CN216660810U - A turnover box that is used for lithium ion battery ization to become partial volume cabinet - Google Patents

Abstract

The utility model relates to the technical field related to a battery formation and capacity grading cabinet, in particular to a turnover box for a lithium ion battery formation and capacity grading cabinet. This turnover box includes: the battery box comprises a box body with an upward opening for placing a cuboid battery and a battery placing area arranged in the box body; the battery box comprises a box body, a plurality of battery jar baffles and a plurality of battery jar baffles, wherein the cuboid inner cavity of the box body is vertically provided with two vertical rows of battery jar baffles along the length direction, and the box body and the battery jar baffles are integrally formed in an integral injection molding mode; every two liang of correspondences of every row battery jar baffle form a set of, form a battery between two corresponding battery jar baffles of every group and place the district, lie in two battery jar baffles of the left and right sides of outside and cuboid inner chamber left and right sides face respectively and form the battery and place the district. The utility model is convenient for the placement and the removal of the turnover box on the battery formation and capacity grading cabinet, can shorten the time for loading and unloading the batteries, save the time cost for loading and unloading the batteries, accelerate the process progress of the batteries and increase the utilization rate of the capacity grading cabinet.

Description

A turnover box that is used for lithium ion battery ization to become partial volume cabinet

Technical Field

The utility model relates to the technical field related to a battery formation and grading cabinet, in particular to a turnover box for a lithium ion battery formation and grading cabinet, which is used as a clamp for placing a battery on the formation and grading cabinet.

Background

The lithium ion battery is an important component in the field of new energy, has been developed greatly by virtue of the advantages of light weight, high specific energy, high working voltage, long service life, low self-discharge and the like, and is rapidly applied to the fields of various modern mobile communication devices and portable electronic devices. In practice, it is found that the capacities of the single batteries produced in batches under the same process conditions are different and even far from each other. Therefore, the capacity grading process is a crucial link in the production process of the battery core. But present formation grading cabinet's anchor clamps technique has following problem: the battery formation and capacity grading is an important step in the battery production process, and production staff need to frequently carry out one battery formation and capacity grading upper and lower cabinet operation in the existing operation. Therefore, the time for loading the cabinet is long, and great potential safety hazards exist. Meanwhile, the utilization rate of the chemical component capacitance cabinet is also influenced.

SUMMERY OF THE UTILITY MODEL

The utility model aims to provide a turnover box for a lithium ion battery formation and capacity division cabinet, which improves the efficiency of loading and unloading batteries, shortens the time of loading and unloading batteries, accelerates the process progress of batteries, improves the utilization rate of the capacity division cabinet, saves energy, reduces consumption and lightens the labor intensity.

In order to achieve the above purpose, the utility model provides the following technical scheme:

a transfer case for a lithium ion battery dispensing cabinet, the transfer case comprising: the battery box comprises a box body with an upward opening for placing a cuboid battery and a battery placing area arranged in the box body; the battery box comprises a box body, a plurality of battery jar baffles and a plurality of battery jar baffles, wherein the cuboid inner cavity of the box body is vertically provided with two vertical rows of battery jar baffles along the length direction, and the box body and the battery jar baffles are integrally formed in an integral injection molding mode; every two liang of correspondences of every row battery jar baffle form a set of, form a battery between two corresponding battery jar baffles of every group and place the district, lie in two battery jar baffles of the left and right sides of outside and cuboid inner chamber left and right sides face respectively and form the battery and place the district.

The turnover box for the lithium ion battery chemical component storage cabinet is characterized in that the box body is of a structure that a stacking groove and a battery groove are communicated with each other vertically, the upper surface of the battery groove is provided with an opening, the front surface, the upper surface and the lower surface of the stacking groove are provided with openings, and a cuboid inner cavity for installing a baffle plate of the battery groove is formed in the battery groove.

When the turnover boxes are stacked up and down, the battery grooves of the turnover boxes on the upper layer correspond to and are matched with the stacking grooves of the turnover boxes on the lower layer.

The turnover box for the lithium ion battery formation and capacity-dividing cabinet is characterized in that the battery placement area is formed by rectangular grooves which are arranged between battery groove baffles and are used for placing batteries at intervals.

The turnover box for the lithium ion battery formation and capacity grading cabinet is characterized in that two adjacent battery placing areas are arranged, the distance corresponds to the distance between two adjacent probes on the formation and capacity grading cabinet, and a 15-25 mm gap is reserved between the two adjacent battery placing areas according to the distance between probe points of the formation and capacity grading cabinet.

The turnover box for the lithium ion battery formation component container cabinet is characterized in that the height of each battery jar baffle is 60-80 mm, and the width of each battery jar baffle is 5-15 mm.

A turnover box for lithium ion battery ization becomes to hold cabinet, all set up the transport handle on two sides of box body of turnover box, and the bottom surface of transport handle is equipped with the recess that the hand can stretch into.

The turnover box for the lithium ion battery component container cabinet is characterized in that two opposite parallel positioning grooves are transversely formed in the bottom surface of the box body, reinforcing ribs are uniformly and parallelly distributed on the bottom surface of the box body and are vertical to the positioning grooves, and when the turnover boxes are stacked, the reinforcing ribs on the bottom surface of the upper turnover box are positioned between two adjacent battery placing areas of the next turnover box; the positioning groove of the turnover box at the upper layer is positioned between the adjacent reinforcing ribs and corresponds to the battery placing area of the turnover box at the lower layer.

When the turnover box for the lithium ion battery formation and capacity-dividing cabinet is used, the battery pole is upwards placed in the battery placing area.

Compared with the prior art, the utility model has the following advantages and beneficial effects:

1. the utility model improves the utilization rate of the chemical composition grading cabinet, saves energy and reduces consumption.

2. The utility model can shorten the time for loading the battery into the cabinet, quicken the process progress of the battery and improve the production efficiency more safely.

3. The utility model can carry out the operation of loading and unloading the batteries in batches, thereby reducing the working time, saving the labor cost and lightening the labor intensity.

4. The structure of the battery clamp is changed, so that the battery clamp for fixing the battery can flexibly go up and down the formation and grading cabinet, the battery can go up and down the cabinet in a whole box, and the operation efficiency of the formation and grading cabinet for a single battery is effectively improved.

Drawings

FIG. 1 is a schematic view of a structure according to the present invention;

FIG. 2 is a schematic left side view of the present invention;

FIG. 3 is a schematic front view of the present invention;

fig. 4 is a schematic bottom view of the present invention.

In the figure: the battery box comprises a box body 1, a battery placing area 2, a battery groove baffle 3, reinforcing ribs 4, a carrying handle 5, a battery groove 6, a stacking groove 7, a groove 8 and a positioning groove 9.

Detailed Description

For a better understanding of the objects, structure and function of the utility model, reference should be made to the following detailed description taken in conjunction with the accompanying drawings.

As shown in fig. 1 to 4, the turnover box for lithium ion battery formation and capacity-sharing cabinet of the present invention mainly comprises: the battery box comprises a box body 1 with an upward opening for placing a cuboid battery and a battery placing area 2 arranged in the box body 1; the battery box comprises a box body 1, battery jar baffles 3, a plurality of battery jar baffles and a plurality of battery jar baffles, wherein the two rows of battery jar baffles 3 are vertically arranged in a cuboid inner cavity of the box body 1 along the length direction, and the box body 1 and the battery jar baffles 3 are integrally formed in an integral injection molding mode; every two liang of correspondences of every row of battery jar baffle 3 are a set of, form a battery between two corresponding battery jar baffles 3 of every group and place the district 2, lie in two battery jar baffles 3 of the left and right sides of outside and form battery between the left and right sides face of cuboid inner chamber respectively and place the district 2, and during the use battery utmost point post upwards places in the battery and places the district 2.

As shown in fig. 3, the case body 1 is a structure in which the stacking groove 7 and the battery groove 6 are integrally communicated with each other up and down, the upper surface of the battery groove 6 is open, the front surface, the upper surface and the lower surface of the stacking groove 7 are open, and a rectangular parallelepiped inner cavity for mounting the battery groove baffle 3 is formed in the battery groove 6. When the turnover boxes are stacked up and down, the battery groove 6 of the turnover box at the upper layer corresponds to and matches with the stacking groove 7 of the turnover box at the lower layer.

The battery placing area 2 is formed by distributing a plurality of cuboid grooves (16 in the embodiment) for placing batteries among the battery groove baffles 3 at certain intervals; district 2 is placed to two adjacent batteries, and the interval corresponds the interval of two adjacent probes on the formation partial volume cabinet, according to the interval between the formation partial volume cabinet probe point position, leaves 20mm space between two adjacent battery are placed district 2, makes the probe homoenergetic contact battery. Each battery well baffle 3 has a height of 70mm and a width of 10 mm.

The two sides of the box body 1 of the turnover box are both provided with carrying handles 5, and the bottom surfaces of the carrying handles 5 are provided with grooves 8 into which hands can extend. The turnover boxes can be stacked and placed, turnover is convenient and fast, stacking is tidy, and management is convenient. The bottom surface of the box body 1 is transversely provided with two positioning grooves 9 which are parallel relatively, the bottom surface of the box body 1 is uniformly and parallelly distributed with reinforcing ribs 4, the reinforcing ribs 4 are vertical to the positioning grooves 9, and when the turnover boxes are stacked, the reinforcing ribs 4 on the bottom surface of the upper turnover box are positioned between two adjacent battery placing areas 2 of the lower turnover box; the positioning groove 9 of the turnover box of the upper layer is positioned between the adjacent reinforcing ribs 4 and corresponds to the battery placing area 2 of the turnover box of the lower layer. Therefore, the turnover boxes can be safely and firmly stacked without toppling over.

The result shows that the turnover box for the lithium ion battery formation and capacity grading cabinet is convenient to place and take down on the battery formation and capacity grading cabinet, can shorten the time of loading and unloading batteries, saves the time cost of loading and unloading batteries, quickens the process progress of the batteries, increases the utilization rate of the capacity grading cabinet, saves energy, reduces consumption, reduces the labor intensity of workers, and improves the production efficiency more safely.

While the utility model has been described with reference to certain embodiments, it will be understood by those skilled in the art that various changes may be made and equivalents may be substituted for elements thereof without departing from the scope of the utility model. In addition, many modifications may be made to adapt a particular situation or material to the teachings of the utility model without departing from the essential scope thereof. Therefore, it is intended that the utility model not be limited to the particular embodiment disclosed, but that the utility model will include all embodiments falling within the scope of the appended claims.

Claims (9)

1. A tote box for a lithium ion battery dispensing cabinet, the tote box comprising: the battery box comprises a box body with an upward opening for placing a cuboid battery and a battery placing area arranged in the box body; the battery box comprises a box body, a plurality of battery jar baffles and a plurality of battery jar baffles, wherein the cuboid inner cavity of the box body is vertically provided with two vertical rows of battery jar baffles along the length direction, and the box body and the battery jar baffles are integrally formed in an integral injection molding mode; every two liang of correspondences of every row battery jar baffle form a set of, form a battery between two corresponding battery jar baffles of every group and place the district, lie in two battery jar baffles of the left and right sides of outside and cuboid inner chamber left and right sides face respectively and form the battery and place the district.

2. The turnover box for a lithium ion battery chemical component container according to claim 1, wherein the box body is a stacking groove, the battery groove is in an upper-lower integrated communication structure, the upper surface of the battery groove is opened, the front surface, the upper surface and the lower surface of the stacking groove are opened, and a cuboid inner cavity for installing a baffle plate of the battery groove is formed in the battery groove.

3. The transfer case for a lithium ion battery compartment cabinet according to claim 2, wherein the battery well of the transfer case of the previous layer corresponds to and matches the stacking well of the transfer case of the next layer when the transfer cases are stacked up and down.

4. The turnover box for a lithium ion battery compartment according to claim 1, wherein the battery receiving area is rectangular parallelepiped slots spaced apart between battery slot baffles for receiving batteries.

5. The turnover box for a lithium ion battery chemical composition container cabinet as claimed in claim 1, wherein the distance between two adjacent battery placing areas corresponds to the distance between two adjacent probes on the chemical composition container cabinet, and a 15-25 mm gap is left between two adjacent battery placing areas according to the distance between probe points of the chemical composition container cabinet.

6. The turnover box for a lithium ion battery compartment cabinet according to claim 1, wherein each battery compartment baffle has a height of 60 to 80mm and a width of 5 to 15 mm.

7. The transfer box for a lithium ion battery container as defined in claim 1, wherein the transfer box has carrying handles on both sides of the box body, and the carrying handles have bottom surfaces provided with grooves into which a hand can be inserted.

8. The turnover box for lithium ion battery formation container cabinet according to claim 1, wherein the bottom surface of the box body is transversely provided with two relatively parallel positioning grooves, the bottom surface of the box body is uniformly and parallelly provided with reinforcing ribs, the reinforcing ribs are perpendicular to the positioning grooves, and when the turnover boxes are stacked, the reinforcing ribs on the bottom surface of the upper turnover box are positioned between two adjacent battery placing areas of the next turnover box; the positioning groove of the turnover box at the upper layer is positioned between the adjacent reinforcing ribs and corresponds to the battery placing area of the turnover box at the lower layer.

9. The tote box for lithium ion battery cellularization volumetric bins of claim 1, wherein, in use, the battery poles are placed upward in the battery placement area.

Images