CN210092256U - Formation clamp for silicon-carbon cathode battery - Google Patents

Abstract

The utility model discloses a formation anchor clamps of silicon carbon negative pole battery belongs to silicon carbon negative pole battery technical field. The utility model discloses a battery box, solid fixed splint and flexible splint, battery box top evenly seted up the battery standing groove, first electric telescopic handle is installed to one side of battery standing groove inner wall, the welding of first electric telescopic handle's flexible end has solid fixed splint, battery standing groove inner wall all seted up the spout, the inside slip cover of spout is equipped with flexible splint, one side welding of flexible splint have second electric telescopic handle, the outer wall of battery box have the singlechip through bolt fixed mounting. The utility model discloses a flexible splint can stretch out and draw back in the battery standing groove, and cooperation solid fixed splint can fix multiple volume and the battery of size, can wrap up the battery after the gasbag is aerifyd, and the increase becomes the area of contact of anchor clamps and battery, prevents not hard up, has improved the practicality and the stability that become anchor clamps.

Description

Formation clamp for silicon-carbon cathode battery

Technical Field

The utility model relates to a silicon carbon negative pole battery technical field, more specifically say, relate to a formation anchor clamps of silicon carbon negative pole battery.

Background

In recent years, the lithium ion battery industry in China is rapidly developed, the global market share is continuously increased, and the demand of the lithium ion battery cathode material is continuously increased under the drive of large-scale lithium ion battery industry investment. Silicon cathodes have higher mass and volume energy densities than graphite cathodes. Silicon carbon negative electrode batteries have also been used in various fields, and the silicon carbon negative electrode batteries charge and discharge secondary batteries during the production process, which are also called battery formation. The battery is fixed by a clamp during formation, but the existing formation clamp of the silicon-carbon cathode battery has some defects in the use process. 1. The existing formation clamp for the silicon-carbon cathode battery can only fix batteries with corresponding volumes and sizes generally, and cannot fix batteries with different volumes and sizes. 2. The formation clamp of the existing silicon-carbon cathode battery has different fixing force to the battery, the surface of the battery can be abraded due to overlarge force, the battery can be loosened when the battery is formed due to undersize force, and the trouble in battery formation is increased.

SUMMERY OF THE UTILITY MODEL

1. Technical problem to be solved by the utility model

An object of the utility model is to overcome prior art not enough, provide a silicon carbon negative pole battery's formation anchor clamps, the utility model discloses a flexible splint cooperation solid fixed splint can carry out the one-to-one to the battery of multiple volume and size, can wrap up the battery after the gasbag is aerifyd, increases the area of contact of formation anchor clamps and battery, has improved the practicality of formation anchor clamps.

2. Technical scheme

In order to achieve the above purpose, the utility model provides a technical scheme does:

the utility model discloses a formation anchor clamps of silicon carbon negative pole battery, including battery box, solid fixed splint and flexible splint, battery box top evenly seted up the battery standing groove, one side of battery standing groove inner wall is installed first electric telescopic handle through bolt fastening, the flexible end welding of first electric telescopic handle has solid fixed splint, the both sides of solid fixed splint contact with battery standing groove inner wall, solid fixed splint deviate from one side of first electric telescopic handle and install first pressure sensor through bolt fastening, one side of solid fixed splint, battery standing groove inner wall all seted up the spout, slide between the adjacent spout and overlap flexible splint, one side welding of flexible splint have the second electric telescopic handle, the second electric telescopic handle is installed in the battery standing groove through bolt fastening, the opposite side of flexible splint is installed the second pressure sensor through bolt fastening, the outer wall of battery box pass through bolt fixed mounting and have the singlechip, the signal output part of first pressure sensor, second pressure sensor and the signal input part electric connection of singlechip, the signal output part of singlechip respectively with first electric telescopic handle, second electric telescopic handle electric connection.

Furthermore, rubber pads are bonded on the surfaces of the fixed clamping plate and the telescopic clamping plate, and the first pressure sensor and the second pressure sensor are embedded in the rubber pads.

Furthermore, one side of the fixed splint departing from the first electric telescopic rod is provided with symmetrically distributed grooves.

Furthermore, a rubber rope is bonded in the groove, an air bag is bonded at one end of the rubber rope, and the air bag is sleeved in the groove.

Further, the outer wall of the battery box is uniformly provided with round holes, an air pump is fixedly arranged in the round holes through bolts, and the output end of the air pump is communicated with the air bag through a folding air pipe.

Furthermore, the single chip microcomputer and the air pump are electrically connected with an external power supply.

3. Advantageous effects

Adopt the technical scheme provided by the utility model, compare with prior art, have following beneficial effect:

the utility model can clamp the battery between the fixed clamp plate, the telescopic clamp plate and the battery box after the first electric telescopic rod and the second electric telescopic rod are stretched, the first pressure sensor and the second pressure sensor can transmit pressure information to the singlechip after contacting the battery, the singlechip controls the extension or the shortening of the two electric telescopic rods according to internal programming, the strength of the battery fixed by the formed clamp is maintained in normal strength, the battery surface is prevented from being worn due to overlarge strength, the battery formed by undersize strength can be loosened when formed, the applicability of the formed clamp is improved, the telescopic clamp plate can be stretched in the battery placing groove, the batteries with various sizes and volumes can be fixed one by matching with the fixed clamp plate, when some batteries with strange shapes are encountered, the air pump can inflate the air bag through the folding air pipe, the air bag can wrap the battery after being inflated, the increase becomes the area of contact of anchor clamps and battery, and flexible splint of cooperation and solid fixed splint can be fixed the battery, prevent not hard up between anchor clamps and the battery, and the rubber pad is convenient for two sensitive accepted pressure information of pressure sensor and not crushed by the pressure, has improved the practicality that becomes anchor clamps.

Drawings

Fig. 1 is a top view of the battery box of the present invention;

FIG. 2 is a top sectional view of the partial structure of the present invention;

fig. 3 is an enlarged view of the structure a in fig. 2 according to the present invention;

fig. 4 is a side view of the fixing splint of the present invention;

fig. 5 is a schematic circuit diagram of the present invention.

In the figure: 101. a battery box; 102. a single chip microcomputer; 103. a battery placement groove; 104. an air pump; 201. fixing the clamping plate; 202. a chute; 203. a first pressure sensor; 204. a first electric telescopic rod; 205. a groove; 206. a bungee cord; 207. an air bag; 301. a retractable splint; 302. a rubber pad; 303. a second pressure sensor; 304. and the second electric telescopic rod.

Detailed Description

The invention is further described with reference to the following figures and examples:

example 1

As can be seen from fig. 1 to 5, the formation fixture for silicon-carbon negative electrode batteries of the present embodiment comprises a battery box 101, a fixing clamp plate 201 and a telescopic clamp plate 301, wherein the top of the battery box 101 is uniformly provided with a battery placement groove 103, one side of the inner wall of the battery placement groove 103 is fixedly provided with a first electric telescopic rod 204 through a bolt, the telescopic end of the first electric telescopic rod 204 is welded with the fixing clamp plate 201, two sides of the fixing clamp plate 201 are in contact with the inner wall of the battery placement groove 103, so that the fixing clamp plate 201 can fix some flexible batteries, one side of the fixing clamp plate 201 away from the first electric telescopic rod 204 is fixedly provided with a first pressure sensor 203 through a bolt, one side of the fixing clamp plate 201 and the inner wall of the battery placement groove 103 are both provided with sliding grooves 202, the telescopic clamp plate 301 is slidably sleeved between the adjacent sliding grooves 202, the telescopic clamp plate 301 is composed of, second electric telescopic handle 304 passes through bolt fixed mounting and is inboard at battery standing groove 103, there is second pressure sensor 303 the opposite side of flexible splint 301 through bolt fixed mounting, second electric telescopic handle 304 all fixes at flexible splint 301 lagging end with second pressure sensor 303, there is singlechip 102 the outer wall of battery box 101 through bolt fixed mounting, first pressure sensor 203, the signal output part of second pressure sensor 303 and the signal input part electric connection of singlechip 102, singlechip 102's signal output part respectively with first electric telescopic handle 204, second electric telescopic handle 304 electric connection.

Rubber pads 302 are respectively bonded on the surfaces of the fixed splint 201 and the telescopic splint 301, the first pressure sensor 203 and the second pressure sensor 303 are respectively embedded in the rubber pads 302, the rubber pads 302 enable the first pressure sensor 203 and the second pressure sensor 303 to sensitively receive pressure information and not to be crushed, one side of the fixed splint 201 away from the first electric telescopic rod 204 is provided with symmetrically distributed grooves 205, rubber ropes 206 are bonded in the grooves 205, one end of each rubber rope 206 is bonded with an air bag 207, one side of each air bag 207 is provided with an exhaust hole which is smaller, the rubber ropes 206 can be pulled back to the air bags 207 after exhaust, the air bags 207 are sleeved inside the grooves 205, the outer wall of the battery box 101 is uniformly provided with round holes, air pumps 104 are fixedly mounted in the round holes through bolts, the output ends of the air pumps 104 are communicated with the air bags 207 through folding air pipes, the single chip microcomputer 102 and the air, singlechip 102's model is the field fire and inherits fire STM32 development board, and singlechip 102 is prior art, and accessible WIFI is connected with cell-phone APP, and singlechip 102 controls two electric telescopic handle's extension or shortening according to internal programming.

The utility model discloses a first electric telescopic handle 204 and second electric telescopic handle 304 flexible back, can clamp the battery between solid fixed splint 201, flexible splint 301 and battery box 101, first pressure sensor 203 and second pressure sensor 303 can transmit pressure information to singlechip 102 after contacting the battery, singlechip 102 controls the extension or shortening of two electric telescopic handles according to internal programming, make the dynamics of becoming the fixed battery of anchor clamps maintain in normal dynamics, prevent that too big power from making the battery surface produce wearing and tearing, the dynamics can become flexible when the battery formation of dynamics undersize, the suitability of becoming anchor clamps is improved, flexible splint 301 can stretch out and draw back in battery standing groove 103, cooperation solid fixed splint 201 can be fixed one by one to the battery of multiple volume and size, when meeting some battery of strange shape, air pump 104 can inflate gasbag 207 through folding trachea, the gasbag 207 can wrap up the battery after aerifing, increases the area of contact who becomes anchor clamps and battery, and cooperation flexible splint 301 and solid fixed splint 201 can be fixed the battery, prevents not hard up between anchor clamps and the battery, and rubber pad 302 is convenient for two sensitive accepted pressure information of pressure sensor and is not crushed by the pressure, has improved the practicality that becomes anchor clamps.

The present invention and its embodiments have been described above schematically, and the description is not limited thereto, and what is shown in the drawings is only one of the embodiments of the present invention, and the actual structure is not limited thereto. Therefore, if the person skilled in the art receives the teaching of the present invention, without departing from the inventive spirit of the present invention, the person skilled in the art should also design the similar structural modes and embodiments without creativity to the technical solution, and all shall fall within the protection scope of the present invention.

Claims (6)

1. The utility model provides a formation anchor clamps of silicon carbon negative pole battery, includes battery box (101), solid fixed splint (201) and flexible splint (301), its characterized in that: the battery box is characterized in that a battery placing groove (103) is uniformly formed in the top of the battery box (101), a first electric telescopic rod (204) is fixedly installed on one side of the inner wall of the battery placing groove (103) through a bolt, a fixing clamp plate (201) is welded at the telescopic end of the first electric telescopic rod (204), two sides of the fixing clamp plate (201) are in contact with the inner wall of the battery placing groove (103), a first pressure sensor (203) is fixedly installed on one side, away from the first electric telescopic rod (204), of the fixing clamp plate (201), sliding grooves (202) are formed in the inner wall of the battery placing groove (103), a telescopic clamp plate (301) is slidably sleeved between the adjacent sliding grooves (202), a second electric telescopic rod (304) is welded on one side of the telescopic clamp plate (301), and the second electric telescopic rod (304) is fixedly installed on the inner side of the battery placing groove (103) through a bolt, the other side of flexible splint (301) has second pressure sensor (303) through bolt fixed mounting, the outer wall of battery box (101) have singlechip (102) through bolt fixed mounting, the signal output part of first pressure sensor (203), second pressure sensor (303) and the signal input part electric connection of singlechip (102), the signal output part of singlechip (102) respectively with first electric telescopic handle (204), second electric telescopic handle (304) electric connection.

2. The forming clamp of the silicon-carbon negative electrode battery as claimed in claim 1, wherein: the plate surfaces of the fixed clamping plate (201) and the telescopic clamping plate (301) are respectively bonded with a rubber pad (302), and the first pressure sensor (203) and the second pressure sensor (303) are respectively embedded in the rubber pads (302).

3. The forming clamp of the silicon-carbon negative electrode battery as claimed in claim 1, wherein: one side of the fixed splint (201) departing from the first electric telescopic rod (204) is provided with symmetrically distributed grooves (205).

4. The forming clamp of the silicon-carbon negative electrode battery as claimed in claim 3, wherein: the rubber rope (206) is adhered in the groove (205), the air bag (207) is adhered at one end of the rubber rope (206), and the air bag (207) is sleeved in the groove (205).

5. The forming clamp of the silicon-carbon negative electrode battery as claimed in claim 4, wherein: the battery box (101) outer wall evenly seted up the round hole, there is air pump (104) through bolt fixed mounting in the round hole, air pump (104) output communicates with gasbag (207) through folding trachea.

6. The forming clamp of the silicon-carbon negative electrode battery as claimed in claim 5, wherein: the single chip microcomputer (102) and the air pump (104) are electrically connected with an external power supply.

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