battery cell stacking device provided by the utility model has the advantages that the stacking mechanism can clamp the battery cells from the preset positions and enable the battery cells to slide down to the stacking part through the guide part, so that continuous stacking of the battery cells is realized, the stacking process of the battery cells is simplified, and the stacking efficiency of the battery cells is improved. However, after the stacking mechanism stacks the battery cells, the battery module is inconvenient to take out from the stacking mechanism due to the fact that the stacking mechanism limits the battery, and the battery module is inconvenient to use.

Disclosure of Invention

The present utility model is directed to a cell stacking mechanism for solving the above-mentioned problems.

The utility model realizes the above purpose through the following technical scheme:

the utility model provides an electricity core stacking mechanism, includes the base, base top rear end is provided with the feeding mechanism, base top front end fixedly connected with two curb plates, be provided with flourishing work or material rest between the curb plate, seted up fore-and-aft spout on the curb plate, sliding fit has and is used for the drive flourishing work or material rest pivoted rotary mechanism in the spout, one the curb plate spout internally mounted have and are used for the drive rotary mechanism goes up and down the lead screw, be provided with in the base and be used for the drive feeding mechanism with lead screw pivoted power unit.

Preferably, the material containing frame is concave, and two sides of the material containing frame are contacted with the side plates.

Preferably, the rotating mechanism comprises sliding blocks, the sliding blocks are slidably connected in the sliding grooves, rotating shafts are rotatably connected between the sliding blocks, a first motor is fixedly connected to one sliding block, and an output shaft of the first motor is fixedly connected with the rotating shafts.

Preferably, the bottom of the material containing frame is fixedly connected with a connecting block, the connecting block is fixedly connected with the rotating shaft, and the screw rod is in threaded connection with the sliding block on one side far away from the first motor.

Preferably, the power mechanism comprises a second motor, the second motor is fixedly connected in the base, an output shaft of the second motor is fixedly connected with the screw rod, a driving synchronizing wheel is fixedly connected on the screw rod and is connected with a driven synchronizing wheel through a synchronous belt, a transmission shaft is fixedly connected in the driven synchronizing wheel, and the transmission shaft is rotatably installed in the base.

Preferably, the material taking mechanism comprises a rotary table, the rotary table is fixedly connected to the top of the transmission shaft, the rotary table top is fixedly connected with a mounting frame, the front side of the mounting frame is fixedly connected with a fixing plate, and the top of the fixing plate is provided with a material clamping assembly.

The beneficial effects are that: according to the utility model, the feeding mechanism is driven to rotate and the material containing frame is driven to move downwards simultaneously by the power mechanism, the battery cells are stacked on the material containing frame by the feeding mechanism along with the gradual downward movement of the material containing frame, and the material containing frame is rotated ninety degrees by the rotating mechanism after the battery cells are stacked, so that the battery cell module is convenient to take out and more convenient to use.

Additional features and advantages of the utility model will be set forth in the description which follows, or may be learned by practice of the utility model.

Drawings

The accompanying drawings are included to provide a further understanding of the utility model, and are incorporated in and constitute a part of this specification, illustrate the utility model and together with the description serve to explain, without limitation, the utility model. In the drawings:

FIG. 1 is a perspective view of a cell stacking mechanism according to the present utility model;

fig. 2 is a left side view of a cell stacking mechanism according to the present utility model;

fig. 3 is a front view of a cell stacking mechanism according to the present utility model;

fig. 4 is a left side view of the internal structure of the base of the cell stacking mechanism according to the present utility model;

FIG. 5 is a perspective view of a side plate, a material containing frame and a rotating mechanism of a cell stacking mechanism according to the present utility model;

fig. 6 is a top view of the internal structure of the base of the cell stacking mechanism according to the present utility model.

The reference numerals are explained as follows: 1. a base; 2. a material taking mechanism; 201. a turntable; 202. a mounting frame; 203. a fixing plate; 204. a clamping assembly; 3. a side plate; 301. a chute; 4. a material containing frame; 401. a connecting block; 5. a rotation mechanism; 501. a slide block; 502. a rotating shaft; 503. a first motor; 6. a screw rod; 7. a power mechanism; 701. a second motor; 702. a driving synchronizing wheel; 703. a driven synchronizing wheel; 704. and a transmission shaft.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments.

In the description of the present utility model, it should be understood that the terms "upper," "lower," "front," "rear," "left," "right," "top," "bottom," "inner," "outer," and the like indicate or are based on the orientation or positional relationship shown in the drawings, merely to facilitate description of the present utility model and to simplify the description, and do not indicate or imply that the devices or elements referred to must have a specific orientation, be configured and operated in a specific orientation, and thus should not be construed as limiting the present utility model.

The utility model is further described below with reference to the accompanying drawings:

as shown in fig. 1-6, a battery core stacking mechanism comprises a base 1, wherein a material taking mechanism 2 is arranged at the rear end of the top of the base 1, two side plates 3 are fixedly connected to the front end of the top of the base 1, a material containing frame 4 is arranged between the side plates 3, the material taking mechanism 2 clamps battery cores on an externally arranged feeding device and stacks the battery cores on the material containing frame 4, a longitudinal sliding groove 301 is formed in the side plates 3, a rotating mechanism 5 for driving the material containing frame 4 to rotate is arranged in the sliding groove 301 in a sliding manner, a screw rod 6 for driving the rotating mechanism 5 to lift is rotatably arranged in the sliding groove 301 of one side plate 3, a power mechanism 7 for driving the material taking mechanism 2 and the screw rod 6 to rotate is arranged in the base 1, the material taking mechanism 2 is driven to rotate so as to clamp materials conveniently, meanwhile, the power mechanism 7 drives the screw rod 6 to rotate so that the rotating mechanism 5 drives the material containing frame 4 to move downwards gradually, and after the material taking mechanism 2 stacks the battery cores on the material containing frame 4 one by one, the material containing frame 4 is rotated by the rotating mechanism 5 so that the material containing frame 4 is flattened through the rotating mechanism 4 so as to be convenient for taking a battery module out manually;

the material containing frame 4 is concave, and two sides of the material containing frame 4 are contacted with the side plates 3, so that the placement of the battery cells is convenient, and the battery cells are prevented from falling;

the rotating mechanism 5 comprises sliding blocks 501, the sliding blocks 501 are slidably connected in the sliding grooves 301, a rotating shaft 502 is connected between the sliding blocks 501 through bearings, a first motor 503 is connected to one sliding block 501 through a screw, and an output shaft of the first motor 503 is fixedly connected with the rotating shaft 502;

the bottom of the material containing frame 4 is fixedly connected with a connecting block 401, the connecting block 401 is fixedly connected with a rotating shaft 502, the rotating shaft 502 is driven to rotate by a first motor 503, the rotating shaft 502 drives the material containing frame 4 to rotate by the connecting block 401, the material containing frame 4 rotates from a vertical state to a horizontal state, manual material taking is facilitated, and a screw rod 6 is connected with a sliding block 501 on one side far away from the first motor 503 through threads;

the power mechanism 7 comprises a second motor 701, the second motor 701 is connected in the base 1 through a screw, an output shaft of the second motor 701 is connected with the screw rod 6 through a coupling, a driving synchronous wheel 702 is fixedly connected to the screw rod 6, the driving synchronous wheel 702 is connected with a driven synchronous wheel 703 through a synchronous belt, a transmission shaft 704 is fixedly connected in the driven synchronous wheel 703, the transmission shaft 704 is arranged in the base 1 through a bearing, the top end of the transmission shaft 704 is fixedly connected with the material taking mechanism 2, the screw rod 6 is driven to rotate through the second motor 701, the screw rod 6 drives the transmission shaft 704 to rotate through the driving synchronous wheel 702 and the driven synchronous wheel 703, so that the material taking mechanism 2 always rotates in one direction, the material taking mechanism 2 clamps when facing towards the battery cell, meanwhile, the material containing frame 4 moves downwards, and then the material taking mechanism 2 continues to rotate and discharges towards the material containing frame 4;

the material taking mechanism 2 comprises a rotary table 201, the rotary table 201 is fixedly connected to the top of a transmission shaft 704, a mounting frame 202 is connected to the top of the rotary table 201 through screws, a fixing plate 203 is connected to the front side of the mounting frame 202 through screws, and a material clamping assembly 204 is mounted on the top of the fixing plate 203.

Working principle: when the battery charging device is used, after an external feeding device sends a battery cell, the second motor 701 drives the screw rod 6 to rotate, meanwhile, the screw rod 6 drives the driving synchronous wheel 702 to rotate, the driving synchronous wheel 702 drives the driven synchronous wheel 703 to rotate through the synchronous belt, the driven synchronous wheel 703 drives the transmission shaft 704 to rotate, the transmission shaft 704 drives the rotary table 201 to rotate, the whole taking mechanism 2 is enabled to rotate, when the material clamping assembly 204 faces the battery cell, the material clamping assembly 204 clamps the battery cell, then the taking mechanism 2 continues to rotate towards the same direction until the material clamping assembly 204 faces the material containing frame 4, the material clamping assembly 204 stacks the battery cell on the material containing frame 4, in the process, the screw rod 6 rotates to drive one sliding block 501 to move downwards, one sliding block 501 drives the other sliding block 501 to move downwards synchronously through the rotary shaft 502, so that the rotary shaft 502 drives the material containing frame 4 to move downwards gradually, the battery cell is enabled to be stacked on the material containing frame 4 one by one, when the battery cell is stacked on the material containing frame 4, the bottom of the material containing frame 4 is close to the top of the base 1, then the sliding block 502 is driven to rotate in the same direction until the battery cell is driven to rotate 401, and the battery cell is conveniently rotated to a horizontal state.

The foregoing has shown and described the basic principles, principal features and advantages of the utility model. It will be understood by those skilled in the art that the present utility model is not limited to the embodiments described above, and that the above embodiments and descriptions are merely illustrative of the principles of the present utility model, and various changes and modifications may be made without departing from the spirit and scope of the utility model, which is defined in the appended claims. The scope of the utility model is defined by the appended claims and their equivalents.

Claims (6)

1. The utility model provides a electricity core stacking mechanism, includes base (1), base (1) top rear end is provided with feeding mechanism (2), its characterized in that: the automatic feeding device is characterized in that two side plates (3) are fixedly connected to the front end of the top of the base (1), a material containing frame (4) is arranged between the side plates (3), a longitudinal sliding groove (301) is formed in the side plates (3), a rotating mechanism (5) used for driving the material containing frame (4) to rotate is arranged in the sliding groove (301), a screw rod (6) used for driving the rotating mechanism (5) to lift is arranged in the sliding groove (301) of the side plates (3) in a rotating mode, and a power mechanism (7) used for driving the material taking mechanism (2) and the screw rod (6) to rotate is arranged in the base (1).

2. The cell stacking mechanism of claim 1, wherein: the material containing frame (4) is concave, and two sides of the material containing frame (4) are contacted with the side plates (3).

3. The cell stacking mechanism of claim 1, wherein: the rotating mechanism (5) comprises sliding blocks (501), the sliding blocks (501) are slidably connected in the sliding grooves (301), rotating shafts (502) are rotatably connected between the sliding blocks (501), one sliding block (501) is fixedly connected with a first motor (503), and an output shaft of the first motor (503) is fixedly connected with the rotating shafts (502).

4. A cell stacking mechanism according to claim 3, wherein: the bottom of the material containing frame (4) is fixedly connected with a connecting block (401), the connecting block (401) is fixedly connected with the rotating shaft (502), and the screw rod (6) is in threaded connection with a sliding block (501) on one side far away from the first motor (503).

5. The cell stacking mechanism of claim 1, wherein: the power mechanism (7) comprises a second motor (701), the second motor (701) is fixedly connected in the base (1), an output shaft of the second motor (701) is fixedly connected with the screw rod (6), a driving synchronizing wheel (702) is fixedly connected on the screw rod (6), the driving synchronizing wheel (702) is connected with a driven synchronizing wheel (703) through a synchronous belt, a transmission shaft (704) is fixedly connected in the driven synchronizing wheel (703), and the transmission shaft (704) is rotatably installed in the base (1).

6. The cell stacking mechanism of claim 5, wherein: the material taking mechanism (2) comprises a rotary table (201), the rotary table (201) is fixedly connected to the top of a transmission shaft (704), a mounting frame (202) is fixedly connected to the top of the rotary table (201), a fixing plate (203) is fixedly connected to the front side of the mounting frame (202), and a material clamping assembly (204) is mounted on the top of the fixing plate (203).