BATTERY BOX

Abstract

This application provides a battery box, which includes: a heat exchange plate and a lower frame body located on the heat exchange plate. The lower frame body includes edge beams and internal beams, the edge beams forming a circumferential closure opened in an up-down direction, the edge beams and the heat exchange plate together forming an accommodating space with an upward opening, and the internal beams located inside the accommodating space and divide the accommodating space into sub-accommodating spaces for placing battery modules. The heat exchange plate is configured to support the battery modules and exchanges heat with batteries of the battery modules, and a bottom plane of an internal beam is partly in contact with a top plane of the heat exchange plate in the up-down direction.

Description

TECHNICAL FIELD

This application relates to the battery field, and in particular, to a battery box.

BACKGROUND

In the battery field, a battery box includes a lower frame body and a heat exchange plate. The lower framer body and the heat exchange plate form an accommodating space for accommodating a battery module. The lower housing includes a plurality of beams. The battery module includes a plurality of arranged batteries and is supported on the heat exchange plate. The heat exchange plate supports the batteries and exchanges heat with the batteries.

A battery generally needs to stay at a constant temperature range to ensure stability and constancy of the operating temperature of the battery.

However, because the heat exchange plate is fixed to the beams of the lower frame body, the entire bottom planes of the beams are in contact with the heat exchange plate. Therefore, there is heat transfer between the heat exchange plate and the beams of the lower frame body, which affects the heat exchange effect of the heat exchange plate on the batteries and the stability and constancy of the operating temperature of the battery.

SUMMARY

In view of the problem existing in the prior art, an objective of this application is to provide a battery box, which can reduce heat exchange between a heat exchange plate and bottom planes of internal beams.

In order to achieve the above object, this application provides a battery box, which includes: a heat exchange plate; a lower frame body located on the heat exchange plate, where the lower frame body includes edge beams and internal beams, the edge beams form a circumferential closure opened in an up-down direction, the edge beams and the heat exchange plate together form an accommodating space with an upward opening, and the internal beams are located inside the accommodating space and divide the accommodating space into sub-accommodating spaces for placing battery modules; the heat exchange plate is used to support the battery modules and exchanges heat with batteries of the battery modules, and a bottom plane of an internal beam is partly in contact with a top plane of the heat exchange plate in the up-down direction.

In an embodiment, the bottom plane of the internal beam includes: a first plane, which is in contact with the top plane of the heat exchange plate; and a second plane, which is recessed upwardly with respect to the first plane from a side of the first plane in a direction that intersects with the up-down direction, so that the second plane is spaced apart from the top plane of the heat exchange plate in the up-down direction.

In an embodiment, the battery box further includes heat insulation glue, the heat insulation glue being filled between the second plane of the bottom plane of the internal beam and the top plane of the heat exchange plate.

In an embodiment, the bottom plane of the internal beam further includes a third plane, which is recessed upwardly with respect to the first plane from another side of the first plane opposite to the direction that intersects with the up-down direction, so that the third plane is spaced apart from the top plane of the heat exchange plate in the up-down direction.

In an embodiment, the battery box further includes heat insulation glue, which is filled between the third plane and the top plane of the heat exchange plate.

In an embodiment, the top plane of the heat exchange plate is flat in general.

In an embodiment, the heat exchange plate has a main body and a bulge extending from the main body. A downside of the bulge is recessed upwardly with respect to the main body, and an upside of the bulge protrudes upwardly with respect to the main body. The bulge has a top surface constituting part of the top plane and an inclined plane. The inclined plane is located laterally to the top surface along the direction intersecting with the up-down direction. The bottom plane of the internal beam is partly in contact with the top surface of the bulge, and the inclined plane of the bulge is spaced apart from the top plane of the heat exchange plate in the up-down direction.

In an embodiment, the battery box further includes heat insulation glue, which is filled between the bottom plane of the internal beam and the inclined plane of the bulge.

In an embodiment, a notch is provided on a lateral surface of the internal beam facing toward the battery.

In an embodiment, the internal beam has an accommodating cavity located above a location where the bottom plane of the internal beam contacts the top plane of the heat exchange plate. The battery box further includes a fastener which passes through the heat exchange plate and the internal beam at the location where the bottom plane of the internal beam contacts the top plane of the heat exchange plate and extends into the accommodating cavity. A part of the fastener extending into the accommodating cavity is spaced apart from a wall of the accommodating cavity.

The beneficial effects of this application are as follows: by making the bottom plane of the internal beam partly in contact with the top plane of the heat exchange plate in the up-down direction, the contact area between the bottom plane of the internal beam and the top plane of the heat exchange plate is reduced. This reduces the heat exchange between the heat exchange plate and the bottom plane of the internal beam, and in turn the impact on the heat exchange between the heat exchange plate and the battery modules (mainly the batteries) is reduced, and the stability, constancy and controllability of the operating temperature of the batteries are improved.

BRIEF DESCRIPTION OF DRAWINGS

FIG. 1 is a perspective view of a battery box according to this application, where battery modules are shown for the sake of clarity;

FIG. 2 is a perspective view of assembly of the battery box according to this application;

FIG. 3 is a vertical view of FIG. 2;

FIG. 4 is a sectional view of FIG. 3;

FIG. 5 is an enlarged view of a circled part in FIG. 4;

FIG. 6 is a variation of FIG. 5;

FIG. 7 is another view corresponding to FIG. 5, showing another internal beam of a lower frame body of the battery box according to this application; and

FIG. 8 is a variation of FIG. 7.

Reference signs are described as follows:

X. left-right direction
Y. forward-back direction
Z. up-down direction
1. heat exchange plate
T11. top plane
12. main body
121. upper surface
13. bulge
131. top surface
132. inclined plane
14. first plate
15. second plate
F. flow passage
2. lower frame body
21. edge beam
22. internal beam
B22. bottom plane
B221. first plane
B222. second plane
B223. third plane
224. lateral surface
224a. notch
225. accommodating cavity
R. sub-accommodating space
3. heat insulation glue
4. fastener
5. heat insulation pad
6. protective plate
7. battery module
71. battery

DESCRIPTION OF EMBODIMENTS

The accompanying drawings illustrate embodiments of this application and it is understood that the disclosed embodiments are merely examples of this application, which may be implemented in various forms. Therefore, specific details disclosed herein are not to be interpreted as limiting, but merely as a basis for the claims and as a representative basis for teaching one skilled in the art to implement this application in various ways.

Additionally, expressions such as up, down, left, right, front, and back that are used to indicate directions for the operations and construction of the constituent components in the embodiments are not absolute but rather relative. Such indications are appropriate when these components are in the locations illustrated in the drawings; however, these directions should be interpreted differently when these locations change, in order to correspond to the changes.

FIG. 1 is a perspective view of a battery box according to this application, where battery modules are shown for the sake of clarity. FIG. 2 is an assembled perspective view of the battery box according to this application. FIG. 3 is a top view of FIG. 2. FIG. 4 is a sectional view of FIG. 3. FIG. 5 is an enlarged view of a circled part in FIG. 4. FIG. 6 is a variation of FIG. 5. FIG. 7 is another view corresponding to FIG. 5, showing another internal beam of a lower frame body of the battery box according to this application. FIG. 8 is a variation of FIG. 7.

The battery box according to this application includes a heat exchange plate 1 and a lower frame body 2. The battery box further includes heat insulation glue 3. The battery box further includes a fastener 4, a heat insulation pad 5, and a protective plate 6.

The heat exchange plate 1 is used to support battery modules 7 and exchanges heat with batteries 71 of the battery modules 7. The battery 71 may generally include a housing and an electrode assembly and an electrolyte that are accommodated inside the housing. The electrode assembly includes a positive electrode plate, a negative electrode plate, and a separator. The battery 71 may be a can-type (or hard-case) battery, and accordingly as shown in FIG. 1, and the housing includes a top cover and an outer case fitted with the top cover; or the battery 71 may be a pouch-type (or soft-case) battery, and the case is made of a packaging film (such as an aluminum plastic film). The heat exchange plate 1 includes a first plate 14 and a second plate 15. The second plate 15 joins from below with the first plate 14 to form a flow passage F for a heat exchange medium to flow through, as shown in FIG. 5 and FIG. 6. The first plate 14 and/or the second plate 15 may be formed by stamping. To improve the heat exchange effect, the heat exchange plate 1 is made of a material having high thermal conductivity, preferably a metal material, and more preferably an aluminum alloy material.

The lower frame body 2 is located on the heat exchange plate 1. The lower frame body 2 includes edge beams 21 and internal beams 22. The edge beams 21 form a circumferential closure opened in an up-down direction Z, and the edge beams 21 and the heat exchange plate 1 together form an accommodating space with an upward opening. The internal beams 22 are located inside the accommodating space and divide the accommodating space into sub-accommodating spaces R for placing the battery modules 7, and a bottom plane B22 of the internal beam 22 is partly in contact with a top plane T11 of the heat exchange plate 1 in the up-down direction Z. By making the bottom plane B22 of the internal beam 22 partly in contact with the top plane T11 of the heat exchange plate 1 in the up-down direction Z, the contact area between the bottom plane B22 of the internal beam 22 and the top plane T11 of the heat exchange plate 1 is reduced. This reduces the heat exchange between the heat exchange plate 1 and the bottom plane B22 of the internal beam 22, and in turn the impact on the heat exchange between the heat exchange plate 1 and the battery modules 7 (mainly the batteries 71) is reduced, and the stability, constancy and controllability of the operating temperature of the batteries 71 are improved.

Both the edge beams 21 and the internal beams 22 can be made of a metal material, such as an aluminum alloy, and may use die castings or extrusion profiles. To reduce weight, the edge beams 21 and the internal beams 22 can have cavities (that is, a later described accommodating cavity 225 is present in the internal beam 22, but no cavity is shown for the edge beam 21). In a word, they are profiles with cavities. It is to be noted that, the respective longitudinal directions of the edge beams 21 and the internal beams 22 may be an X direction and their respective transverse directions may be a Y direction, or the longitudinal direction may be a Y direction and the transverse direction may be an X direction. However, in this specification, the transverse direction and the longitudinal direction are directions of a beam structure itself, which constitute a local coordinate system, while the X, Y, and Z directions of the battery box in FIG. 1 form a global coordinate system. There is no strict correspondence between the two coordinate systems.

In an example in FIG. 5, the bottom plane B22 of the internal beam 22 includes: a first plane B221, which is in contact with the top plane T11 of the heat exchange plate 1; a second plane B222, which is recessed upwardly with respect to the first plane B221 from a side of the first plane B221 in a direction that intersects with the up-down direction Z, so that the second plane B222 is spaced apart from the top plane T11 of the heat exchange plate 1 in the up-down direction Z.

Further, in the example in FIG. 5, the heat insulation glue 3 is filled between the second plane B222 of the bottom plane B22 of the internal beam 22 and the top plane T11 of the heat exchange plate. The filling of the heat insulation glue 3 may fill seamlessly a gap between the second plane B222 of the bottom plane B22 of the internal beam 22 and the top plane T11 of the heat exchange plate 1. This prevents heat from transferring to the second plane B222 of the bottom plane B22 of the internal beam 22 through the air by means of heat radiation from the top plane T11 of the heat exchange plate 1. This further reduces the heat exchange between the heat exchange plate 1 and the internal beam 22, and in turn the impact on the heat exchange between the heat exchange plate 1 and the battery modules 7 (mainly the batteries 71) is further reduced, and the stability, constancy and controllability of the operating temperature of the batteries 71 are further improved.

In an example in FIG. 6, on the basis of the embodiment shown in FIG. 5, the bottom plane B22 of the internal beam 22 further includes a third plane B223, which is recessed upwardly with respect to the first plane B221 from another side of the first plane B221 opposite to the direction that intersects with the up-down direction Z, so that the third plane B223 is spaced apart from the top plane T11 of the heat exchange plate 1 in the up-down direction Z. By making the third plane B223 spaced apart from the top plane T11 of the heat exchange plate 1 in the up-down direction Z, the contact area between the bottom plane B22 of the internal beam 22 and the top plane T11 of the heat exchange plate 1 is further reduced. This further reduces the heat exchange between the top plane T11 of the heat exchange plate 1 and the bottom plane B22 of the internal beam 22, and in turn the impact on the heat exchange between the heat exchange plate 1 and the battery modules 7 (mainly the batteries 71) is further reduced, and the stability, constancy and controllability of the operating temperature of the batteries 71 are further improved.

Further, in the example shown in FIG. 6, the heat insulation glue 3 is filled between the third plane B223 and the top plane T11 of the heat exchange plate 1. Again, the filling of the heat insulation glue 3 may fill seamlessly a gap between the third plane B223 of the bottom plane B22 of the internal beam 22 and the top plane T11 of the heat exchange plate 1. This prevents heat from transferring to the third plane B223 of the bottom plane B22 of the internal beam 22 through the air by means of heat radiation from the top plane T11 of the heat exchange plate 1. This further reduces the heat exchange between the heat exchange plate 1 and the internal beam 22, and in turn the impact on the heat exchange between the heat exchange plate 1 and the battery modules 7 (mainly the batteries 71) is further reduced, and the stability, constancy and controllability of the operating temperature of the batteries 71 are further improved.

In the examples in FIG. 5 and FIG. 6, the top plane T11 of the heat exchange plate 1 is flat in general. This improves the flatness for heat exchange with the batteries 71 of the battery modules 7, thereby improving the uniformity of heat exchange. The second plane B222 and the third plane B223 may form a ring, or may not form a ring, which may be dependent on the control of heat exchange.

In examples in FIG. 7 and FIG. 8, the heat exchange plate 1 has a main body 12 and a bulge 13 extending from the main body 12. A downside of the bulge 13 is recessed upwardly with respect to the main body 12, and an upside of the bulge 13 protrudes upwardly with respect to the main body 12. The bulge 13 has a top surface 131 constituting part of the top plane T11 and an inclined plane 132. The inclined plane 132 is located laterally to the top surface 131 along the direction intersecting with the up-down direction Z. The bottom plane B22 of the internal beam 22 is partly in contact with the top surface 131 of the bulge 13, and the inclined plane 132 of the bulge 13 is spaced apart from the top plane T11 of the heat exchange plate 1 in the up-down direction Z. By making the bottom plane B22 of the internal beam 22 partly in contact with the top surface 131 of the bulge 13, and the inclined plane 132 of the bulge 13 spaced apart from the top plane T11 of the heat exchange plate 1 in the up-down direction Z, the contact area between the bottom plane B22 of the internal beam 22 and the top plane T11 of the heat exchange plate 1 is reduced. This reduces the heat exchange between the heat exchange plate and the bottom plane of the internal beam, and in turn the impact on the heat exchange between the heat exchange plate and the battery modules (mainly the batteries) is reduced, and the stability, constancy and controllability of the operating temperature of the batteries are improved. Moreover, the provision of the bulge 13 also helps to strengthen the performance of the internal beam 22 to buffer against outside shocks.

Further, in the examples in FIG. 7 and FIG. 8, the heat insulation glue 3 is filled between the bottom plane B22 of the internal beam 22 and the inclined plane 132 of the bulge 13. Again, the filling of the heat insulation glue 3 may fill seamlessly a gap between the bottom plane B22 of the internal beam 22 and the inclined plane 132 of the bulge 13. This prevents heat from transferring to the bottom plane B22 of the internal beam 22 through the air by means of heat radiation from the inclined plane 132 of the bulge 13 of the heat exchange plate 1. This further reduces the heat exchange between the heat exchange plate 1 and the internal beam 22, and in turn the impact on the heat exchange between the heat exchange plate 1 and the battery modules 7 (mainly the batteries 71) is further reduced, and the stability, constancy and controllability of the operating temperature of the batteries 71 are further improved.

In the example in FIG. 7, the bottom plane B22 of the internal beam 22 is similar to that in FIG. 6; in the example in FIG. 8, the bottom plane B22 of the internal beam 22 is flat.

In the examples in FIG. 7 and FIG. 8, a notch 224a is provided on a lateral surface 224 of the internal beam 22 facing toward the battery. The provision of the notch 224a can reduce the contact area of the lateral surface of the battery module 7 with the internal beam 22 in case of impact vibration, reducing the level of unexpected heat exchange. Moreover, the notch 224a may also reduce the weight of the internal beam 22, helping the weight reduction of the battery box.

In the examples in FIG. 5 to FIG. 8, the internal beam 22 has an accommodating cavity 225 located above a location where the bottom plane B22 of the internal beam 22 contacts the top plane T11 of the heat exchange plate 1. A fastener 4 passes through the heat exchange plate 1 and the internal beam 22 at the location where the bottom plane B22 of the internal beam 22 contacts the top plane T11 of the heat exchange plate 1 and extends into the accommodating cavity 225. A part of the fastener 4 extending into the accommodating cavity 225 is spaced apart from a wall of the accommodating cavity 225. In this way, the part of the fastener 4 extending into the accommodating cavity 225 is prevented from coming into contact with the wall of the accommodating cavity 225, so the heat exchange area between the internal beam 22 and the heat exchange plate 1 will not increase because of the fastener 4.

A material of the heat insulation glue 3 may be selected from any suitable materials, such as polyurethane heat insulation glue and heat insulation epoxy glue.

The fastener 4 is configured to fix the heat exchange plate 1 to the lower frame body 2. The fastener 4 may use any suitable forms, such as a rivet, a combination of a bolt and a nut, or a screw. A material of the fastener 4 is preferably a material with low thermal conductivity.

A heat insulation pad 5 is provided under the heat exchange plate 1, as shown in FIG. 1. With the provision of the heat insulation pad 5, heat transfer of the heat exchange plate 1 is blocked in at least the downward direction, which facilitates heat preservation for the batteries 71 of the battery module 7. A material of the heat insulation pad 5 may be heat insulation cotton, foam, or the like.

A protective plate 6 supports the heat insulation pad 5 and the heat exchange plate 1 from below, as shown in FIG. 1. Under the impact of an external force (for example, flying rocks), the protective plate 6 protects the heat exchange plate 1 from failure due to damage by the external force. A material of the protective plate 6 is preferably a material with strong impact resistance, such as an aluminum alloy, a stainless steel, a high-strength steel, and a hot dip galvanized dual-phase DP high-strength alloy steel.

The above detailed description describes various example embodiments, but this specification is not intended to be limited to the specifically disclosed combinations. Therefore, unless otherwise stated, the various features disclosed herein can be combined together to form a plurality of additional combinations that are not shown for the sake of clarity.

Claims

1. A battery box, comprising: a heat exchange plate;a lower frame body located on a top plane of the heat exchange plate, the lower frame body comprising edge beams and internal beams;heat insulation glue; anda fastener,wherein the edge beams form a circumferential closure opened in an up-down direction, the edge beams and the heat exchange plate together form an accommodating space with an upward opening, the internal beams are located inside the accommodating space and divide the accommodating space into sub-accommodating spaces for placing battery modules therein, the heat exchange plate is configured to support the battery modules and exchanges heat with batteries of the battery modules,wherein at least one of the internal beams comprises a bottom plane, the bottom plane is partly in contact with the top plane of the heat exchange plate in the up-down direction and further comprises: a first plane in contact with the top plane of the heat exchange plate; anda second plane recessed upwardly with respect to the first plane from a side of the first plane in a direction that intersects with the up-down direction, such that the second plane is spaced apart from the top plane of the heat exchange plate in the up-down direction,wherein the fastener passes through the heat exchange plate and the internal beam at the location where the bottom plane of the internal beam contacts the top plane of the heat exchange plate.

2. The battery box according to claim 1, wherein at least a part of the heat insulation glue is filled between the second plane of the bottom plane of the at least one of the internal beams and the top plane of the heat exchange plate.

3. The battery box according to claim 1, wherein the at least one of the internal beams has an accommodating cavity located above a location where the bottom plane of the at least one of the internal beams contacts the top plane of the heat exchange plate, the fastener extends into the accommodating cavity.

4. The battery box according to claim 3, wherein at least a part of the fastener extends into the accommodating cavity and is spaced apart from a wall of the accommodating cavity.

5. The battery box according to claim 1, wherein the bottom plane of the internal beam further comprises a third plane recessed upwardly with respect to the first plane from another side of the first plane opposite to the direction that intersects with the up-down direction, so that the third plane is spaced apart from the top plane of the heat exchange plate in the up-down direction.

6. The battery box according to claim 5, wherein at least a part of the heat insulation glue is filled between the third plane and the top plane of the heat exchange plate.

7. The battery box according to claim 1, wherein the top plane of the heat exchange plate is flat in general.

8. The battery box according to claim 1, wherein the heat exchange plate comprises a main body and a bulge extending from the main body, wherein a downside of the bulge is recessed upwardly with respect to the main body, and an upside of the bulge protrudes upwardly with respect to the main body, the bulge has a top surface constituting a part of the top plane and an inclined plane, the inclined plane is positioned laterally to the top surface along the direction intersecting with the up-down direction.

9. The battery box according to claim 8, wherein the bottom plane of the at least one of the internal beams is partly in contact with the top surface of the bulge, and the inclined plane of the bulge is spaced apart from the top plane of the heat exchange plate in the up-down direction.

10. The battery box according to claim 8, wherein at least a part of the heat insulation glue is filled between the bottom plane of the internal beam and the inclined plane of the bulge.

11. The battery box according to claim 1, wherein a notch is provided on a lateral surface of the internal beam facing toward the battery modules.

12. The battery box according to claim 1, wherein the battery box further comprises a heat insulation pad under the heat exchange plate.

13. The battery box according to claim 12, wherein the heat insulation pad comprises insulating cotton or foam.

14. The battery box according to claim 12, wherein the battery box further comprises a protective plate under the heat insulation pad.

15. The battery box according to claim 14, wherein the protective plate comprises a material selected from one or more of an aluminum alloy, a stainless steel, a high-strength steel, and a hot dip galvanized dual-phase DP high-strength alloy steel.

16. The battery box according to claim 1, wherein the heat insulation glue is selected from one or more of heat insulation polyurethane glue and heat insulation epoxy glue.

17. The battery box according to claim 1, wherein the fastener is selected from at least one of a rivet, a combination of a bolt and a nut, and a screw.

18. The battery box according to claim 1, wherein the heat exchange plate is made of an aluminum alloy material.

19. The battery box according to claim 1, wherein the heat exchange plate comprises a first plate and a second plate, the top plane of the heat exchange plate is on the first plate, the lower frame body is located on the first plate of the heat exchange plate, and the second plate joins from below with the first plate to form a flow passage therebetween for a heat exchange medium to flow through.

20. The battery box according to claim 19, wherein the first plate and the second plate are formed by stamping.