CN219180667U - Connection structure suitable for expansion reaction of battery - Google Patents

Abstract

The utility model discloses a connecting structure suitable for an expansion reaction of a battery, and relates to the technical field of carbon batteries. The utility model includes; installing a module; the movable modules are connected to the mounting modules and are symmetrically arranged in a group; the adaptive connection module is connected to the installation module for connecting the batteries; the adaptive connection module comprises a connection plate, a plurality of connection grooves which are equidistantly formed in the middle of the connection plate, and a connection piece which is arranged in any one of the connection grooves; also comprises; the rapid cooling module is connected to the installation module and is symmetrically arranged in a group. The utility model solves the problems that the centralized connection structure of the existing carbon batteries is generally a single connection plate and is matched with a plurality of connection holes so as to realize centralized connection and placement of the plurality of carbon batteries, but the internal space of the connection holes is not adjustable, and the applicability is insufficient after the carbon batteries are expanded.

Description

Connection structure suitable for expansion reaction of battery

Technical Field

The utility model relates to the technical field of carbon batteries, in particular to a connecting structure suitable for an expansion reaction of a battery.

Background

Carbon batteries are known as: a neutral zinc-manganese dioxide dry battery belongs to a primary battery in a chemical power supply, is a disposable battery, and in the use of a plurality of carbon batteries, a connecting structure for centralized connection is needed.

However, the following drawbacks still exist in practical use:

the existing centralized connection structure of the carbon batteries is generally a single connection plate and is matched with a plurality of connection holes formed in the connection structure to realize centralized connection and placement of the plurality of carbon batteries, but the inner space of the formed connection holes is not adjustable, and after the carbon batteries expand, the applicability is insufficient.

Therefore, the requirements in practical use cannot be met, so there is an urgent need in the market for improved techniques to solve the above problems.

Disclosure of Invention

The utility model aims to provide a connecting structure for adapting to expansion reaction of a battery, which solves the problems that the centralized connecting structure of the traditional carbon battery is generally a single connecting plate and is matched with a plurality of connecting holes so as to realize centralized connection and placement of a plurality of carbon batteries, but the internal space of the connecting holes is not adjustable and the applicability is insufficient after the carbon batteries are expanded by arranging an adapting connecting module.

In order to solve the technical problems, the utility model is realized by the following technical scheme:

the utility model is a connection structure for adapting to an expansion reaction of a battery, comprising;

installing a module;

the movable modules are connected to the mounting modules and are symmetrically arranged in a group;

the adaptive connection module is connected to the installation module for connecting the batteries;

the adaptive connection module comprises a connection plate, a plurality of connection grooves which are equidistantly formed in the middle of the connection plate, and a connection piece which is arranged in any one connection groove;

also comprises;

the rapid cooling module is connected to the installation module and is symmetrically arranged in a group.

Further, any one of the connecting pieces comprises two groups of connecting blocks, a plurality of telescopic springs which are equidistantly connected to the front ends of the connecting blocks and a plurality of adapting plates which are connected to the front ends of the telescopic springs;

any connecting block is clamped in an opening formed in the inner side wall of the corresponding connecting groove;

specifically, through a plurality of expansion springs, structure connection between the connecting block and the adapting plate is carried out, and through the space formed by the inner sides of the two groups of adapting plates and the interference force exerted by the expansion springs, stable connection of the embedded battery can be carried out, and meanwhile, the elastic force of the expansion springs can be used for stable connection of the expanded battery.

Further, damping force exists between the side edge of any one connecting block and the inner side wall of the opening, and the upper part of the connecting block extends out of the opening.

Specifically, the damping force ensures the stability of the structure of the connecting block, and the force required by the disassembly and assembly of the connecting block can be easily applied by controlling the structure of the upper part of the connecting block.

Further, the installation module comprises an installation frame and a group of positioning plates symmetrically connected to the front and rear lower parts of the installation frame;

wherein, the front end part of any one of the positioning plates is a positioning hole which is penetrated and opened;

wherein the connecting plate is arranged in the mounting frame;

specifically, the mounting frame can bear the connecting plate, positioning bolts are placed in the positioning holes, and after tightening, the device is integrally and stably processed through the stabilized positioning plate.

Further, any one of the movable modules comprises a group of symmetrical support blocks and a movable plate connected to the inner side of the group of support blocks through a threaded column;

wherein, the end part of the thread column is provided with a threaded nut;

specifically, the screw thread post can carry out the fastening connection between the support block and the movable plate under the locking of the matched nut to the angle adjustment can be carried out on the movable plate by applying the unscrewing force to the nut, so that the end part of the connecting plate is exposed, the structure can be easily controlled, and the force is applied during self disassembly and assembly.

Further, rectangular openings are formed in the front and rear upper portions of the mounting frame in a penetrating mode, and round holes are formed in the upper portions of two sides of the mounting frame in a penetrating mode;

wherein, the end part of the movable plate and the inner side wall of the rectangular opening are arranged in a relatively flat way;

specifically, the rectangular opening provides a movable space for the handle to be controlled for assembling and disassembling the connecting plate, and the round hole receives a temperature sensor described below.

Further, any one of the rapid cooling modules comprises a temperature sensor arranged in the corresponding round hole, a hollow block connected to the lower part of one side of the mounting frame and a connecting pipe penetrating through the middle part of one end of the hollow block;

wherein, one side of the upper end of the connecting pipe is penetrated with an electromagnetic valve and is connected with an external liquid nitrogen conveying pipe;

wherein, the inner side surface of the hollow block is provided with holes which are equidistantly and penetratingly arranged;

specifically, the temperature sensor is controlled to detect the temperature of a plurality of carbon batteries in use, and the external liquid nitrogen can be accessed under the state that the electromagnetic valve is opened through the connecting pipe, so that the high-temperature rapid cooling treatment is performed, and the safety use of the carbon batteries is easy.

Further, a group of protruding blocks are connected to the end parts of the inner sides of the hollow blocks, are rectangular and are connected in a clamping mode in rectangular grooves formed in corresponding positions of the mounting frames;

specifically, the lug is connected with the rectangular groove in a clamping way, and the structure is fastened and installed between the hollow block and the mounting frame.

The utility model has the following beneficial effects:

according to the utility model, two groups of adapter plates are additionally arranged in the connecting groove and are connected through the telescopic spring, on one hand, the telescopic spring can form an abutting force to the battery arranged on the inner side of the adapter plate by means of self elastic force, so that the battery is in a stable connection state, on the other hand, the battery can be stably connected by means of elastic force again, and the expanded carbon battery can be adapted to be used easily;

meanwhile, a group of hollow blocks are additionally arranged, external liquid nitrogen can be accessed through a connecting pipe, so that after the temperature sensor is used for detecting the overhigh temperature, the rapid cooling treatment of the high-temperature environment is performed, the battery is in a safe use environment, and the occurrence probability of risks is reduced.

Of course, it is not necessary for any one product to practice the utility model to achieve all of the advantages set forth above at the same time.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present utility model, the drawings that are needed for the description of the embodiments will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the present utility model, and that other drawings may be obtained according to these drawings without inventive effort for a person skilled in the art.

FIG. 1 is an external view of the present utility model;

FIG. 2 is a block diagram of an adapter module according to the present utility model;

FIG. 3 is a block diagram of a rapid cooling module according to the present utility model;

fig. 4 is a connection diagram of the installation module and the movable module of the present utility model.

In the drawings, the list of components represented by the various numbers is as follows:

100. installing a module; 110. a mounting frame; 120. a positioning plate; 200. a movable module; 210. a support block; 220. a threaded column; 230. a movable plate; 300. adapting the connection module; 310. a connecting plate; 320. a connecting groove; 330. a connecting piece; 331. a connecting block; 332. a telescopic spring; 333. an adapter plate; 400. a rapid cooling module; 410. a temperature sensor; 420. a hollow block; 430. connecting pipe; 440. and a bump.

Detailed Description

The technical solutions in the embodiments of the present utility model will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present utility model.

Example 1

Referring to fig. 2, the present embodiment is a connection structure for adapting an expansion reaction of a battery, including;

an adapter module 300 connected to the mounting module 100 for connecting the battery;

the adaptive connection module 300 comprises a connection plate 310, a plurality of connection grooves 320 equidistantly formed in the middle of the connection plate 310, and a connection piece 330 arranged in any one of the connection grooves 320;

any one of the connecting pieces 330 comprises two groups of connecting blocks 331, a plurality of telescopic springs 332 equidistantly connected to the front ends of the connecting blocks 331, and a plurality of adapting plates 333 connected to the front ends of the telescopic springs 332;

wherein, any connecting block 331 is clamped in an opening formed on the inner side wall of the corresponding connecting groove 320;

damping force exists between the side edge of any connecting block 331 and the inner side wall of the opening, and the upper part of the connecting block 331 extends out of the opening;

connecting the carbon batteries, placing the connecting plate 310 in the mounting frame 110 in advance, and applying a rotating force to a group of movable plates 230 to enable the inner side walls of the movable plates 230 to abut against the end parts of the connecting plate 310 under the rotation of the threads, and locking nuts at the end parts of the threaded columns 220;

at this time, the corresponding connection block 331 is placed in the corresponding connection groove 320, so that the connection block 331 is in a stable state by the damping force of the inner side of the opening;

then, sequentially placing a corresponding number of carbon batteries in the connecting groove 320, compressing the telescopic spring 332 in advance, so that the carbon batteries smoothly enter the space inside the adapting plate 333, subsequently recovering deformation, applying an abutting force to the carbon batteries, and enabling the carbon batteries to be in a stable state, namely completing connection of a plurality of carbon batteries;

when the expansion reaction of the carbon battery occurs, the expansion spring 332 compresses itself again by virtue of the elastic force of the expansion spring, and the recovery deformation is performed again, as in the above steps, namely, the expansion reaction of the carbon battery is adapted. Example 2

Referring to fig. 3, the method further includes;

the rapid cooling module 400 is connected to the installation module 100 and is symmetrically arranged for a group;

any one of the rapid cooling modules 400 includes a temperature sensor 410 disposed in a corresponding circular hole, a hollow block 420 connected to a lower portion of one side of the mounting frame 110, and a connection pipe 430 penetrating a middle portion of one end of the hollow block 420;

wherein, one side of the upper end of the connecting pipe 430 is penetrated with an electromagnetic valve and is connected with an external liquid nitrogen delivery pipe;

wherein, the inner side surface of the hollow block 420 is provided with holes which are equidistantly penetrated;

the inner end of the hollow block 420 is connected with a group of protruding blocks 440, and the protruding blocks 440 are rectangular and are connected in a clamping way in rectangular grooves formed in corresponding positions of the mounting frame 110;

detecting the working environment of the carbon battery, and detecting the temperature by extending the temperature sensor 410 to a detection end in the connecting plate 310;

after the battery at high temperature is rapidly cooled by the temperature sensor 410, the electromagnetic valve is in an opened state, and is connected with external liquid nitrogen through the connecting pipe 430, and is contacted with the mounting frame 110 through the plurality of holes on the inner side by the hollow block 420, and the cold air is transferred to the connecting plate 310, so that the rapid cooling of the battery is completed.

In the description of the present utility model, it should also be noted that, unless explicitly specified and limited otherwise, the terms "disposed," "mounted," "connected," and "connected" are to be construed broadly, and may be, for example, fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; can be directly connected or indirectly connected through an intermediate medium, and can be communication between two elements. The specific meaning of the above terms in the present utility model can be understood by those of ordinary skill in the art according to the specific circumstances.

Finally, it should be noted that: the foregoing description is only a preferred embodiment of the present utility model, and the present utility model is not limited thereto, but it is to be understood that modifications and equivalents of some of the technical features described in the foregoing embodiments may be made by those skilled in the art, although the present utility model has been described in detail with reference to the foregoing embodiments. Any modification, equivalent replacement, improvement, etc. made within the spirit and principle of the present utility model should be included in the protection scope of the present utility model.

Claims (8)

1. A connection structure adapted to an expansion reaction of a cell, characterized by;

comprises the following steps of;

a mounting module (100);

the movable module (200) is connected to the installation module (100) and is symmetrically arranged in a group;

an adaptive connection module (300) connected to the mounting module (100) for connecting the batteries;

the adaptive connection module (300) comprises a connection plate (310), a plurality of connection grooves (320) which are equidistantly formed in the middle of the connection plate (310) and connection pieces (330) which are arranged in any one of the connection grooves (320);

also comprises;

the rapid cooling module (400) is connected to the mounting module (100) and is symmetrically arranged for a group.

2. A connection structure for adapting cell expansion reaction according to claim 1, characterized in that any one of the connection members (330) comprises two sets of connection blocks (331), a plurality of expansion springs (332) equidistantly connected to the front ends of the connection blocks (331), and a plurality of adapting plates (333) connected to the front ends of the expansion springs (332);

any connecting block (331) is clamped in an opening formed in the inner side wall of the corresponding connecting groove (320).

3. A connection structure for adapting to the expansion reaction of a cell according to claim 2, characterized in that a damping force exists between the side edge of any one of the connection blocks (331) and the inner side wall of the opening, and the upper portion of the connection block (331) extends out of the opening.

4. A connection structure for adapting an expansion reaction of a battery according to claim 3, wherein the mounting module (100) comprises a mounting frame (110) and a set of positioning plates (120) symmetrically connected to front and rear lower portions of the mounting frame (110);

wherein, the front end part of any one positioning plate (120) is a positioning hole which is penetrated and opened;

wherein, the connecting plate (310) is arranged in the mounting frame (110).

5. The connection structure for adapting an expansion reaction of a battery according to claim 4, wherein any one of the movable modules (200) comprises a set of symmetrical support blocks (210) and a movable plate (230) connected to the inside of the set of support blocks (210) through a screw column (220);

wherein the end of the threaded post (220) is provided with a threaded nut.

6. The connection structure for adapting to the expansion reaction of a battery according to claim 5, wherein the front and rear upper portions of the mounting frame (110) have rectangular openings formed therethrough, and the upper portions of both sides of the mounting frame (110) have circular holes formed therethrough;

wherein, the end of the movable plate (230) is arranged in a relatively flat way with the inner side wall of the rectangular opening.

7. The connection structure for adapting to an expansion reaction of a battery according to claim 6, wherein any one of the rapid cooling modules (400) comprises a temperature sensor (410) disposed in a corresponding circular hole, a hollow block (420) connected to a lower portion of one side of the mounting frame (110), and a connection pipe (430) penetrating a middle portion of one end of the hollow block (420);

wherein, one side of the upper end of the connecting pipe (430) is penetrated with an electromagnetic valve and is connected with an external liquid nitrogen conveying pipe;

wherein, the inner side surface of the hollow block (420) is provided with holes which are penetrated and opened at equal intervals.

8. The connection structure for adapting to the expansion reaction of the battery according to claim 7, wherein a set of protrusions (440) are connected to the inner end of the hollow block (420), and the protrusions (440) are rectangular and are connected to rectangular grooves formed in corresponding positions of the mounting frame (110) in a clamping manner.

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