CN218769751U - Graphite alkene lithium cell heat abstractor - Google Patents

Abstract

The utility model discloses a graphite alkene lithium cell heat abstractor, the on-line screen storage device comprises a supporting pedestal and is characterized by further comprising, support the base upper surface and seted up the intercommunicating pore, the inside mounting groove of seting up of intercommunicating pore, the inside movable mounting of mounting groove has the motor fixed plate, support base upper surface swing joint has the heat conduction copper billet, the fixed orifices has been seted up on the positive surface of support base, graphite alkene lithium cell has been placed to heat conduction copper billet upper surface, the heat dissipation air exit has all been seted up with the rear surface to the positive surface of support base, the heat dissipation air exit communicates with each other with the intercommunicating pore is inside, support the base upper surface and seted up spacing connecting groove, spacing connecting groove communicates with each other with the heat dissipation air exit is inside. Through the inside temperature of the spacing heat conduction piece of PLC temperature control circuit board and the temperature sensor monitoring that set up to the automatic selection radiating mode, when practicing thrift electric power, effectively protect not high temperature of graphite alkene lithium cell.

Description

Graphite alkene lithium cell heat abstractor

Technical Field

The utility model belongs to the technical field of heat abstractor, concretely relates to graphite alkene lithium cell heat abstractor.

Background

Along with the state impels new forms of energy technical development vigorously, various devices with electric drive begin to popularize, the battery technology is also more and more important, graphite alkene battery, utilize the characteristic of lithium ion at a large amount of quick shuttle motion between graphite alkene surface and electrode, the new forms of energy battery of development, graphite alkene lithium cell charge-discharge efficiency is higher, often accompany the production of a large amount of heat energy when quick charge-discharge, therefore graphite alkene lithium cell heat dissipation is more important, need in time with graphite alkene lithium cell charge-discharge production heat distribute away.

The utility model discloses a publication number is CN 211295195U's a graphite alkene group battery heat abstractor, including installing the casing, the upper end of installation casing is equipped with first mounting groove, and the opening of first mounting groove runs through the upside lateral wall setting of installation casing, the lower extreme of installation casing is equipped with the second mounting groove, and the lateral wall setting that the second mounting groove runs through the installation casing, communicate through first bar opening between first mounting groove and the second mounting groove, the upper end of installation casing is equipped with the closing cap that matches the setting with first mounting groove, and is equipped with group battery fixed establishment on the closing cap, be equipped with heat dissipation mechanism in the second mounting groove. The utility model discloses be convenient for fix not unidimensional graphite alkene group battery and place, be convenient for fix the heat dissipation processing to the graphite alkene group battery of different models, but it is in the use, graphite alkene lithium cell is when using, it is different according to using the scene, often charge-discharge speed can be different, when slowly charging, the temperature rises slowly, rely on self and the heat contact of air can satisfy the heat dissipation demand, do not need the motor to drive the heat dissipation that flows this moment, when quick charge-discharge, the temperature can rise fast, just need ventilation unit auxiliary heat dissipation, can not select the problem that the radiating mode practiced thrift electric power according to battery temperature.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a graphite alkene lithium cell heat abstractor, in order to solve and to provide a graphite alkene lithium cell heat abstractor that has now in the above-mentioned background art in the use, because graphite alkene lithium cell is when using, according to using the scene different, often charge-discharge speed can be different, when slowly charging, the temperature rises slowly, rely on self and the heat contact of air can satisfy the heat dissipation demand, do not need the motor to drive the heat dissipation that air flows this moment, when quick charge-discharge, the temperature can rise fast, just need ventilation unit auxiliary heat dissipation, can not select the problem that the radiating mode practiced thrift electric power according to battery temperature.

In order to achieve the above object, the utility model provides a following technical scheme: the utility model provides a graphite alkene lithium cell heat abstractor, includes the support base, the intercommunicating pore has been seted up to the support base upper surface, the inside mounting groove that has seted up of intercommunicating pore, the inside movable mounting of mounting groove has the motor fixed plate, support base upper surface swing joint has the heat conduction copper billet, the fixed orifices has been seted up on the positive surface of support base, the graphite alkene lithium cell has been placed to heat conduction copper billet upper surface.

It is specific, heat conduction copper billet through setting up contacts with the graphite alkene lithium cell, thereby can be inside heat conduction to heat conduction copper billet when the graphite alkene lithium cell generates heat, heat conduction copper billet lower surface is provided with a large amount of radiating grooves, can increase the contact surface with the air, thereby give off the heat to the air, thereby at graphite alkene lithium cell low power during operation, conduct the heat to the air through supplementary heat conduction copper billet, when graphite alkene lithium cell high power during operation, need the starter motor to drive the circulation of air, thereby drive the circulation of air, blow away the inside heat of heat conduction copper billet fast, can avoid graphite alkene lithium cell body temperature to rise fast, select the radiating mode according to temperature variation, can effectual saving electric power.

Preferably, the front surface and the rear surface of the support base are both provided with heat dissipation air outlets, the heat dissipation air outlets are communicated with the inside of the communication hole, the upper surface of the support base is provided with a limiting connecting groove, and the limiting connecting groove is communicated with the inside of the heat dissipation air outlets.

Specifically, through mutually supporting of heat dissipation air exit and intercommunicating pore, can be with inside the air suction heat dissipation air exit from heat conduction copper billet top to form the wind channel.

Preferably, the upper surface of the heat-conducting copper block is provided with an air guide groove, the lower surface of the heat-conducting copper block is provided with an air inlet, the lower surface of the heat-conducting copper block is fixedly provided with a limiting heat-conducting block, and the limiting heat-conducting block is matched with the limiting connecting groove.

Specifically, can get into inside the air intake when the graphite alkene lithium cell is placed on heat conduction copper billet upper surface through the wind-guiding groove, and contact with graphite alkene lithium cell lower surface as far as possible to make the air that flows take away more heats, spacing heat conduction piece can make the heat conduction copper billet fix and support base upper surface department.

Preferably, the lower surface of the heat conducting copper block is provided with a heat dissipation groove, the lower surface of the limiting heat conducting block is fixedly provided with a heat dissipation fin, and the front surface of the limiting heat conducting block is provided with a fixing pin hole.

The heat dissipation structure comprises a heat dissipation groove, a heat conduction copper block and a copper plate fixing pin, wherein the heat dissipation groove is formed in the copper plate fixing pin, the heat conduction copper block is arranged on the copper plate fixing pin, the copper plate fixing pin is arranged on the copper plate fixing pin, and the copper plate fixing pin is arranged on the copper plate fixing pin.

Preferably, a temperature sensor is fixedly mounted inside the limiting heat conduction block, and a PLC temperature control circuit board is fixedly mounted inside the limiting heat conduction block and on one side of the temperature sensor.

Specifically, the internal temperature of the limiting heat conducting block can be monitored in real time through the temperature sensor, and when the internal temperature of the limiting heat conducting block is too high, the PLC temperature control circuit board receives a signal to start the motor to perform auxiliary heat dissipation.

Preferably, fixed surface installs the heat dissipation motor under the motor fixed plate, heat dissipation motor output fixed mounting has radiator vane, the inside movable mounting of fixed orifices has the copper fixed pin.

Specifically, hang the motor inside the intercommunicating pore through the motor fixed plate, cover and to fix the motor fixed plate inside the mounting groove after the heat conduction copper billet, the starter motor fixed plate can drive the heat dissipation motor rotatory, and the heat dissipation motor is rotatory to be driven the circulation of air, and the copper fixed pin can be fixed spacing heat conduction piece inside spacing connecting groove.

Compared with the prior art, the beneficial effects of the utility model are that:

1. through the heat conduction copper billet that sets up mutually supports with the heat dissipation motor, can be inside heat conduction to heat conduction copper billet when graphite alkene lithium cell generates heat, heat conduction copper billet lower surface is provided with a large amount of heat dissipation grooves, can increase the contact surface with the air, thereby give off the heat to in the air, thereby at graphite alkene lithium cell low power during operation, conduct the heat to the air in through supplementary heat conduction copper billet, when graphite alkene lithium cell high power during operation, the temperature risees fast, the temperature sensor monitors when spacing heat conduction block inside temperature risees fast, can signal to PLC temperature control circuit board, PLC temperature control circuit board received signal can start motor fixed plate heat dissipation motor and drive the circulation of air, thereby drive the circulation of air, blow away the inside heat of heat conduction copper billet fast, can avoid graphite alkene lithium cell body temperature to rise fast, effectual saving electric power.

2. Through the heat conduction copper billet and the motor fixed plate that set up mutually support, when needing to overhaul the heat dissipation motor simultaneously, only need to screw off the nut of copper fixed pin one end inside taking the copper fixed pin out the fixed orifices, can remove the relatively fixed to the heat conduction copper billet, can separate the heat conduction copper billet with the support base this moment, do not have the extrusion of heat conduction copper billet, the motor fixed plate can directly follow the inside shifting out of mounting groove, conveniently overhauls the heat dissipation motor.

Drawings

Fig. 1 is a schematic view of the overall structure of the present invention;

FIG. 2 is a schematic view of the installation state structure of the present invention;

fig. 3 is a cross-sectional view of the present invention;

FIG. 4 is a schematic structural view of the heat-conducting copper block of the present invention;

fig. 5 is a schematic structural view of the supporting base and the motor fixing plate of the present invention.

In the figure: 1. a support base; 101. a heat dissipation air outlet; 102. the limiting connection groove; 2. a heat-conducting copper block; 201. a wind guide groove; 202. an air inlet; 203. a heat dissipation groove; 204. limiting the heat conducting block; 205. a heat dissipating fin; 206. a fixing pin hole; 207. a temperature sensor; 208. a PLC temperature control circuit board; 3. a communicating hole; 301. installing a groove; 302. a motor fixing plate; 303. a heat dissipation motor; 304. a heat dissipating fin; 4. a fixing hole; 401. fixing pins by a copper plate; 9. graphene lithium batteries.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

Referring to fig. 1-5, the present invention provides a technical solution: the utility model provides a graphite alkene lithium cell heat abstractor, includes and supports base 1, supports 1 upper surface of base and has seted up the intercommunicating pore 3, and mounting groove 301 has been seted up to intercommunicating pore 3 inside, and the inside movable mounting of mounting groove 301 has motor fixed plate 302, supports 1 upper surface swing joint of base has heat conduction copper billet 2, supports 1 positive surface of base and has seted up fixed orifices 4, and graphite alkene lithium cell 9 has been placed to 2 upper surfaces of heat conduction copper billet.

In this embodiment, contact with graphite alkene lithium cell 9 through the heat conduction copper billet 2 that sets up, thereby can be with heat conduction to the inside of heat conduction copper billet 2 when graphite alkene lithium cell 9 generates heat, 2 lower surfaces of heat conduction copper billet are provided with a large amount of radiating grooves, can increase the contact surface with the air, thereby give off the heat to in the air, thereby at graphite alkene lithium cell 9 low-power during operation, through assisting heat conduction copper billet 2 with heat conduction to in the air, when graphite alkene lithium cell 9 high power during operation, need the starter motor to drive the circulation of air, thereby drive the circulation of air, blow away the heat of 2 inside heat conduction copper billets fast, can avoid graphite alkene lithium cell 9 body temperature to rise fast, select the heat dissipation mode according to temperature variation, can effectual saving electric power.

Wherein, in order to realize radiating purpose, this device adopts following technical scheme to realize: the front surface and the rear surface of the supporting base 1 are both provided with a heat dissipation air outlet 101, the heat dissipation air outlet 101 is communicated with the inside of the communicating hole 3, the upper surface of the supporting base 1 is provided with a limiting connecting groove 102, the limiting connecting groove 102 is communicated with the inside of the heat dissipation air outlet 101, the upper surface of the heat conduction copper block 2 is provided with an air guide groove 201, the lower surface of the heat conduction copper block 2 is provided with an air inlet 202, the lower surface of the heat conduction copper block 2 is fixedly provided with a limiting heat conduction block 204, the limiting heat conduction block 204 is matched with the limiting connecting groove 102, the lower surface of the heat conduction copper block 2 is provided with a heat dissipation groove 203, the lower surface of the limiting heat conduction block 204 is fixedly provided with a heat dissipation fin 205, and the front surface of the limiting heat conduction block 204 is provided with a fixed pin hole 206.

Through heat dissipation air exit 101 and intercommunicating pore 3 mutually supporting, can be inside heat dissipation air exit 101 from the suction of heat conduction copper billet 2 top with the air, thereby form the wind channel, wind-guiding groove 201 can place when heat conduction copper billet 2 upper surface at graphite alkene lithium cell 9, can get into inside air intake 202, and as far as possible with graphite alkene lithium cell 9 lower surface contact, thereby make the air that flows take away more heat, spacing heat conduction piece 204 can make heat conduction copper billet 2 fix in supporting base 1 upper surface department, heat dissipation groove 203 increases the contact surface of heat conduction copper billet 2 and air, thereby give off the heat to in the air fast, radiating fin 205 can be with heat conduction copper billet 2 conduction to the inside heat transfer of spacing heat conduction piece 204 to in heat dissipation air exit 101 inside air, fixing pin hole 206 and copper fixed pin 401 mutually support, can fix spacing heat conduction piece 204 inside spacing connection groove 102.

Wherein, in order to realize the purpose of easy access motor, this device adopts following technical scheme to realize: the inside fixed mounting of spacing heat conduction piece 204 has temperature sensor 207, and inside and the fixed mounting that is located temperature sensor 207 one side of spacing heat conduction piece 204 has PLC control by temperature change circuit board 208, and fixed surface mounting has heat dissipation motor 303 under the motor fixed plate 302, and heat dissipation motor 303 output end fixed mounting has radiator fin 304, and the inside movable mounting of fixed orifices 4 has copper fixed pin 401.

Can the inside temperature of spacing heat conduction piece 204 of real-time supervision through temperature sensor 207, when the inside high temperature of spacing heat conduction piece 204, PLC control by temperature change circuit board 208 received the signal can the starter motor carry out supplementary heat dissipation, motor fixed plate 302 hangs the motor inside intercommunicating pore 3, cover and can fix motor fixed plate 302 inside mounting groove 301 after heat conduction copper billet 2, starter motor fixed plate 302 can drive heat dissipation motor 303 rotatory, heat dissipation motor 303 is rotatory can drive the circulation of air, copper fixed pin 401 can be fixed spacing heat conduction piece 204 inside spacing connecting groove 102.

The utility model discloses a theory of operation and use flow: when the device is used, the graphene lithium battery 9 and the device are fixed at proper positions through the U-shaped pins, when the graphene lithium battery 9 generates heat, heat can be conducted into the heat conducting copper block 2, the lower surface of the heat conducting copper block 2 is provided with a large number of heat radiating grooves 203, the contact surface with air can be increased, and therefore the heat can be radiated into the air, so that when the graphene lithium battery 9 works at low power, the heat can be conducted into the air through the auxiliary heat conducting copper block 2, when the graphene lithium battery 9 works at high power, the temperature rises rapidly, when the temperature sensor 207 monitors that the temperature in the limiting heat conducting block 204 rises rapidly, a signal is sent to the PLC temperature control circuit board 208, and when the PLC temperature control circuit board 208 receives the signal, the motor fixing plate 302 is started to radiate the heat, and the motor 303 is started to drive the air to circulate, thereby drive the circulation of air, blow away the inside heat of heat conduction copper billet 2 fast, can avoid graphite alkene lithium cell 9 body temperature to rise fast, effectual saving electric power, when needing to overhaul heat dissipation motor 303 simultaneously, only need screw down the nut of copper fixed pin 401 one end take copper fixed pin 401 out inside fixed orifices 4, can remove the relatively fixed to heat conduction copper billet 2, can separate heat conduction copper billet 2 and support base 1 this moment, do not have the extrusion of heat conduction copper billet 2, motor fixed plate 302 can directly shift out from mounting groove 301 is inside, the convenience is overhauld heat dissipation motor 303.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims (6)

1. The utility model provides a graphite alkene lithium cell heat abstractor, is including supporting base (1), its characterized in that: support base (1) upper surface and seted up intercommunicating pore (3), mounting groove (301) have been seted up to intercommunicating pore (3) inside, the inside movable mounting of mounting groove (301) has motor fixed plate (302), it has heat conduction copper billet (2) to support base (1) upper surface swing joint, support base (1) positive surface and seted up fixed orifices (4), graphite alkene lithium cell (9) have been placed to heat conduction copper billet (2) upper surface.

2. The graphene lithium battery heat dissipation device of claim 1, wherein: support base (1) front surface and rear surface and all seted up heat dissipation air exit (101), heat dissipation air exit (101) communicate with each other with intercommunicating pore (3) inside, support base (1) upper surface has seted up spacing connecting grooves (102), spacing connecting grooves (102) communicate with each other with heat dissipation air exit (101) inside.

3. The graphene lithium battery heat dissipation device of claim 2, wherein: the air guide groove (201) is formed in the upper surface of the heat conduction copper block (2), the air inlet (202) is formed in the lower surface of the heat conduction copper block (2), the limiting heat conduction block (204) is fixedly mounted on the lower surface of the heat conduction copper block (2), and the limiting heat conduction block (204) is matched with the limiting connection groove (102).

4. The graphene lithium battery heat dissipation device of claim 3, wherein: the lower surface of the heat-conducting copper block (2) is provided with a heat-radiating groove (203), the lower surface of the limiting heat-conducting block (204) is fixedly provided with a heat-radiating fin (205), and the front surface of the limiting heat-conducting block (204) is provided with a fixing pin hole (206).

5. The graphene lithium battery heat dissipation device of claim 3, wherein: the temperature sensor (207) is fixedly mounted inside the limiting heat conduction block (204), and the PLC temperature control circuit board (208) is fixedly mounted inside the limiting heat conduction block (204) and located on one side of the temperature sensor (207).

6. The heat dissipation device for the graphene lithium battery as recited in claim 1, wherein: fixed surface installs heat dissipation motor (303) under motor fixed plate (302), heat dissipation motor (303) output fixed mounting has radiator fin (304), the inside movable mounting of fixed orifices (4) has copper fixed pin (401).

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