CN217035835U - Be applied to limit structure of battery safety support frame of energy storage power - Google Patents

Abstract

The utility model discloses a limiting structure of a battery safety supporting frame applied to an energy storage power supply, wherein a first conducting strip is arranged at the top of the battery frame, a second conducting strip is arranged at the bottom of the battery frame, and the battery frame is used for accommodating a plurality of batteries; one end of each battery is connected with the first conducting strip positioned at the top of the battery rack, and the other end of each battery is connected with the second conducting strip positioned at the bottom of the battery rack; be provided with stop gear and a plurality of latch mechanism on the battery frame side, stop gear is last to have and is used for holding circuit board joint region, the circuit board is arranged in on the joint region, and a plurality of latch mechanism with the circuit board joint, latch mechanism is used for fixing the circuit board. Through the arrangement of the limiting mechanism and the clamping mechanisms, the circuit board can be fixed on the battery rack under the condition of not using screws, so that the circuit board can be conveniently assembled and disassembled; because the steps of locking the screw are reduced, the production efficiency is improved, and the production cost is reduced.

Description

Be applied to limit structure of battery safety support frame of energy storage power

Technical Field

The utility model relates to the technical field of energy storage power supply battery support frames, in particular to a limiting structure of a battery safety support frame applied to an energy storage power supply.

Background

The energy storage power supply battery is applied to various fields of using batteries such as a mobile power supply, the battery support is used for fixing the batteries, and the support is fixed, so that the space between the batteries is reserved to facilitate heat dissipation. And meanwhile, a circuit board for controlling and monitoring the battery is arranged on one side of the battery bracket. In the prior art, a circuit board is fixed on a battery bracket through screws; however, in use, the screws encroach on the space inside the battery rack for accommodating the batteries, and there is a risk of scratching the batteries.

SUMMERY OF THE UTILITY MODEL

Therefore, a limiting structure applied to a battery safety supporting frame of an energy storage power supply needs to be provided, so that a circuit board can be fixed on the battery frame without screws.

For realizing above-mentioned purpose, the application provides a be applied to battery safety support frame's of energy storage power limit structure, includes: the battery comprises a battery frame, a first conducting plate, a second conducting plate and a circuit board;

the first conducting strip is arranged at the top of the battery frame, the second conducting strip is arranged at the bottom of the battery frame, and the battery frame is used for accommodating a plurality of batteries; one end of each battery is connected with the first conducting strip positioned at the top of the battery frame, and the other end of each battery is connected with the second conducting strip positioned at the bottom of the battery frame;

the battery rack is characterized in that a limiting mechanism and a plurality of clamping mechanisms are arranged on one side face of the battery rack, the limiting mechanism is used for containing the circuit board in a clamping area, the circuit board is arranged on the clamping area and is clamped with the circuit board in a plurality of clamping mechanisms, and the clamping mechanisms are used for fixing the circuit board.

Further, the method also comprises the following steps: a plurality of first L-shaped conducting plates and a plurality of second L-shaped conducting plates; one end of the first L-shaped conducting strip is electrically connected with the first conducting strip, and the other end of the first L-shaped conducting strip is electrically connected with the circuit board; one end of the second L-shaped conducting strip is electrically connected with the second conducting strip, and the other two ends of the second L-shaped conducting strip are electrically connected with the circuit board.

Further, the first conducting strip and the second conducting strip are both nickel strips.

Further, stop gear includes: the circuit board comprises a plurality of limiting lugs and a plurality of limiting pieces, wherein the plurality of limiting pieces surround a clamping area which is used for accommodating the circuit board;

the limiting lugs are arranged in the clamping area, and one side face, far away from the battery rack, of each limiting lug is located on the same plane.

Further, the battery holder includes: a first battery holder and a second battery holder;

a plurality of first battery accommodating areas are arranged on the first battery frame in an array manner and used for accommodating one end of a battery, and a plurality of second battery accommodating areas are arranged on the second battery frame in an array manner and used for accommodating the other end of the battery; a first battery receiving area and a second battery receiving area are used for receiving a battery.

Furthermore, a plurality of first columns are arranged on the first battery rack, and a plurality of second columns are arranged on the second battery rack; one end of the first column, which is far away from the first battery rack, is connected with one end of the second column, which is far away from the second battery rack.

Further, the method also comprises the following steps: the first foam and the second foam; the first foam is arranged on one side, far away from the battery rack, of the first conducting strip; the second foam is arranged on one side, far away from the battery rack, of the second conducting strip, and the first foam and the second foam are used for protecting the first conducting strip and the second conducting strip respectively.

Different from the prior art, the technical scheme enables the circuit board to be fixed on the battery rack without screws through the arrangement of the limiting mechanism and the plurality of clamping mechanisms, so that the circuit board can be conveniently assembled and disassembled; because the step of locking the screw is reduced, the production efficiency is improved, and the production cost is reduced.

Drawings

Fig. 1 is an exploded view of a limit structure of a battery safety support frame applied to an energy storage power supply;

fig. 2 is a structural diagram of a limiting structure of the battery safety support frame applied to the energy storage power supply;

fig. 3 is a view showing the structure of the clamping area.

Description of reference numerals:

1. a battery holder; 2. a first conductive sheet; 3. a second conductive sheet; 4. a circuit board; 5. a limiting mechanism; 6. a clamping mechanism; 7. first foam; 8. second foam;

11. a first battery holder; 12. a first column; 13. a second battery holder; 14. a second column;

21. a first L-shaped conductive sheet;

31. a second L-shaped conductive sheet;

51. a clamping area; 52. a limiting bump; 53. and a limiting member.

Detailed Description

To explain technical contents, structural features, and objects and effects of the technical solutions in detail, the following detailed description is given with reference to the accompanying drawings in conjunction with the embodiments.

Referring to fig. 1 to 3, the present application discloses a limiting structure of a battery safety supporting frame applied to an energy storage power supply, comprising: the battery comprises a battery frame 1, a first conducting plate 2, a second conducting plate 3 and a circuit board 4; the first conducting plate 2 is arranged at the top of the battery frame 1, the second conducting plate 3 is arranged at the bottom of the battery frame 1, and the battery frame 1 is used for accommodating a plurality of batteries; one end of each battery is connected with the first conducting strip 2 positioned at the top of the battery frame 1, and the other end of each battery is connected with the second conducting strip 3 positioned at the bottom of the battery frame 1; be provided with stop gear 5 and a plurality of latch mechanism 6 on 1 side of battery rack, stop gear 5 is last to have and to be used for the holding 4 joint region 51 of circuit board, circuit board 4 is arranged in on the joint region 51, and a plurality of latch mechanism 6 with 4 joints of circuit board, latch mechanism 6 is used for fixing circuit board 4.

It should be noted that the battery rack 1 is used for accommodating multiple batteries arranged in an array; holes are formed in the battery rack 1 above and below each battery; the battery frame 1 is of a hexahedral structure, the top surface and the bottom surface of the battery frame 1 in the application are parallel to each other, the first conducting plate 2 is arranged on the top surface of the battery frame 1, and the second conducting plate 3 is arranged on the bottom surface of the battery frame 1; the first conducting plate 2 is electrically connected with a plurality of batteries through a plurality of through holes on the top of the battery rack 1, and the second conducting plate 3 is electrically connected with a plurality of batteries through a plurality of through holes on the bottom of the battery rack 1 in the same way.

It should be further noted that a limiting mechanism 5 is arranged on one side face of the battery rack 1, the limiting mechanism 5 is used for placing the circuit board 4, specifically, a clamping area 51 is arranged on the limiting mechanism 5, the circuit board 4 is arranged in the clamping area 51, and the area size of the clamping area 51 is matched with the area size of the circuit board 4. Specifically, in this application, circuit board 4 is preferred square, i.e., joint region 51 also is square structure, just stop gear 5 is in be provided with L type spacing unit on four angles of circuit board 4, make four angles of circuit board 4 are arranged in on the L type spacing unit.

It should be further noted that a plurality of the clamping mechanisms 6 are disposed in the clamping area 51, or a plurality of the clamping mechanisms 6 are disposed at intervals along the edge of the clamping area 51, and when the circuit board 4 is disposed in the clamping area, the circuit board 4 is clamped on the battery holder 1 through the clamping mechanisms 6.

Specifically, as a plurality of 6 edges of latch mechanism when the regional 51 settings of joint, latch mechanism 6 includes head rod and first lug, and the head rod is around following the regional 51 marginal intervals of joint set up, and the head rod is arranged in to first lug and is kept away from the one end of battery holder 1, and first lug court the regional 51 extensions of joint, the one end that the head rod was kept away from to first lug are provided with the chamfer angle, and the circuit board 4 of being convenient for slides in. Of course, in other embodiments, the clamping mechanism 6 includes a second protrusion and a second connecting rod, the second connecting rod can be placed at any position in the clamping area 51, and the circuit board 4 will be provided with a through hole at a corresponding position, one end of the second connecting rod away from the battery rack 1 is provided with the second protrusion, and the frame width of the second protrusion is greater than the aperture of the clamping through hole.

According to the technical scheme, the limiting mechanism 5 and the clamping mechanisms 6 are arranged, so that the circuit board 4 can be fixed on the battery rack 1 without screws, and the circuit board 4 can be conveniently assembled and disassembled; because the step of locking the screw is reduced, the production efficiency is improved, and the production cost is reduced.

Referring to fig. 2, in order to make the circuit board 4 and the battery rack 1 more firmly connected, in this embodiment, the method further includes: a plurality of first L-shaped conductive sheets 21 and a plurality of second L-shaped conductive sheets 31; one end of the first L-shaped conducting strip 21 is electrically connected to the first conducting strip 2, and the other end is electrically connected to the circuit board 4; one end of the second L-shaped conductive plate 31 is electrically connected to the second conductive plate 3, and the other end is electrically connected to the circuit board 4. In certain embodiments, the first conductive sheet 2 and the second conductive sheet 3 are both nickel strips. Some of the first L-shaped conductive sheets 21 and the second L-shaped conductive sheets 31 in fig. 1 to 3 are not yet folded.

It should be noted that, the first L-shaped conductive plate 21 and the second L-shaped conductive plate 31 have the same structural material, and the connection manner between the first L-shaped conductive plate 21 and the first conductive plate 2 is the same as the connection manner between the second L-shaped conductive plate 31 and the second conductive plate 3, and the connection manner between the first L-shaped conductive plate 21 and the circuit board 4 is the same as the connection manner between the second L-shaped conductive plate 31 and the circuit board 4; the first L-shaped conductive sheet 21 will be exemplified hereinafter.

Specifically, one end of the first L-shaped conductive plate 21 is connected to the first conductive plate 2, the other end of the first L-shaped conductive plate 21 is connected to the circuit board 4, and the right angle of the first L-shaped conductive plate 21 is overlapped on the right angle of the battery holder 1, so as to connect the first conductive plate 2 and the circuit board 4; meanwhile, the first L-shaped conductive plate 21 may further fix the circuit board 4 to the battery holder 1.

It should be further noted that the first conductive plate 2 may be multiple pieces, and each piece of the first conductive plate 2 is connected to one first L-shaped conductive plate 21 and connected to the circuit board 4.

Referring to fig. 1 and 3, in this embodiment, the limiting mechanism 5 includes: the circuit board comprises a plurality of limiting bumps 52 and a plurality of limiting pieces 53, the limiting pieces 53 surround a clamping area 51, and the clamping area 51 is used for accommodating the circuit board 4; the plurality of limiting lugs 52 are arranged in the clamping area 51, and the plurality of limiting lugs 52 are far away from one side surface of the battery rack 1 and are positioned on the same plane.

It should be noted that the plurality of limiting protrusions 52 are fixedly disposed on the battery rack 1, and a side surface of the plurality of limiting protrusions 52 away from the battery rack 1 is flush; that is, a side surface of the plurality of limiting protrusions 52 away from the battery rack 1 is located on the same virtual plane, and the virtual plane is perpendicular to the horizontal plane. Specifically, when the side surface of the battery holder 1 is uneven, the limiting bump 52 lifts the circuit board 4 away from the battery holder 1 in order to place the circuit board 4 on a flat surface.

Referring to fig. 1, in order to protect the first conductive plate 2 and the second conductive plate 3, in this embodiment, the method further includes: a first foam 7 and a second foam 8; the first foam 7 is arranged on one side of the first conducting strip 2 far away from the battery frame 1; the second foam 8 is arranged on one side, far away from the battery rack 1, of the second conducting plate 3, and the first foam 7 and the second foam 8 are respectively used for protecting the first conducting plate 2 and the second conducting plate 3. It should be noted that the first foam 7 is adhered to one side of the first conductive sheet 2 away from the battery rack 1, and the first foam 7 is connected to the battery rack 1 through a gap in the first conductive sheet 2; the second foam 8 works in the same way.

When the first conducting strip 2 is impacted by external force, the first foam 7 buffers the force, and the impact force on the first conducting strip 2 is reduced; if the first conducting plate 2 is deformed by a force, the first conducting plate 2 is fixed on the battery frame 1 by the first foam 7, and the deformation of the first conducting plate 2 is limited by the first foam 7. Of course, in some implementations the first and second foam sheets 7, 8 also serve to prevent oxidation of the first and second conductive sheets 2, 3.

Referring to fig. 1 to 3, in this embodiment, the battery rack 1 includes: a first battery holder 11 and a second battery holder 13;

a plurality of first battery accommodating areas are arranged on the first battery frame 11 in an array manner and used for accommodating one end of a battery, and a plurality of second battery accommodating areas are arranged on the second battery frame 13 in an array manner and used for accommodating the other end of the battery; a first battery accommodation region and a second battery accommodation region are used for accommodating a battery. It should be noted that the first battery rack 11 and the second battery rack 13 have the same structure, and therefore the first battery rack 11 will be taken as an example for description in this embodiment. Specifically, the first battery rack 11 and the second battery rack 13 are adapted to each other and used for fixing a plurality of batteries, wherein one first battery accommodating area is combined with one second battery accommodating area and used for accommodating one battery; the first battery accommodating area is arranged at one end of the battery, and the second battery accommodating area is arranged at the other end of the battery; therefore, the number of the first battery receiving regions is the same as the number of the second battery receiving regions.

Referring to fig. 1 to 3, in the present embodiment, a plurality of first columns 12 are disposed on the first battery rack 11, and a plurality of second columns 14 are disposed on the second battery rack 13; the end of the first column 12 away from the first battery holder 11 is connected to the end of the second column 14 away from the second battery holder 13.

It should be noted that the plurality of first columns 12 on the first battery rack 11 are integrally formed with the first battery rack 11; similarly, the second columns 14 on the second battery rack 13 are integrally formed with the second battery rack 13; the first battery frame 11 and the second battery frame 13 are connected through a first column 12 and a second column 14; specifically, one end of the first column 12, which is far away from the first battery rack 11, is connected to one end of the second column 14, which is far away from the first battery rack 11. Therefore, the number of the first columns 12 is the same as that of the second columns 14, and in the present application, the first columns 12 are disposed opposite to the second columns 14. Further, since the battery is a cylinder, there will be gaps between the batteries, and the first column 12 can be placed in the gaps between the first battery receiving areas. It should also be noted that the first column 12 and the second column 14 are at the same height.

It should be noted that, although the above embodiments have been described herein, the scope of the present invention is not limited thereby. Therefore, based on the innovative concepts of the present invention, the technical solutions of the present invention can be directly or indirectly applied to other related technical fields by changing and modifying the embodiments described herein or by using the equivalent structures or equivalent processes of the content of the present specification and the attached drawings, and are included in the scope of the present patent.

Claims (7)

1. The utility model provides a be applied to battery safety support frame's of energy storage power limit structure which characterized in that includes: the battery comprises a battery frame, a first conducting plate, a second conducting plate and a circuit board;

the first conducting strip is arranged at the top of the battery frame, the second conducting strip is arranged at the bottom of the battery frame, and the battery frame is used for accommodating a plurality of batteries; one end of each battery is connected with the first conducting strip positioned at the top of the battery rack, and the other end of each battery is connected with the second conducting strip positioned at the bottom of the battery rack;

the battery rack is characterized in that a limiting mechanism and a plurality of clamping mechanisms are arranged on one side face of the battery rack, a clamping area used for containing the circuit board is arranged on the limiting mechanism, the circuit board is arranged on the clamping area, the clamping mechanisms are clamped with the circuit board, and the clamping mechanisms are used for fixing the circuit board.

2. The limit structure of claim 1, further comprising: a plurality of first L-shaped conducting strips and a plurality of second L-shaped conducting strips; one end of the first L-shaped conducting strip is electrically connected with the first conducting strip, and the other end of the first L-shaped conducting strip is electrically connected with the circuit board; one end of the second L-shaped conducting strip is electrically connected with the second conducting strip, and the other end of the second L-shaped conducting strip is electrically connected with the circuit board.

3. The limit structure of the battery safety support frame applied to the energy storage power supply of claim 1, wherein the first conducting strip and the second conducting strip are both nickel strips.

4. The limit structure of the battery safety support frame applied to the energy storage power supply according to claim 1, wherein the limit structure comprises: the circuit board comprises a plurality of limiting lugs and a plurality of limiting pieces, wherein the plurality of limiting pieces surround a clamping area which is used for accommodating the circuit board;

the limiting lugs are arranged in the clamping area, and one side face, far away from the battery rack, of each limiting lug is located on the same plane.

5. The limit structure of the battery safety support frame applied to the energy storage power supply according to claim 1, wherein the battery frame comprises: a first battery holder and a second battery holder;

a plurality of first battery accommodating areas are arranged on the first battery rack in an array manner, the first battery accommodating areas are used for accommodating one ends of batteries, a plurality of second battery accommodating areas are arranged on the second battery rack in an array manner, and the second battery accommodating areas are used for accommodating the other ends of the batteries; a first battery receiving area and a second battery receiving area are used for receiving a battery.

6. The limit structure of the battery safety support frame applied to the energy storage power supply of claim 5, wherein a plurality of first columns are arranged on the first battery frame, and a plurality of second columns are arranged on the second battery frame; one end of the first column, which is far away from the first battery rack, is connected with one end of the second column, which is far away from the second battery rack.

7. The limit structure of claim 1, further comprising: the first foam and the second foam; the first foam is arranged on one side, far away from the battery rack, of the first conducting strip; the second foam is arranged on one side, far away from the battery rack, of the second conducting strip, and the first foam and the second foam are used for protecting the first conducting strip and the second conducting strip respectively.

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