CN215496962U - Stackable battery and stackable battery pack - Google Patents

Abstract

The utility model discloses a stackable battery and a stackable battery pack, the stackable battery includes: the battery comprises a battery body, a socket piece and a plug piece; the socket piece and the plug piece are respectively arranged on two opposite surfaces of the battery body, the socket piece is provided with a socket slot, and the plug piece is provided with a plug bulge; when one battery body is stacked with the other battery body, the inserting projection in one battery body is inserted into the bearing slot in the other battery body. When a battery body piles up with another battery body to the protruding socket joint groove of pegging graft in another battery body of grafting in the battery body, so, pile up in proper order through the mode of pegging graft, need not to fix through the rack again, simple structure not only easily realizes, and reduce cost.

Description

Stackable battery and stackable battery pack

Technical Field

The application relates to the technical field of new energy, in particular to a stackable battery and a stackable battery pack.

Background

At present, the number of the plug-in box type lithium batteries is generally large in the using process, and the plug-in box type lithium batteries are generally stacked by adopting a standard network cabinet or a customized cabinet in consideration of use safety, convenience, attractiveness and the like. The standard network cabinet can be easily bought in the market, the use requirements can be met by slightly modifying the standard network cabinet in actual use, the customized cabinet is designed according to the user requirements, the cabinet finished product does not need to be modified and can be directly installed and used, and the standard network cabinet and the customized cabinet have the defect of high cost.

SUMMERY OF THE UTILITY MODEL

The application provides a stackable battery and a stackable battery pack, which are simple in structure, easy to realize and capable of reducing cost.

According to a first aspect of the present application, there is provided a stackable battery comprising: the battery comprises a battery body, a socket piece and a plug piece; the socket piece and the plug piece are respectively arranged on two opposite surfaces of the battery body, the socket piece is provided with a socket slot, and the plug piece is provided with a plug bulge; when one battery body is stacked with the other battery body, the inserting projection in one battery body is inserted into the bearing slot in the other battery body.

In one embodiment, two socket pieces are oppositely arranged on the top surface of the battery body, and a first side surface limiting structure is further arranged on each socket piece and used for abutting against the side surface of the battery body so as to limit the two socket pieces to approach each other; the battery comprises a battery body and is characterized in that two plug connectors are oppositely arranged on the bottom surface of the battery body, and a second side limiting structure is further arranged on each plug connector and used for abutting against the side surface of the battery body so as to limit the two plug connectors to be close to each other.

In an embodiment, the socket piece is further provided with a first transverse limiting structure, the plug piece is further provided with a second transverse limiting structure, and when the plug protrusion in one battery body is plugged into the socket slot in the other battery body, the first transverse limiting structure is used for blocking the second transverse limiting structure from moving along the transverse direction so as to limit the relative movement of one battery body and the other battery body along the transverse direction; the socket piece is further provided with a first longitudinal limiting structure, the plug connector is further provided with a second longitudinal limiting structure, and when the plug protrusion in one battery body is plugged in the socket slot in the other battery body, the first longitudinal limiting structure is used for blocking the second longitudinal limiting structure from moving along the longitudinal direction so as to limit the relative movement of the one battery body and the other battery body along the longitudinal direction.

In one embodiment, the first lateral restraining structure comprises: the two first transverse limiting plates are respectively arranged on two wide side edges of the socket piece along the length direction of the socket piece; the second transverse limiting structure comprises: the two second transverse limiting plates are respectively arranged on two wide side edges of the plug connector along the length direction of the plug connector; when the inserting protrusion in one battery body is inserted into the inserting groove in the other battery body, the two second transverse limiting plates are positioned between the two first transverse limiting plates, and the distance between the inner sides of the two first transverse limiting plates is equal to the distance between the outer sides of the two second transverse limiting plates; the first longitudinal limiting structure comprises: the two first longitudinal limiting plates are respectively arranged on two long side edges of the socket piece along the width direction of the socket piece; the second longitudinal limiting structure comprises: the two second longitudinal limiting plates are respectively arranged on two long side edges of the plug connector along the width direction of the plug connector; when the inserting protrusion in one battery body is inserted into the inserting groove in the other battery body, the two second longitudinal limiting plates are positioned between the two first longitudinal limiting plates, and the distance between the inner sides of the two first longitudinal limiting plates is equal to the distance between the outer sides of the two second longitudinal limiting plates; the two first transverse limiting plates and the two first longitudinal limiting plates are sequentially connected to form the socket slot, and the two second transverse limiting plates and the two second longitudinal limiting plates are sequentially connected to form the inserting protrusion; the length direction of the socket piece and the length direction of the plug connector are both the transverse direction, and the width direction of the socket piece and the width direction of the plug connector are both the longitudinal direction.

In an embodiment, a first notch portion is further disposed on the first longitudinal limiting plate close to the side of the battery body, and the first lateral limiting structure is mounted on the first notch portion; and a second notch part is further arranged on the second longitudinal limiting plate close to the side surface of the battery body in the two second longitudinal limiting plates, and the second lateral limiting structure is arranged at the second notch part.

In one embodiment, the first side limiting structure and the second side limiting structure are both L-shaped limiting structures, and each L-shaped limiting structure is provided with a connecting part and a blocking part vertically connected with the connecting part; the connecting part of the first side limiting structure is connected to the first notch part, and the blocking part of the first side limiting structure blocks the side surface of the battery body; the connecting portion of the second side limiting structure is connected to the second notch portion, and the blocking portion of the second side limiting structure abuts against the side face of the battery body.

In an embodiment, a first connecting portion is further disposed on a groove wall of the socket groove, a second connecting portion is further disposed on the insertion protrusion, and when the insertion protrusion in one battery body is inserted into the socket groove in another battery body, the first connecting portion is tightly connected with the second connecting portion.

In an embodiment, the first connecting portion is a via hole, the second connecting portion is a screw hole, and the first connecting portion and the second connecting portion are connected through a fastening bolt.

In one embodiment, the method further comprises: the two ends of the socket piece extend and are exposed out of the battery body respectively to form two socket piece exposed sections, the two ends of the plug piece extend and are exposed out of the battery body respectively to form two plug piece exposed sections, the two socket piece exposed sections are in one-to-one correspondence with the two plug piece exposed sections respectively, and the connecting piece is used for connecting the socket piece exposed sections and the plug piece exposed sections in one-to-one correspondence.

According to a second aspect of the present application, there is provided a stacked battery pack including: at least two of said stackable batteries.

According to the stackable battery and the stackable battery pack of the above embodiments, when one battery body is stacked with another battery body, the insertion protrusion in the battery body is inserted into the socket groove in the other battery body, so that the batteries are sequentially stacked in an insertion manner without being fixed by a cabinet, and the stackable battery pack are simple in structure, easy to implement and capable of reducing cost.

Drawings

Fig. 1 is an exploded view of a stackable battery provided herein;

fig. 2 is a schematic structural diagram of a stackable battery provided herein after assembly;

FIG. 3 is a first schematic diagram illustrating a process of stacking stackable batteries in the stacked battery pack provided herein;

fig. 4 is a second schematic process diagram illustrating stacking of stackable batteries in the stacked battery pack provided herein.

Detailed Description

The present application will be described in further detail below with reference to the accompanying drawings by way of specific embodiments. Wherein like elements in different embodiments are numbered with like associated elements. In the following description, numerous details are set forth in order to provide a better understanding of the present application. However, those skilled in the art will readily recognize that some of the features may be omitted or replaced with other elements, materials, methods in different instances. In some instances, certain operations related to the present application have not been shown or described in detail in order to avoid obscuring the core of the present application from excessive description, and it is not necessary for those skilled in the art to describe these operations in detail, so that they may be fully understood from the description in the specification and the general knowledge in the art.

Furthermore, the features, operations, or characteristics described in the specification may be combined in any suitable manner to form various embodiments, and the operation steps involved in the embodiments may be interchanged or modified in order as will be apparent to those skilled in the art. Accordingly, the description and drawings are merely for clarity of description of certain embodiments and are not intended to necessarily refer to a required composition and/or order.

The numbering of the components as such, e.g., "first", "second", etc., is used herein only to distinguish the objects as described, and does not have any sequential or technical meaning. The term "connected" and "coupled" when used in this application, unless otherwise indicated, includes both direct and indirect connections (couplings).

The present application provides a stackable battery and a stackable battery pack, wherein the stackable battery pack is composed of at least two stackable batteries, and the stackable batteries are connected in series or in parallel. In this application, adopt the mode of grafting arch grafting in the socket groove between each heap battery to connect each heap battery, not only simple structure, easily operation still can show reduce cost for the mode that adopts the cabinet body to assemble in the past.

The first embodiment,

Referring to fig. 1 and 2, the present embodiment provides a stackable battery, which mainly includes: a battery body 10, a socket 20, and a plug 30. The socket 20 and the socket 30 are respectively provided on opposite surfaces of the battery body 10, and more specifically, the socket 20 and the socket 30 are respectively fixed on opposite surfaces of the battery body 10 by means of bonding, bolt fastening, welding, or the like. The female member 20 is provided with a female receiving groove 21 and the male member 30 is provided with a male protrusion 31. When one cell body is stacked with another cell body, the insertion projection 31 of one cell body 10 is inserted into the insertion groove 21 of the other cell body 10. In this manner, a stacked placement of two stackable batteries is achieved.

In this embodiment, the battery body 10 may be a lithium ion battery, or may be a lead-acid battery, and preferably, a lithium ion battery is used. The battery body 10 has a case, and when two stackable batteries are stacked, for convenience of description, opposite surfaces of the battery body 10 on which the socket member 20 and the plug member 30 are respectively mounted are referred to as a top surface and a bottom surface, that is, the socket member 20 is mounted on the top surface of the battery body 10 and the plug member 30 is mounted on the bottom surface of the battery body 10.

When only one socket member 20 and one plug member 30 are provided, it is only necessary to install the socket member 20 at a position where the top surface of the battery body 10 coincides with the center of gravity and to install the plug member 30 at a position where the bottom surface of the battery body 10 coincides with the center of gravity in a direction perpendicular to the top surface and the bottom surface of the battery body 10 in the case where the center of gravity of the battery body 10 is determined.

Referring specifically to fig. 3 and 4, the battery bodies of the two stackable batteries are defined as a first battery body 10 and a second battery body 10 ', respectively, the female member in the first battery body 10 is defined as a first female member 20, the female groove in the first female member 20 is defined as a first female groove 21, the male member in the first battery body 10 is defined as a first male member 30, the male protrusion in the first male member 30 is defined as a first male protrusion 31, the female member in the second battery body 10 ' is defined as a second female member 20 ', the female groove in the second female member 20 ' is defined as a second female groove 21 ', the male member in the first battery body 10 is defined as a second male member 30 ', the male protrusion in the second male member 30 ' is defined as a second male protrusion 31 ', and the first battery body 10 is located above the second battery body 10 '. The first coupling projection 31 of the first coupling member 30 of the first battery body 10 is coupled to the second receiving groove 21 of the second receiving member 20 ' of the second battery body 10 ' when the first battery body 10 is stacked to the second battery body 10 ', so that the stacked arrangement of two stackable batteries is accomplished.

In one embodiment, the battery body 10 is a cylindrical lithium battery such as 18650, the socket member 20 has a ring shape disposed on and surrounding the top surface of the cylindrical lithium battery, and the plug member 30 has a ring shape surrounding the bottom surface of the cylindrical lithium battery. Of course, the insertion protrusion 31 may be in an annular shape, or may be a protrusion structure sequentially arranged at intervals along a length direction of the annular insertion protrusion, and correspondingly, the insertion slot 21 is a groove in an annular shape, or may be a groove adapted to a plurality of protrusion structures.

In this embodiment, the battery body 10 is a square structure, two socket members 20 are disposed on the top surface of the battery body 10 opposite to each other, both the socket members 20 are elongated structures, and correspondingly, two plug members 30 are disposed on the bottom surface of the battery body 10 opposite to each other, both the plug members 30 are elongated structures. The two socket members 20 correspond to the two plug members 30 one by one. A first side limiting structure 22 is further disposed on the socket member 20, and the first side limiting structure 22 is used for abutting against the side of the battery body 10 to limit the two socket members 20 from approaching each other. The plug-in unit 30 is further provided with a second side surface limiting structure 32, and the second side surface limiting structure 32 is used for abutting against the side surface of the battery body 10 to limit the two plug-in units 30 to approach each other. The arrangement is such that play of the two stackable batteries is avoided when the two stackable batteries are stacked, thereby providing stability of stacking.

In this embodiment, the socket member 20 and the plug member 30 have the same length, which is defined as length B, and the distance between the two socket members 20 and the distance between the two plug members 30 are the same, which is defined as distance a, wherein the value of the distance a is greater than the value of the length B, so that a fool-proof function can be formed when stacking two stackable batteries, thereby preventing an installation error.

In one embodiment, the first side limiting structures 22 of the two socket members 20 respectively abut against two opposite sides of the battery body 10, the second side limiting structures 32 of the two plug members 30 respectively abut against two opposite sides of the battery body 10, and the first side limiting structures 22 of the two socket members 20 respectively abut against two opposite sides of the battery body 10 the same as the second side limiting structures 32 of the two plug members 30 respectively abut against two opposite sides of the battery body 10.

In this embodiment, a first lateral limiting structure is further disposed on the socket member 20, a second lateral limiting structure is further disposed on the plug member 30, and when the plug protrusion 31 of one battery body 10 is plugged into the socket slot 21 of another battery body 10, the first lateral limiting structure is used to block the second lateral limiting structure from moving in the lateral direction, so as to limit the relative movement between the one battery body 10 and the other battery body 10 in the lateral direction. The socket member 20 is further provided with a first longitudinal limiting structure, the plug member 30 is further provided with a second longitudinal limiting structure, and when the plug protrusion 31 of one battery body 10 is plugged into the socket groove 21 of the other battery body 10, the first longitudinal limiting structure is used for blocking the second longitudinal limiting structure from moving along the longitudinal direction so as to limit the relative movement of one battery body 10 and the other battery body 10 along the longitudinal direction. Thus, the stability of stacking of two stackable batteries is further improved by the structure of limiting in the transverse direction and the longitudinal direction.

In this embodiment, first horizontal limit structure includes: the two first transverse limiting plates 23 are respectively arranged on two wide side edges of the socket piece 20 along the length direction of the socket piece 20; the horizontal limit structure of second includes: and two second transverse limit plates 33, the two second transverse limit plates 33 being respectively disposed on two wide sides of the plug 30 along a length direction of the plug 30. When the insertion protrusion 31 of one battery body 10 is inserted into the insertion slot 21 of the other battery body 10, the two second transverse limiting plates 33 are located between the two first transverse limiting plates 23, and the distance between the inner sides of the two first transverse limiting plates 23 is equal to the distance between the outer sides of the two second transverse limiting plates 33, so that the transverse square is limited.

First vertical limit structure includes: two first longitudinal retainer plates 24, the two first longitudinal retainer plates 24 being provided on both long sides of the socket 20 in the width direction of the socket 20, respectively. The second longitudinal limiting structure comprises: and two second longitudinal limit plates 34, the two second longitudinal limit plates 34 being respectively disposed on two long sides of the plug-in unit 30 along the width direction of the plug-in unit 30. When the insertion protrusion 31 of one battery body 10 is inserted into the insertion slot 21 of the other battery body 10, the two second longitudinal limiting plates 34 are located between the two first longitudinal limiting plates 24, and the distance between the inner sides of the two first longitudinal limiting plates 24 is equal to the distance between the outer sides of the two second longitudinal limiting plates 34, so that the longitudinal direction is limited.

In this embodiment, the two first transverse limiting plates 23 and the two first longitudinal limiting plates 24 are sequentially connected to form the socket 21, and the two second transverse limiting plates 33 and the two second longitudinal limiting plates 34 are sequentially connected to form the inserting protrusion 31.

The longitudinal direction of the socket 20 and the longitudinal direction of the plug 30 are both transverse directions, and the width direction of the socket 20 and the width direction of the plug 30 are both longitudinal directions.

As shown in fig. 1, a first notch portion 241 is further provided in one of the two first longitudinal restraining plates 24 close to the side of the battery body 10, and the first side restraining structure 22 is mounted in the first notch portion 241. A second cutaway portion 341 is further provided in one of the two second longitudinal restriction plates 34 close to the side of the battery body 10, and the second side restriction structure 32 is mounted in the second cutaway portion 341. Through the setting of breach portion, not only make things convenient for the installation of vertical limiting plate, still can save the material of vertical limiting plate simultaneously to reach the purpose of saving the cost.

In this embodiment, the first side limiting structure 22 and the second side limiting structure 32 are both L-shaped limiting structures, and each L-shaped limiting structure has a connecting portion and a blocking portion vertically connected to the connecting portion. The connecting portion of the first side limiting structure 21 is connected to the first notch portion 241, and the blocking portion of the first side limiting structure 22 blocks the side of the battery body 10. The connecting portion of the second side limiting structure 32 is connected to the second notch portion 341, and the blocking portion of the second side limiting structure 34 abuts against the side surface of the battery body 10.

In one embodiment, a first connecting portion 231 is further disposed on a groove wall of the socket slot 21, a second connecting portion 331 is further disposed on the insertion projection 31, and when the insertion projection 31 of one battery body 10 is inserted into the socket slot 21 of another battery body 10, the first connecting portion 231 is tightly connected with the second connecting portion 331.

In this embodiment, the first connecting portion 231 is a through hole, the second connecting portion 331 is a screw hole, and when the inserting protrusion 31 of one battery body 10 is inserted into the inserting slot 21 of another battery body 10, the first connecting portion 231 and the second connecting portion 331 are connected by the fastening bolt 50.

With continued reference to fig. 1 and 2, the stackable battery provided in this embodiment further includes: and the two ends of the socket piece 20 extend and are exposed out of the battery body 10 respectively to form two socket piece exposed sections, the two ends of the plug piece 30 extend and are exposed out of the battery body 10 respectively to form two plug piece exposed sections, the two socket piece exposed sections are in one-to-one correspondence with the two plug piece exposed sections respectively, and the connecting piece 40 is used for connecting the socket piece exposed sections and the plug piece exposed sections which are in one-to-one correspondence so as to connect the socket piece 20 and the plug piece 30 which are in one-to-one correspondence. The installation of the socket 20 and the plug 30 is facilitated by the arrangement of the connection member 40.

In this embodiment, the connection member 40 is preferably a screw, and correspondingly, a through hole is provided at the exposed section of the socket member, and a screw hole is provided at the exposed section of the plug member for connection by the screw.

Example II,

As shown in fig. 3 and 4, the present embodiment provides a stacked battery pack, the stacked battery pack including: at least two stackable batteries. Fig. 3 and 4 show four stackable batteries, which are sequentially stacked to form a cost-stacked battery pack. Of course, in other embodiments, other different numbers of stackable batteries may be provided in the stacked battery pack.

In summary, in the hydrogen fuel cell testing system and the stackable battery provided by the present application, when one battery body is stacked with another battery body, the insertion protrusion in the battery body is inserted into the socket groove in the other battery body, so that the battery bodies are sequentially stacked in an insertion manner without being fixed by a cabinet, which is not only simple in structure and easy to implement, but also can reduce the cost.

The present invention has been described in terms of specific examples, which are provided to aid understanding of the utility model and are not intended to be limiting. For a person skilled in the art to which the utility model pertains, several simple deductions, modifications or substitutions may be made according to the idea of the utility model.

Claims (10)

1. A stackable battery, comprising: the battery comprises a battery body, a socket piece and a plug piece; the socket piece and the plug piece are respectively arranged on two opposite surfaces of the battery body, the socket piece is provided with a socket slot, and the plug piece is provided with a plug bulge; when one battery body is stacked with the other battery body, the inserting projection in one battery body is inserted into the bearing slot in the other battery body.

2. The stackable battery according to claim 1, wherein the top surface of said battery body is oppositely disposed with two sockets, said sockets further having a first side stop structure disposed thereon, said first side stop structure being adapted to abut against a side of said battery body to limit the proximity of said two sockets to each other; the battery comprises a battery body and is characterized in that two plug connectors are oppositely arranged on the bottom surface of the battery body, and a second side limiting structure is further arranged on each plug connector and used for abutting against the side surface of the battery body so as to limit the two plug connectors to be close to each other.

3. The stackable battery according to claim 2, wherein said female member further has a first lateral restraining structure provided thereon, said male member further has a second lateral restraining structure provided thereon, said first lateral restraining structure being adapted to block said second lateral restraining structure from moving in a lateral direction when said male protrusion of one of said battery bodies is inserted into said female slot of another of said battery bodies, so as to restrain relative movement of one of said battery bodies and another of said battery bodies in the lateral direction; the socket piece is further provided with a first longitudinal limiting structure, the plug connector is further provided with a second longitudinal limiting structure, and when the plug protrusion in one battery body is plugged in the socket slot in the other battery body, the first longitudinal limiting structure is used for blocking the second longitudinal limiting structure from moving along the longitudinal direction so as to limit the relative movement of the one battery body and the other battery body along the longitudinal direction.

4. The stackable battery of claim 3, wherein the first lateral restraining structure comprises: the two first transverse limiting plates are respectively arranged on two wide side edges of the socket piece along the length direction of the socket piece; the second transverse limiting structure comprises: the two second transverse limiting plates are respectively arranged on two wide side edges of the plug connector along the length direction of the plug connector; when the inserting protrusion in one battery body is inserted into the inserting groove in the other battery body, the two second transverse limiting plates are positioned between the two first transverse limiting plates, and the distance between the inner sides of the two first transverse limiting plates is equal to the distance between the outer sides of the two second transverse limiting plates; the first longitudinal limiting structure comprises: the two first longitudinal limiting plates are respectively arranged on two long side edges of the socket piece along the width direction of the socket piece; the second longitudinal limiting structure comprises: the two second longitudinal limiting plates are respectively arranged on two long side edges of the plug connector along the width direction of the plug connector; when the inserting protrusion in one battery body is inserted into the inserting groove in the other battery body, the two second longitudinal limiting plates are positioned between the two first longitudinal limiting plates, and the distance between the inner sides of the two first longitudinal limiting plates is equal to the distance between the outer sides of the two second longitudinal limiting plates; the two first transverse limiting plates and the two first longitudinal limiting plates are sequentially connected to form the socket slot, and the two second transverse limiting plates and the two second longitudinal limiting plates are sequentially connected to form the inserting protrusion; the length direction of the socket piece and the length direction of the plug connector are both the transverse direction, and the width direction of the socket piece and the width direction of the plug connector are both the longitudinal direction.

5. The stackable battery according to claim 4, wherein a first notch portion is further provided on the first one of the two first longitudinal restriction plates that is adjacent to the side of the battery body, the first side restriction structure being mounted in the first notch portion; and a second notch part is further arranged on the second longitudinal limiting plate close to the side surface of the battery body in the two second longitudinal limiting plates, and the second lateral limiting structure is arranged at the second notch part.

6. The stackable battery of claim 5, wherein the first and second side limiting structures are each an L-shaped limiting structure having a connecting portion and a blocking portion perpendicularly connected to the connecting portion; the connecting part of the first side limiting structure is connected to the first notch part, and the blocking part of the first side limiting structure blocks the side surface of the battery body; the connecting portion of the second side limiting structure is connected to the second notch portion, and the blocking portion of the second side limiting structure abuts against the side face of the battery body.

7. The stackable battery as defined in claim 1, wherein a first connecting portion is further formed on a wall of said receptacle slot, and a second connecting portion is further formed on said insertion projection, said first connecting portion being securely connected to said second connecting portion when said insertion projection of one of said battery bodies is inserted into said receptacle slot of another of said battery bodies.

8. The stackable battery according to claim 7, wherein the first connection part is a via hole, the second connection part is a screw hole, and the first connection part and the second connection part are connected by a fastening bolt.

9. The stackable battery according to claim 1, further comprising: the two ends of the socket piece extend and are exposed out of the battery body respectively to form two socket piece exposed sections, the two ends of the plug piece extend and are exposed out of the battery body respectively to form two plug piece exposed sections, the two socket piece exposed sections are in one-to-one correspondence with the two plug piece exposed sections respectively, and the connecting piece is used for connecting the socket piece exposed sections and the plug piece exposed sections in one-to-one correspondence.

10. A stacked battery, comprising: at least two stackable batteries according to any one of claims 1 to 9.

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