CN220518838U - Battery packaging tray, battery packaging box and battery pack - Google Patents

Abstract

The utility model discloses a battery packaging tray, a battery packaging box and a battery pack, wherein the battery packaging tray comprises a plurality of rectangular accommodating cavities, loading and unloading gaps are symmetrically formed in two opposite side walls of each accommodating cavity, first reinforcing ribs are arranged at the bottoms of the loading and unloading gaps, clearance gaps are formed in the other two side walls of each accommodating cavity, second reinforcing ribs are arranged at the bottoms of the clearance gaps, the battery packaging tray is an EPP structural member, and the battery packaging box comprises the battery packaging tray. The lithium battery pack can be used as a buffer package of the lithium battery pack to protect the lithium battery pack in the transportation process, and meanwhile, scraps are not easy to drop, so that the lithium battery pack can be kept relatively clean; in addition, the battery packaging tray can be used on a mechanical automatic packaging line, so that automatic packaging of the lithium battery pack can be realized, and the packaging efficiency of the lithium battery pack is improved.

Description

Battery packaging tray, battery packaging box and battery pack

Technical Field

The utility model relates to the field of battery transportation packaging, in particular to a battery packaging tray, a battery packaging box and a battery pack.

Background

With the arrival of new energy age, the application of lithium batteries is more and more extensive, and the packaging and transportation of lithium battery packs are particularly important. The lithium battery pack is easy to damage, squeeze and deform, even electrolyte leaks and the like in the transportation process, so that the loss of the lithium battery pack in the transportation process is seriously increased, and the production cost of the lithium battery pack is increased. To reduce this, lithium battery packs are typically buffer packed.

At present, the cushioning packaging in the common lithium battery pack transportation generally adopts corrugated board, EPS (polystyrene foam), EPE (pearl wool) and other materials. Corrugated board and EPS (polystyrene foam) materials are easy to fall off scraps and particles in the using process, so that the battery pack is not easy to keep clean. EPE (pearl wool) materials are often formed through viscose, the solidified overflowed viscose is easy to scrape the lithium battery pack, and most of buffer packaging of the EPE (pearl wool) materials is formed manually, so that the size precision cannot meet an automatic packaging line, and the EPE (pearl wool) materials can only be packaged manually, so that the packaging efficiency is low.

Disclosure of Invention

The utility model aims to solve the problem that a common buffer package in lithium battery package transportation cannot keep the battery package clean or cannot be applied to an automatic packaging line in the prior art, and provides a battery package tray, a battery package box and a battery package.

In order to achieve the above object, the present utility model provides the following technical solutions:

the utility model provides a battery package tray, includes the holding chamber of a plurality of rectangle, two relative lateral walls symmetry in holding chamber are provided with loading and unloading breach, loading and unloading breach bottom is provided with first strengthening rib, two other lateral walls in holding chamber are provided with keeps away a breach, it all is provided with the second strengthening rib to keep away a breach bottom, battery package tray is the EPP structure.

The utility model discloses a battery packaging tray, which comprises a plurality of containing cavities, wherein the containing cavities are used for containing battery packages, the containing cavities are rectangular, four right angles of the rectangle can be used as positioning references for automatic packaging and installation of the battery packages of a mechanical packaging line, two opposite side walls of the containing cavities are symmetrically provided with loading and unloading gaps, the loading and unloading gaps can meet the requirement that manipulator clamps on the mechanical packaging line are opened, the bottom of the loading and unloading gaps is provided with first reinforcing ribs, the other two side walls of the containing cavities are provided with position avoiding gaps, the position avoiding gaps provide position avoiding for a protruding structure of the battery packages and simultaneously help to fix the battery packages, the bottom of the position avoiding gaps is provided with second reinforcing ribs, the first reinforcing ribs and the second reinforcing ribs can help the containing cavities maintain the shape, the risk that the positioning references are influenced due to deformation of the containing cavities during packaging and installation of the battery packages is reduced, the battery packaging tray is an EPP (expanded polypropylene) structural member, the EPP material is not easy to fall down, relative cleaning of the battery packages is facilitated, and the EPP structural member can meet the requirement of automatic packaging line processing precision through the machine. The battery packaging tray can be used as buffer packaging of the lithium battery pack to protect the lithium battery pack in the transportation process, and meanwhile, scraps are not easy to fall off, so that the lithium battery pack can be kept relatively clean; in addition, the battery packaging tray can be used on a mechanical automatic packaging line, so that automatic packaging of the lithium battery pack can be realized, and the packaging efficiency of the lithium battery pack is improved.

As a preferable scheme of the utility model, the top surface and the bottom surface of the battery packaging tray are respectively and correspondingly provided with a splicing limiting structure, and the adjacent battery packaging trays can be stacked up and down through the splicing limiting structures, and the splicing limiting structures comprise splicing bosses and splicing grooves which are mutually matched. The splicing limiting structure can splice and lock, so that the stacking of the trays is more stable, and meanwhile, the space utilization rate can be improved; the splicing boss is buckled with the splicing groove, and the adjacent battery packaging trays can be stacked up and down stably.

As a preferable mode of the utility model, the battery packaging tray is an integral injection molding member. The first reinforcing ribs, the second reinforcing ribs and the splicing limiting structures are integrally formed with the body of the battery packaging tray, so that the glue overflow problem caused by glue forming of each component can be avoided, and the risk of scraping the buffer packaging of the lithium battery pack is reduced.

As the preferable scheme of the utility model, the splicing lug boss is arranged on the top surface of the battery packaging tray, and the splicing groove is correspondingly arranged on the bottom surface of the battery packaging tray, so that the stacking limit of the battery packaging tray can be better realized.

As a preferable scheme of the utility model, the splicing lug boss comprises an angular lug boss and a middle lug boss, wherein the angular lug boss is positioned at four corners of the battery packaging tray, the middle lug boss is positioned between two adjacent angular lug bosses, the splicing groove comprises an angular groove and a middle groove, the angular groove is positioned at four corners of the battery packaging tray, the middle groove is positioned between two adjacent angular grooves, the angular lug boss is matched with the angular groove, and the middle lug boss is matched with the middle groove. The arrangement of the splicing bosses and the splicing grooves can better realize the stacking limit of the battery packaging tray; in addition, the middle boss can also reduce the shrinkage deformation of the battery packaging tray after cooling and shaping.

As the preferable scheme of the utility model, the angle lug boss comprises an L-shaped lug boss, so that the stacking limit of the battery packaging tray can be better realized, and the stability of the battery pack in the transportation process is improved.

As a preferred embodiment of the present utility model, adjacent receiving chambers share one side wall. The usable area of the battery packaging tray is limited, and the adjacent accommodating cavities share one side wall, so that the battery packaging tray can accommodate more accommodating cavities in a limited area; but also can save materials, is convenient for processing and reduces the manufacturing cost.

As a preferable scheme of the utility model, the wall thickness range of the accommodating cavity is as follows: 30-45mm. Preferably, the wall thickness of the accommodating cavity may be 30mm, 35mm, 40mm, 45mm, etc. When the wall thickness of the accommodating cavity is larger than or equal to 30mm, the accommodating cavity can not only provide enough buffer for the battery pack and protect the battery during transportation, but also keep a rectangular shape when the battery pack is not installed; when the wall thickness of the accommodating cavity is smaller than or equal to 45mm, the buffer package of the battery pack is not bulked.

As a preferable mode of the utility model, the height of the accommodating cavity is 2-8mm higher than the height of the battery pack. Preferably, the height of the receiving chamber may be 2mm, 3mm, 4mm, 5mm, 6mm, 7mm, 8mm, etc. higher than the height of the battery pack. When the height of the accommodating cavity is 2-8mm higher than that of the battery pack, the battery pack in the accommodating cavity of the lower tray can be prevented from contacting with the bottom surface of the upper tray after the adjacent battery pack trays are stacked, and the risk of damaging the battery pack is reduced; meanwhile, the possibility of large deformation of the accommodating cavity of the lower tray is reduced, and the stability of a plurality of stacked battery packaging trays in transportation is ensured.

The utility model also discloses a battery packaging box which comprises any battery packaging tray.

The battery packaging box comprises any battery packaging tray, can improve the stability of the battery pack in the accommodating cavity, realize effective protection of the battery pack, reduce risks of problems such as bruise, extrusion deformation and the like of the battery pack in the transportation process, reduce the loss of the battery pack in the transportation process and reduce the cost; meanwhile, the stability of the battery pack in the transportation process is improved by means of the splicing limiting structure of the battery packaging tray, and the space utilization rate in the battery packaging box body is higher, so that more batteries are transported.

The utility model also discloses a battery pack which is packaged by using any battery packaging tray.

The battery pack is packaged by using any battery packaging tray, the stability of the battery pack in the accommodating cavity is effectively improved, the battery pack is effectively protected, the risks of damaging, extruding and deforming and other problems in the transportation process of the battery pack are reduced, the loss of the battery pack in the transportation process can be reduced, and the cost is reduced.

Compared with the prior art, the utility model has the beneficial effects that:

1. the battery packaging tray can be used as buffer packaging of the lithium battery pack to protect the lithium battery pack in the transportation process, and meanwhile, scraps are not easy to fall off, so that the lithium battery pack can be kept relatively clean; in addition, the battery packaging tray can be used on a mechanical automatic packaging line, so that automatic packaging of the lithium battery pack can be realized, and the packaging efficiency of the lithium battery pack is improved.

2. In a preferred scheme, the battery packaging tray can realize stable stacking by means of the splicing limiting structure, so that the stability of a battery pack in the transportation process is improved; meanwhile, the splicing limiting structure can also reduce the shrinkage deformation of the battery packaging tray after cooling and shaping, and the tray can keep the shape and the size which meet the requirements of a mechanical automatic packaging line.

3. The battery packaging box can improve the stability of the battery pack in the accommodating cavity, effectively protect the battery pack, reduce risks of problems such as bruise and extrusion deformation of the battery pack in the transportation process, reduce the loss of the battery pack in the transportation process and reduce the cost; meanwhile, the stability of the battery pack in the transportation process is improved by means of the splicing limiting structure of the battery packaging tray, and the space utilization rate in the battery packaging box body is higher, so that more batteries are transported.

4. According to the battery pack, the stability of the battery pack in the accommodating cavity is effectively improved, the battery pack is effectively protected, risks of damage, extrusion deformation and other problems of the battery pack in the transportation process are reduced, the loss of the battery pack in the transportation process can be reduced, and the cost is reduced.

Drawings

Fig. 1 is a three-dimensional view of a battery packaging tray of the present utility model;

fig. 2 is a front view of a battery packaging tray of the present utility model;

FIG. 3 is a top view of a battery packaging tray of the present utility model;

fig. 4 is a side view of a battery packaging tray of the present utility model;

fig. 5 is a bottom view of a battery packaging tray of the present utility model.

Reference numerals in the drawings: 1-holding cavity, 2-loading and unloading breach, 3-first strengthening rib, 4-keep away a breach, 5-second strengthening rib, 6-concatenation boss, 61-angular position boss, 62-middle part boss, 7-concatenation recess, 71-angular position recess, 72-middle part recess, 8-tray bottom plate.

Detailed Description

The present utility model will be described in further detail with reference to test examples and specific embodiments. It should not be construed that the scope of the above subject matter of the present utility model is limited to the following embodiments, and all techniques realized based on the present utility model are within the scope of the present utility model.

Example 1

As shown in fig. 1-5, a battery packaging tray comprises a plurality of rectangular accommodating cavities 1, loading and unloading gaps 2 are symmetrically formed in two opposite side walls of each accommodating cavity 1, first reinforcing ribs 3 are arranged at the bottoms of the loading and unloading gaps 2, position avoidance gaps 4 are formed in the other two side walls of each accommodating cavity 1, second reinforcing ribs 5 are arranged at the bottoms of the position avoidance gaps 4, and the battery packaging tray is an EPP structural member.

The utility model discloses a battery packaging tray, which comprises a plurality of accommodating cavities 1, wherein the accommodating cavities 1 are used for accommodating battery packages, the accommodating cavities 1 are rectangular, four right angles of the rectangle can be used as positioning references for automatically packaging and installing the battery packages of a mechanical packaging line, namely positioning points for visual photographing, two opposite side walls of the accommodating cavities 1 are symmetrically provided with loading and unloading notches 2, the loading and unloading notches 2 can meet the requirement that a manipulator clamp on the mechanical packaging line is opened, the manipulator clamp is convenient for clamping and placing the battery packages, the bottoms of the loading and unloading notches 2 are provided with first reinforcing ribs 3, the other two side walls of the accommodating cavities 1 are provided with position avoiding notches 4, the position avoiding notches 4 provide position avoiding for protruding structures (such as positive lugs, negative lugs and the like of the battery packages), meanwhile, the battery packages can be fixed by limiting the protruding structures, the bottoms of the position avoiding notches 4 are provided with second reinforcing ribs 5, the first reinforcing ribs 3 and the second reinforcing ribs 5 can help the accommodating cavities 1 maintain the shape, and reduce the falling down of the battery packages, the EPP (EPP) can not meet the requirements on the positioning precision of a packaging line, and the EPP (EPP packaging tray can not meet the requirements on the appearance of a packaging material, and the packaging accuracy of a packaging tray can be kept by the machine, and the battery packaging tray can be cleaned, and the packaging accuracy can not meet the requirements, and the requirements can be met by relative to the requirements.

As will be appreciated by those skilled in the art, the location and size of the loading gap 2 need to be determined according to the manipulator clamps of a particular automated packaging line; the position and the size of the clearance notch 4 need to be determined according to the protruding structure of the specific battery pack.

It will be appreciated by those skilled in the art that the first reinforcing ribs 3 and the second reinforcing ribs 5 respectively enable the loading and unloading notch 2 and the avoidance notch 4 not to penetrate through the side wall of the accommodating cavity 1 from the top surface to the bottom surface, and the first reinforcing ribs 3 and the second reinforcing ribs 5 can help the accommodating cavity 1 maintain the shape, so that the risk that the accommodating cavity 1 deforms to affect positioning reference when the battery pack is packaged and installed is reduced. Typically, the first reinforcing ribs 3 and the second reinforcing ribs 5 are bar-shaped members.

It can be understood by those skilled in the art that when the machining error of the length and the width of the accommodating cavity 1 is +3mm, the battery packaging tray can meet the precision requirement of an automatic wire bonding, thereby being beneficial to automatic packaging of lithium battery packs and improving packaging efficiency.

The battery packaging tray can be used as buffer packaging of the lithium battery pack to protect the lithium battery pack in the transportation process, and meanwhile, scraps are not easy to fall off, so that the lithium battery pack can be kept relatively clean; in addition, the battery packaging tray can be used on a mechanical automatic packaging line, so that automatic packaging of the lithium battery pack can be realized, and the packaging efficiency of the lithium battery pack is improved.

Example 2

As shown in fig. 1-5, on the basis of embodiment 1, the present embodiment is further optimally designed, specifically, in this embodiment, the battery packaging tray includes 10 the accommodating cavity 1, the shape of the accommodating cavity 1 is rectangular, 10 the accommodating cavity 1 is divided into two rows, each row has 5 the accommodating cavity, the loading and unloading notch 2 is symmetrically opened on two long side walls of the accommodating cavity 1, the avoidance notch 4 is opened on two short side walls of the accommodating cavity 1, the top surface and the bottom surface of the battery packaging tray are respectively provided with a splicing limiting structure, and the adjacent battery packaging trays can be stacked up and down through the splicing limiting structure, and the splicing limiting structure can splice and lock for the stacking of the trays is more stable, and the space utilization rate can also be improved.

Further, battery package tray is an integral injection moulding component, first strengthening rib 3 second strengthening rib 5 reaches concatenation limit structure all with battery package tray's body integrated into one piece can avoid each component to pass through the glue problem that glue shaping arouses, and then reduces the lithium cell package and is scraped the risk of flower by buffer package.

Further, the splicing limiting structure comprises a splicing boss 6 and a splicing groove 7 which are mutually matched. The splicing boss 6 is buckled with the splicing groove 7, and the adjacent battery packaging trays can be stacked up and down stably.

Further, the splicing boss 6 is disposed on the top surface of the battery packaging tray, and the splicing groove 7 is correspondingly disposed on the bottom surface of the battery packaging tray. The stacking limit of the battery packaging tray can be better realized.

It can be understood by those skilled in the art that the splice boss 6 and the splice groove 7 only need to be spliced to realize that the battery package tray is stably stacked, and as an alternative scheme, the splice boss 6 is arranged on the tray bottom plate 8 of the battery package tray, and the splice groove 7 is correspondingly arranged on the top surface of the battery package tray, or, the top surface of the battery package tray is provided with the splice boss 6 and the splice groove 7, and the tray bottom plate 8 is correspondingly arranged with the splice groove 7 and the splice boss 6.

Further, the splicing boss 6 includes an angular boss 61 and a middle boss 62, the angular boss 61 is located at four corners of the battery packaging tray, the middle boss 62 is located between two adjacent angular bosses 61, the splicing groove 7 includes an angular groove 71 and a middle groove 72, the angular groove 71 is located at four corners of the battery packaging tray, the middle groove 72 is located between two adjacent angular grooves 71, the angular boss 61 is adapted to the angular groove 71, and the middle boss 62 is adapted to the middle groove 72. The arrangement of the splicing boss 6 and the splicing groove 7 can better realize the stacking limit of the battery packaging tray; in addition, the middle boss 62 can also reduce the shrinkage deformation of the battery packaging tray after cooling and shaping. Specifically, in this embodiment, the battery packaging tray includes 4 angular bosses 61,2 and two middle bosses 62, and the middle bosses 62 are long and straight.

Further, the angular boss 61 includes an L-shaped boss, compared with other shapes, the angular boss 61 is an L-shaped boss, which can better realize stacking limit of the battery packaging tray, and improve stability of the battery pack in the transportation process. Specifically, in this embodiment, there are 4 angular bosses 61, and since the clearance gap 4 on one side of the accommodating cavity is formed at one corner, 2 angular bosses 61 located at two non-adjacent corners of the battery packaging tray are L-shaped bosses, and the other 2 angular bosses 61 are short linear bosses.

Further, adjacent accommodating chambers 1 share a side wall. The usable area of the battery packaging tray is limited, and the adjacent accommodating cavities 1 share one side wall, so that the battery packaging tray can accommodate more accommodating cavities 1 in a limited area; but also can save materials, is convenient for processing and reduces the manufacturing cost.

Further, the wall thickness range of the accommodating cavity 1 is as follows: 30-45mm. Preferably, the wall thickness of the accommodating cavity 1 may be 30mm, 35mm, 40mm, 45mm, etc. When the wall thickness of the accommodating cavity 1 is larger than or equal to 30mm, the battery pack can be sufficiently buffered, the battery can be protected during transportation, and the rectangular shape can be maintained when the battery pack is not installed; when the wall thickness of the accommodating cavity 1 is smaller than or equal to 45mm, the buffer package of the battery pack is not bulked. Specifically, in this embodiment, the wall thickness of the accommodating cavity 1 is 30mm. It will be appreciated by those skilled in the art that the wall thickness of the receiving chamber 1 may be any value within 30-45mm.

Further, the height of the accommodating cavity 1 is 2-8mm higher than that of the battery pack. Preferably, the height of the receiving chamber 1 may be 2mm, 3mm, 4mm, 5mm, 6mm, 7mm, 8mm, etc. higher than the height of the battery pack. When the height of the accommodating cavity 1 is 2-8mm higher than that of the battery pack, the battery pack in the accommodating cavity 1 of the lower tray can be prevented from contacting with the bottom surface of the upper tray after the adjacent battery pack trays are stacked, and the risk of damaging the battery pack is reduced; meanwhile, the possibility of large deformation of the accommodating cavity 1 of the lower tray is reduced, and the stability of a plurality of stacked battery packaging trays in transportation is ensured. Specifically, in this embodiment, the height of the accommodating cavity 1 is 5mm higher than the height of the battery pack. It will be appreciated by those skilled in the art that the height of the receiving chamber 1 may be any value within 2-8mm higher than the height of the battery pack.

Example 3

The battery packaging box comprises a box body, wherein the top of the box body is provided with an upper cover, the bottom of the box body is provided with a lower cover, the upper cover and the lower cover are connected with the box body through packing belts, and the battery packaging box further comprises any battery packaging tray provided by the utility model, and the top of the lower cover is provided with a splicing structure corresponding to the splicing limiting structure on the bottom surface of the battery packaging tray.

The battery packaging box comprises any battery packaging tray, can improve the stability of a battery pack in the accommodating cavity 1, realize effective protection of the battery pack, reduce risks of damage, extrusion deformation and other problems of the battery pack in the transportation process, reduce the loss of the battery pack in the transportation process and reduce the cost; meanwhile, the stability of the battery pack in the transportation process is improved by means of the splicing limiting structure of the battery packaging tray, and the space utilization rate in the battery packaging box body can be higher, so that more batteries can be transported

The foregoing description of the preferred embodiments of the utility model is not intended to limit the utility model to the particular embodiments disclosed, but on the contrary, the intention is to cover all modifications, equivalents, and alternatives falling within the spirit and scope of the utility model.

Claims (10)

1. The utility model provides a battery packaging tray, its characterized in that includes holding chamber (1) of a plurality of rectangle, two relative lateral walls symmetry in holding chamber (1) are provided with loading and unloading breach (2), loading and unloading breach (2) bottom is provided with first strengthening rib (3), two other lateral walls in holding chamber (1) are provided with keeps away position breach (4), keep away position breach (4) bottom all is provided with second strengthening rib (5), battery packaging tray is EPP structure.

2. The battery packaging tray according to claim 1, wherein the top surface and the bottom surface of the battery packaging tray are respectively provided with a splicing limiting structure in a corresponding manner, adjacent battery packaging trays can be stacked up and down through the splicing limiting structures, and the splicing limiting structures comprise splicing bosses (6) and splicing grooves (7) which are mutually matched.

3. The battery packaging tray of claim 2, wherein the battery packaging tray is a one-piece injection molded component.

4. A battery packaging tray according to claim 3, characterized in that the splicing boss (6) is provided on the top surface of the battery packaging tray, and the splicing groove (7) is provided on the bottom surface of the battery packaging tray.

5. A battery package tray according to claim 3, characterized in that the splice boss (6) comprises an angular boss (61) and a middle boss (62), the angular boss (61) is located at four corners of the battery package tray, the middle boss (62) is located between two adjacent angular bosses (61), the splice groove (7) comprises an angular groove (71) and a middle groove (72), the angular groove (71) is located at four corners of the battery package tray, the middle groove (72) is located between two adjacent angular grooves (71), the angular boss (61) is adapted to the angular groove (71), and the middle boss (62) is adapted to the middle groove (72).

6. The battery packaging tray of claim 5, wherein the angular boss (61) comprises an L-shaped boss.

7. Battery packaging tray according to claim 1, characterized in that adjacent receiving cavities (1) share one side wall.

8. The battery packaging tray according to claim 1, characterized in that the wall thickness of the receiving cavity (1) ranges from: 30-45mm, the height of the accommodating cavity (1) is 2-8mm higher than the height of the battery pack.

9. A battery packaging case comprising the battery packaging tray according to any one of claims 1 to 8.

10. A battery pack, characterized in that it is packaged using the battery packaging tray according to any one of claims 1 to 8.