Patent Description:
A battery box is mainly configured to support and accommodate a battery module. Since the battery module will generate heat during use, a cooling system needs to be adopted to cool the battery module. In the related art, the cooling system includes a cooling plate attached to an outside of the battery box, and the cooling plate is connected with the battery box. When a battery pack is in a vehicle and in operation, a connection between a liquid cooling plate and the battery box is stressed directly, which easily leads to a failure of the connection, and then leads to a failure of a cooling effect of the liquid cooling plate.

<CIT> discloses a battery box, which includes a lower box body, where the lower box body includes a first plate and a second plate. The first plate includes: a bottom wall; the second plate is fixed to the bottom wall from a bottom and engages with the bottom wall to form a flow passage. The second plate is provided with: a second protrusion protruding to the first plate; and an opening running through the second protrusion in a height direction, the second protrusion of the second plate being connected to the bottom wall of the first plate in a sealed manner. The battery box further includes: a reinforcing beam provided under the second plate; the reinforcing beam is mounted at a position corresponding to the opening and is fixedly connected to the first plate and/or the second plate.

A battery box and a battery pack are provided in implementations of the present disclosure, and improve a cooling effect of a cooling system on a battery module.

A battery box is provided in implementations of the present disclosure. The battery box may include a box body, a cooling plate, and a stiffener. The cooling plate is connected with an outside of a wall plate of the box body, and the stiffener is connected with the box body and abuts against a side of the cooling plate away from the wall plate.

The cooling plate is connected with the wall plate, and the stiffener is connected with the box body and abuts against the side of the cooling plate away from the wall plate. The stiffener can keep the cooling plate and the box body in a fitting state. If stiffener does not exist, when the cooling plate is subjected to an external pressure or under an action of a battery module, the cooling plate may be bent and deformed, resulting in a gap between the cooling plate and the wall plate. The stiffener is connected with the box body and abuts against the cooling plate to increase strength and stiffness of a connection between the cooling plate and the box body, so as to avoid a sealing failure caused by a force applied to a weld seam between the cooling plate and the box body during operation of the battery pack, which leads to a failure of a cooling effect of the cooling plate.

In some implementations of the present disclosure, the cooling plate may define grooves at the side of the cooling plate away from the box body, and the stiffener may be provided with convex portions in fit with the grooves, and the convex portions may extend into the grooves respectively and abut against at least part of inner side surfaces of the grooves.

Fitting connections among the convex portions and the grooves can make the stiffener and the cooling plate better abut against each other, so as to increase a fitting degree of the stiffener and the cooling plate.

In some implementations of the present disclosure, the cooling plate may have convex portions at the side of the cooling plate away from the box body, and the stiffener may define grooves in fit with the convex portions, and the convex portions may extend into the grooves respectively and abut against at least part of inner side surfaces of the grooves.

In some implementations of the present disclosure, a number of the convex portions may be less than or equal to a number of the grooves.

In some implementations of the present disclosure, a surface of the cooling plate away from the box body may be a flat surface.

In some implementations of the present disclosure, the stiffener may be not provided with convex portions and directly abut against the flat surface of the cooling plate; or the stiffener may be provided with the convex portions and abut against the flat surface of the cooling plate through the convex portions.

In some implementations of the present disclosure, the stiffener may be in surface contact with a surface of the cooling plate away from the wall plate.

Surface contact between the stiffener and the cooling plate can make the stiffener and the cooling plate have a better fitting degree, so as to avoid a gap between the stiffener and the cooling plate.

In some implementations of the present disclosure, a surface of the stiffener facing the cooling plate may be a curved surface or a flat surface.

In some implementations of the present disclosure, the battery box may further include a heat insulation layer attached to the side of the cooling plate away from the wall plate, and the heat insulation layer may abut against the stiffener.

The heat insulation layer can insulate the cooling plate to prevent a cooling capacity of the cooling plate from losing to the side of the cooling plate away from the wall plate.

In some implementations of the present disclosure, the stiffener may be implemented as a plurality of stiffeners arranged at intervals.

In some implementations of the present disclosure, the stiffener may be implemented as three or more stiffeners, two stiffeners are connected with two ends of the cooling plate respectively, and rest of stiffeners are connected with a middle of the cooling plate.

In some implementations of the present disclosure, two opposite ends of the stiffener may be located at two sides of the cooling plate respectively, and one end of the stiffener is connected with one side of the wall plate.

In the present disclosure, the box body is provided with a lifting lug, the wall plate is provided with a connecting portion, the connecting portion is connected with an end of the lifting lug to form a lifting ring, and the stiffener is connected with the connecting portion.

In the present disclosure, the connecting portion may be integrated with the lifting lug.

The connecting portion is integrated with the lifting lug, which is beneficial to reducing a space occupied by the lifting lug, so as to reduce a volume of the box body.

In some implementations of the present disclosure, the stiffener may be plate-like, and a surface of the stiffener away from the wall plate may be parallel to the wall plate.

A battery pack is further provided in implementations of the present disclosure. The battery pack includes a battery module and the battery box which is provided according to the above implementations, and the battery module is mounted in the battery box.

In order to explain technical solutions in implementations of the present disclosure more clearly, the following will give a brief introduction to accompanying drawings which are needed to be used in description of implementations or the related art. It should be understood that followings drawings only illustrate some implementations of the present disclosure and thus should not be considered as limitation to the scope. For those of ordinary skill in the art, other accompanying drawings can be obtained according to these accompanying drawings without creative efforts.

Reference signs:
<NUM>-battery box; <NUM>-box body; <NUM>-wall plate; <NUM>-lifting lug; <NUM>-connecting portion; <NUM>-cooling plate; <NUM>-groove; <NUM>-stiffener; <NUM>-convex portion; <NUM>-heat insulation layer.

In order to make a purpose, a technical solution, and an advantage of implementations of the present disclosure clearer, the technical solution of implementations of the present disclosure will be described clearly and completely in conjunction with accompanying drawings in implementations of the present disclosure. Obviously, described implementations are part of implementations of the present disclosure, not all of implementations. Generally, the assemblies of implementations of the present disclosure, which are described and illustrated in the accompanying drawings herein, may be arranged and designed in a variety of different configurations.

Therefore, the detailed description of implementations of the present disclosure provided in the accompanying drawings is not intended to limit the claimed scope of the present disclosure, but illustrates only the selected implementations of the present disclosure. All other implementations, obtained by those of ordinary skill in the art in light of implementations of the present disclosure without inventive efforts, will all fall within the claimed scope of the present disclosure.

It should be noted that similar signs and letters indicate similar items in the following accompanying drawings, and therefore, once an item is defined in an accompanying drawing, it is not necessary to further define or explain it in the subsequent accompanying drawings.

In the description of implementations of the present disclosure, it should be understood that orientation or positional relations indicated by terms such as "center", "up", "down", "left", "right", "vertical", "horizontal", "inside", and "outside" are orientation or positional relations based on the accompanying drawings, or orientation or positional relations in which the application product is placed conventionally in use, or orientation or positional relations commonly understood by those skilled in the art, only for facilitating description of the present disclosure and simplifying the description, rather than indicating or implying that the referred devices or elements must be in a particular orientation or constructed or operated in the particular orientation, and therefore they should not be construed as limiting the present disclosure.

In addition, terms such as "first", "second", etc., are used only for distinguishing the description, and should not be construed as indicating or implying relativity importance.

In the description of the present disclosure, it should be indicated that unless otherwise expressly specified or defined, terms such as "provide", "mount", "couple", and "connect" should be understood broadly, and for example, a fixed connection, or a detachable connection, or an integrated connection; and may be a direct connection, or an indirect connection via an intermediate medium, or may be an internal communication between two elements. The specific meanings of the above-mentioned terms in the present disclosure could be understood by those of ordinary skill in the art according to specific situations.

Reference can be made to <FIG>, where <FIG> is a schematic structural diagram of a battery box <NUM> from a first view provided in implementations of the present disclosure from a first view, and <FIG> is a schematic structural diagram of a battery box <NUM> from a second view provided in implementations of the present disclosure. A battery box <NUM> is provided in implementations and configured to accommodate a battery module.

The battery box <NUM> may include a box body <NUM>, a cooling plate <NUM>, and a stiffener <NUM>. The box body <NUM> may define an accommodating space, the accommodating space can be used to accommodate the battery module (not illustrated in the accompanying drawings), the box body <NUM> may have a wall plate <NUM>, an inside of the wall plate <NUM> can constitute an inner wall of the accommodating space.

The cooling plate <NUM> may be connected with the box body <NUM>, and the cooling plate <NUM> may be connected with an outside of the wall plate <NUM>, that is, the cooling plate <NUM> may be connected with a side of the wall plate <NUM> away from the accommodating space.

The stiffener <NUM> may abut against a side of the cooling plate <NUM> away from the wall plate <NUM>, and the stiffener <NUM> may be connected with the box body <NUM>.

It should be noted that in implementations, the wall plate <NUM> connected with the cooling plate <NUM> may be a bottom plate of the box body <NUM>, and the wall plate <NUM> may constitute a bottom wall of the accommodation space. It can be understood that in other implementations of the present disclosure, the wall plate <NUM> may be a side plate of the box body <NUM>, and the side plate may be connected with the cooling plate <NUM>. Alternatively, in other implementations of the present disclosure, the cooling plate <NUM> may also be disposed on both the bottom plate and the side plate of the box body <NUM> as needed.

In implementations, for example, the wall plate <NUM> is the bottom plate of the box body <NUM>. It can be understood that an identical effect may also be realized if the wall plate <NUM> is the side plate of the box body <NUM>.

In implementations, the wall plate <NUM> of the box body <NUM> and the cooling plate <NUM> may be welded by friction stir welding.

Reference can be made to <FIG>, which is a schematic structural diagram of a cooling plate <NUM> and stiffeners <NUM> provided in implementations of the present disclosure. In implementations, the cooling plate <NUM> may be molded by stamping, and the cooling plate <NUM> may be provided with multiple cooling channels (not illustrated in <FIG>) for a liquid coolant to flow. Therefore, multiple long-strip grooves <NUM> can be defined between outside walls of adjacent cooling channels. In other words, the cooling plate <NUM> may define multiple grooves <NUM> at a surface of the cooling plate <NUM>. The stiffener <NUM> may abut against the surface of the cooling plate <NUM>.

In implementations, the stiffener <NUM> may be provided with multiple convex portions <NUM>, and one convex portion <NUM> is corresponding to one groove <NUM>. One convex portion <NUM> may extend into one groove <NUM>, such that each convex portion <NUM> can abut against at least part of an inner side surface of each groove <NUM>. In other words, the each convex portion <NUM> may extend into each groove <NUM>, such that the each convex portion <NUM> abuts against a bottom surface, an inner side surface, or all inner surfaces of the each groove <NUM>. It can be understood that the each convex portion <NUM> abuts against part of or all of inner surfaces of the each groove <NUM>, which can avoid relative movement between the each convex portion <NUM> and the each groove <NUM>, so as to make the stiffener <NUM> and the cooling plate <NUM> present a better abutting state, thereby preventing the stiffener <NUM> and the cooling plate <NUM> from moving relative to each other.

It should be noted that in other implementations of the present disclosure, the number of convex portions <NUM> may be less than the number of grooves <NUM>. For example, the convex portions <NUM> of the stiffener <NUM> only extend into a part of grooves <NUM>, which can also stabilize the stiffener <NUM> and the cooling plate <NUM>.

In implementations, the each groove <NUM> has almost the same shape and size, so the each convex portion <NUM> has almost the same shape and size. It can be understood that in other implementations of the present disclosure, the multiple grooves <NUM> may be designed to be not exactly the same as needed, and corresponding convex portions <NUM> may be adaptively matched and adjusted.

In addition, in other implementations of the present disclosure, the cooling plate <NUM> may not be in the shape illustrated in implementations of the present disclosure, and the grooves <NUM> on the surface of the cooling plate <NUM> may be defined in a process of preparing cooling channels in an early stage or defined in a later stage.

A surface of the cooling plate <NUM> away from the wall plate <NUM> may be a flat surface and does not define the grooves <NUM>. Accordingly, the stiffener <NUM> may directly abut against the flat surface of the cooling plate <NUM> without the convex portions <NUM>, or the stiffener <NUM> may be provided with the convex portions <NUM> and abut against the flat surface.

It can be understood that in other implementations, the cooling plate <NUM> may be provided with convex portions <NUM>, accordingly, the stiffener <NUM> may define grooves <NUM>, and the convex portions <NUM> extend into the grooves <NUM> respectively, such that relative stability of the cooling plate <NUM> and the stiffener <NUM> is realized.

Optionally, in order to increase an abutting effect of the stiffener <NUM> on the cooling plate <NUM>, a surface of the stiffener <NUM> facing the cooling plate <NUM> may be in surface contact with the cooling plate <NUM>. The surface of the stiffener <NUM> facing the cooling plate <NUM> may be a curved surface or a flat surface, and the surface contact can reduce a gap between the stiffener <NUM> and the cooling plate <NUM> and avoid deformation of the cooling plate <NUM> as much as possible.

In implementations, the stiffener <NUM> may be a long-strip plate, and the cooling plate <NUM> may also be a substantially rectangular plate. The stiffener <NUM> may extend from one side of the cooling plate <NUM> to another side of the cooling plate <NUM>. Two opposite ends of the stiffener <NUM> in a length direction of the stiffener <NUM> may be located on two sides of the cooling plate <NUM> respectively, such that the cooling plate <NUM> is abutted against by the stiffener <NUM> in the length direction of the stiffener <NUM>.

In implementations, a surface of the stiffener <NUM> away from the wall plate <NUM> may be parallel to the wall plate <NUM>. In other implementations of the present disclosure, the stiffener <NUM> may be disposed in a curved shape, and the stiffener <NUM> may be bent on the surface of the cooling plate <NUM>, or in other implementations, the stiffener <NUM> may also be in a plate shape which is similar to the shape of the cooling plate <NUM>.

Reference can made to <FIG> again, and in some implementations, the battery box <NUM> may include three stiffeners <NUM>, and the three stiffeners <NUM> may be arranged at intervals. In implementations, the three stiffeners <NUM> may be arranged in parallel. It can be understood that in other implementations of the present disclosure, the three stiffeners <NUM> may be arranged at intervals and at an angle with each other. Alternatively, the three stiffeners <NUM> may be arranged in an interconnected manner, for example, the three stiffeners <NUM> are connected in an "H" shape, etc..

In addition, in other implementations of the present disclosure, the number of the stiffener <NUM> may not be limited to three, for example, may be one, two, four or more, and so on. A shape of the stiffener <NUM> is not limited. For example, the stiffener <NUM> may be implemented as one stiffener <NUM>, the stiffener <NUM> may be in a scattering form, the stiffener <NUM> may have portions extending in multiple directions, and each portion can abut against the cooling plate <NUM>.

Optionally, in some implementations, two of the three stiffeners <NUM> may be connected with the two opposite ends of the cooling plate <NUM> respectively. In other words, one stiffener <NUM> may be connected with one end of the cooling plate <NUM>, and another stiffener <NUM> may be connected with another end of the cooling plate <NUM>. One remaining stiffener <NUM> may be connected with a middle of the cooling plate <NUM>, where the middle is not limited to a middle position of the cooling plate <NUM> in size, but means a position which is not at ends of the cooling plate <NUM>.

In this arrangement manner, edge lifting of an end of the cooling plate <NUM> can be avoided under an action of the stiffener <NUM>. The stiffener <NUM> can keep the end of the cooling plate <NUM> and the box body <NUM> in an abutting state. Even if the battery box <NUM> is subjected to a force applied by environment or the battery module, a sealing failure caused by the force applied to a weal seam between the cooling plate <NUM> and the box body <NUM> will not occur, thereby avoiding a failure of a cooling effect.

It can be understood that in other implementations of the present disclosure, the stiffener <NUM> may not be connected with the end of the cooling plate <NUM>.

In implementations, the battery box <NUM> may further have a heat insulation layer <NUM>, the insulation layer <NUM> may be connected with the side of the cooling plate <NUM> away from the wall plate <NUM> by spraying, and the stiffener <NUM> may abut against the heat insulation layer <NUM>.

The heat insulation layer <NUM> can insulate the cooling plate <NUM> to prevent a cooling capacity of the cooling plate <NUM> from losing to the side of the cooling plate <NUM> away from the wall plate <NUM>.

In some implementations, the heat insulation layer <NUM> may be formed by curing of a heat insulation adhesive attached to the surface of the cooling plate <NUM>, and a shape of a surface of the heat insulation layer <NUM> away from the surface of the cooling plate <NUM> may be similar to a shape of the cooling plate <NUM> away from the wall plate <NUM>. Therefore, in implementations, the shape of the cooling plate <NUM> is taken as an example to describe. It can be understood that the shape of the surface of the heat insulation layer <NUM> away from the wall plate <NUM> may also be changed according to filling requirements.

Reference can be made to <FIG>, which is a partial schematic diagram of a battery box <NUM> in the present disclosure. In implementations, the stiffener <NUM> may be connected with the battery box <NUM> through bolts.

The box body <NUM> is provided with a lifting lug <NUM>, the wall plate <NUM> is provided with a connecting portion <NUM>, the connecting portion <NUM> is connected with an end of the lifting lug <NUM> to form a lifting ring, and the stiffener <NUM> is connected with the connecting portion <NUM>.

the wall plate <NUM> is provided with the connecting portion <NUM> which protrudes from the wall plate <NUM>, and the connecting portion <NUM> and the lifting lug <NUM> is enclosed to form the lifting ring. The connecting portion <NUM> is integrated with the lifting lug <NUM>, which is beneficial to reducing a space occupied by the lifting lug <NUM>, so as to reduce a volume of the box body <NUM>. In addition, the stiffener <NUM> is connected with the connecting portion <NUM>, and the connecting portion <NUM> is connected with the stiffener <NUM> without bending the stiffener <NUM>.

It should be noted that in other implementations of the present disclosure, the stiffener <NUM> may also be connected with the box body <NUM> in other connection manners. For example, the stiffener <NUM> and the box body <NUM> may be welded together, or be connected by screw threads or clamping.

The battery box <NUM> provided in implementations of the present disclosure at least has following advantages. The cooling plate <NUM> is connected with the wall plate <NUM> of the box body <NUM>, the stiffener <NUM> abuts against the side of the cooling plate <NUM> away from the wall plate <NUM>, and the stiffener <NUM> is connected with the box body <NUM>. The stiffener <NUM> can keep the cooling plate <NUM> and the box body <NUM> in the abutting state. The stiffener <NUM> is connected with the box body <NUM> and abuts against the cooling plate <NUM> to increase strength and stiffness of a connection between the cooling plate <NUM> and the box body <NUM>, so as to avoid the sealing failure caused by the force applied to the weld seam between the cooling plate <NUM> and the box body <NUM> during the operation of the battery pack, which leads to the failure of the cooling effect of the cooling plate <NUM>.

Optionally, in terms of implementations of connecting the stiffener <NUM> and the cooling plate <NUM> by fitting connections among the convex portions <NUM> and the grooves <NUM>, the fitting connections among the convex portions <NUM> and the grooves <NUM> can make the stiffener <NUM> and the cooling plate <NUM> better abut against each other, so as to increase a fitting degree of the stiffener <NUM> and the cooling plate <NUM>.

A battery pack is further provided in implementations of the present disclosure. The battery pack may include a battery module and the above battery box <NUM>, and the battery module is mounted in the battery box <NUM>.

The battery pack has at least all the advantages of the above battery box <NUM>, and the cooling plate <NUM> of the battery pack can have a relatively great cooling effect on the battery pack.

The above descriptions are only preferred implementations of the present disclosure, and are not used to limit the present disclosure.

The battery box and the battery pack are provided in the present disclosure. The battery box includes a box body, a cooling plate, and a stiffener. The cooling plate is connected with the outside of the wall plate of the box body, and the stiffener is connected with the box body and abuts against the side of the cooling plate away from the wall plate. The cooling plate is connected with the box body, the stiffener is connected with the box body, and the stiffener abuts against the side of the cooling plate away from the wall plate. The stiffener can keep the cooling plate and the box body in the abutting state, and when the cooling plate is subjected to the external pressure or the action of the battery module, the cooling plate may be bent or deformed, resulting in the gap between the cooling plate and the wall plate. The stiffener is connected with the box body and abuts against the cooling plate to increase the strength and the stiffness of the connection between the cooling plate and the box body, so as to avoid the sealing failure caused by the force applied to the weld seam between the cooling plate and the box body during the operation of the battery pack, which leads to the failure of the cooling effect of the cooling plate.

Claim 1:
A battery box (<NUM>), comprising:
a box body (<NUM>);
a cooling plate (<NUM>) connected with an outside of a wall plate (<NUM>) of the box body (<NUM>); and
a stiffener (<NUM>) connected with the box body (<NUM>) and abutting against a side of the cooling plate (<NUM>) away from the wall plate (<NUM>);
wherein the box body (<NUM>) is provided with a lifting lug (<NUM>), the wall plate (<NUM>) is provided with a connecting portion (<NUM>), the connecting portion (<NUM>) is connected with an end of the lifting lug (<NUM>) to form a lifting ring, and the stiffener (<NUM>) is connected with the connecting portion (<NUM>).