CN115863842A

CN115863842A - Energy storage module of high-efficient heat dissipation management

Info

Publication number: CN115863842A
Application number: CN202310182060.9A
Authority: CN
Inventors: 邓嫄媛; 严磊; 冯威; 赵洁; 李俭; 袁容; 李力; 袁新璐
Original assignee: Chengdu University
Current assignee: Chengdu University
Priority date: 2023-03-01
Filing date: 2023-03-01
Publication date: 2023-03-28
Anticipated expiration: 2043-03-01
Also published as: CN115863842B

Abstract

The invention discloses an energy storage module with efficient heat dissipation management, and relates to the technical field of battery heat dissipation. This kind of energy storage module of high-efficient heat dissipation management, including mounting bracket and electric core module, the bottom integrated into one piece of mounting bracket has the installation section of thick bamboo that a plurality of arrays set up, and electric core module inserts and establish in the installation section of thick bamboo, the fixed cover of lateral wall of mounting bracket is equipped with the adiabatic frame that the annular set up, and the fixed cover of lateral wall of adiabatic frame is equipped with the shell, the installation section of thick bamboo is inserted and is established in the shell, and the top of shell can be dismantled through the bolt and be connected with the apron, the bar opening has been seted up to the lateral wall of shell. When the temperature is higher, combine together liquid cooling and air-cooling, simultaneously, greatly increased radiating area for the heat dissipation is more high-efficient, the effect is better, and, in low temperature environment, can make its inside vacuum state that forms with the air escape in the shell, thereby can play fine heat preservation effect, avoid low temperature to cause the damage to energy storage module, guarantee its result of use and life-span.

Description

Energy storage module of high-efficient heat dissipation management

Technical Field

The invention relates to the technical field of battery heat dissipation, in particular to an energy storage module with efficient heat dissipation management.

Background

The energy storage module battery is widely applied to a plurality of fields by virtue of excellent characteristics, but needs to provide good heat dissipation for the energy storage module battery so as to ensure the stable work of the energy storage module battery, and the existing heat dissipation scheme is generally air cooling or liquid cooling.

However, when current energy storage module battery was used, when adopting forced air cooling or liquid cooling alone, the radiating effect was relatively poor for the heat dissipation is high-efficient inadequately, and simultaneously, heat radiating area is less, also can influence radiating efficiency and effect, and, in low temperature environment, influence energy storage module's performance and life easily.

Disclosure of Invention

The present invention is directed to an energy storage module with efficient heat dissipation management, so as to solve the problems in the background art.

In order to achieve the purpose, the invention provides the following technical scheme: the utility model provides an energy storage module of high-efficient heat dissipation management, includes mounting bracket and electric core module, the bottom integrated into one piece of mounting bracket has the installation section of thick bamboo that a plurality of arrays set up, and electric core module inserts and establish in the installation section of thick bamboo, the fixed cover of lateral wall of mounting bracket is equipped with the adiabatic frame that the annular set up, and the fixed cover of lateral wall of adiabatic frame is equipped with the shell, the installation section of thick bamboo is inserted and is established in the shell, and the top of shell can dismantle through the bolt and be connected with the apron, the bar opening has been seted up to the lateral wall of shell, and the bar opening internal fixation inserts and is equipped with the filter, the lateral wall of shell has the removal frame through first canceling release mechanical system sliding connection, and removes the lateral wall slip of frame at the filter, the lateral wall fixed of shell is inserted and is equipped with the exhaust column, and is provided with exhaust column in the exhaust column, be provided with the evacuation mechanism that is used for carrying out the evacuation in the shell in the exhaust column, and the lateral wall that removes the frame is provided with the atomizing mechanism that is used for atomizing cooling water, the removal of removing the frame promotes through first pushing mechanism, and be provided with temperature sensor in the shell.

Preferably, the first reset mechanism comprises two symmetrically-arranged fixed blocks fixedly connected to the side wall of the housing, a first T-shaped guide rod is inserted into the upper side wall of each fixed block, a supporting block is fixedly connected to the upper end of each first T-shaped guide rod, the supporting blocks are fixed to the side wall of the movable frame, and a first spring is sleeved on the side wall of each first T-shaped guide rod.

Preferably, exhaust mechanism includes the baffle of fixed connection at the exhaust column inside wall, and the lateral wall of baffle has seted up first through-hole, the lower lateral wall fixedly connected with movable plate of removal frame, and the movable plate inserts and establish in the exhaust column and seted up the second through-hole, the inside wall fixedly connected with backup pad of exhaust column, and the lateral wall of backup pad rotates through the pivot and is connected with the commentaries on classics fan, the first motor of lateral wall fixedly connected with of backup pad, and the output of first motor is fixed with the one end of pivot.

Preferably, first pushing mechanism is including inserting the L shaped plate of establishing at the exhaust column lateral wall, and the one end of L shaped plate is fixed with the lateral wall of removal frame, the fixed cover of lateral wall of pivot is equipped with solid fixed ring, and the fixed pipe that solid fixed ring's a plurality of arrays of lateral wall fixedly connected with set up, fixed intraductal sliding connection has the sliding tray, and the upper end fixedly connected with carriage release lever of sliding tray, the other end of carriage release lever runs through the tip and the fixedly connected with metal ball of fixed pipe, and the lateral wall cover of carriage release lever is equipped with the second spring.

Preferably, the vacuumizing mechanism comprises an exhaust pipe fixedly inserted in the side wall of the movable plate, a first one-way valve is fixedly connected in the exhaust pipe, a connecting pipe is fixedly connected to the other end of the exhaust pipe, an air outlet pipe is fixedly connected to the other end of the connecting pipe, a second one-way valve is fixedly connected in the air outlet pipe, a working pipe is fixedly connected to the side wall of the connecting pipe, a piston is slidably connected in the working pipe, and the piston is moved by a second pushing mechanism.

Preferably, the second pushing mechanism comprises a pushing rod fixedly connected to the bottom of the piston, a moving block is fixedly connected to the lower end of the pushing rod, the moving block is connected to the side wall of the connecting pipe through a second resetting mechanism, the pushing block is fixedly connected to the lower side wall of the moving block, a connecting shaft is fixedly connected to the end portion of the rotating shaft, and a plurality of protruding blocks arranged in an array are fixedly connected to the side wall of the connecting shaft.

Preferably, the second reset mechanism comprises two second T-shaped guide rods which are inserted into the side wall of the moving block and symmetrically arranged, the upper ends of the second T-shaped guide rods are fixed to the side wall of the connecting pipe, and a third spring is sleeved on the side wall of the second T-shaped guide rod.

Preferably, the atomizing mechanism comprises a communicating box fixedly connected to the side wall of the moving frame, a water supply pipe is fixedly connected to the top of the communicating box, a plurality of atomizing pipes arranged in an L shape are fixedly connected to the bottom of the communicating box, an atomizing nozzle is fixedly connected to the lower end of each atomizing pipe, and an on-off mechanism for controlling the atomizing pipes to be turned on and off is arranged on the side wall of each atomizing pipe.

Preferably, the on-off mechanism comprises a fixed cover fixedly inserted on the side wall of the atomizing pipe, a sliding plate is connected in the fixed cover in a sliding mode, a third through hole is formed in the bottom of the sliding plate, two first connecting blocks symmetrically arranged on the side wall of the sliding plate are fixedly connected with the side wall of each first connecting block, a third T-shaped guide rod is fixedly connected to the side wall of each first connecting block, a second connecting block is sleeved on the side wall of each third T-shaped guide rod, the second connecting blocks are fixed to the side wall of the fixed cover, a fourth spring is sleeved on the side wall of each third T-shaped guide rod, and the sliding plate is moved through a third pushing mechanism.

Preferably, third pushing mechanism includes the slurcam, and the slurcam includes the inclined plane, the first connecting plate of lateral wall fixedly connected with of slurcam, and the lateral wall fixedly connected with loop bar of first connecting plate, the lateral wall cover of loop bar is equipped with the sleeve pipe, and the sheathed tube other end is fixed with the lateral wall of shell, the lateral wall fixedly connected with second connecting plate of slurcam, and the lateral wall of second connecting plate rotates and is connected with the threaded rod, the lateral wall threaded connection of threaded rod has the thread bush, and the other end of thread bush is fixed with the lateral wall of shell, the lateral wall fixedly connected with second motor of second connecting plate, and the output of second motor is fixed with the one end of threaded rod.

Compared with the prior art, the invention has the beneficial effects that:

this kind of energy storage module of high-efficient heat dissipation management, through setting up updraft ventilator mechanism etc, when temperature sensor detects the temperature in the shell higher, start first motor and carry out the high-speed rotation, the rotation of first motor drives the pivot and rotates the synchronous rotation of fan, thereby carry out the convulsions operation, meanwhile, when the pivot rotates, drive solid fixed ring and metal ball and carry out the synchronous rotation, make the metal ball remove to the direction of keeping away from solid fixed ring under the effect of centrifugal force, and simultaneously, the second spring is compressed, make the lower lateral wall of metal ball and L shaped plate offset, thereby promote L shaped plate and removal frame rebound, first spring is compressed, at this moment, expose the filter, and simultaneously, when removing the frame rebound, it carries out the synchronous movement to drive, make the second through-hole and first through-hole movable plate adjust well, at this moment, outside air passes through in the filter gets into the shell, and discharge through the exhaust pipe, cool off the heat dissipation to installation section of thick bamboo and electric core module through circulating the air, and simultaneously, the setting of installation section of thick bamboo, the radiating area has greatly increased, make the heat dissipation more high-efficient, the effect is better.

This kind of energy storage module of high-efficient heat dissipation management, through setting up atomizing mechanism etc, when dispelling the heat, when removing frame rebound, drive the synchronous rebound of intercommunication case, make atomizer aim at the filter, meanwhile, when the sliding plate offsets with the inclined plane, promote the sliding plate and slide to fixed cover, and simultaneously, the fourth spring is compressed, thereby make the coincidence of third through-hole and atomizing pipe emergence, at this moment, the cooling water passes through and gets into in the atomizing pipe behind delivery pipe and the intercommunication case, and spray in filter department after atomizing through atomizer, along with the inside air is together got into the shell, combine together liquid cooling and air-cooling, thereby make the cooling heat dissipation to installation section of thick bamboo and electric core module more high-efficient, the effect is better.

This kind of energy storage module of high-efficient heat dissipation management, through setting up evacuation mechanism etc., when temperature sensor detects the energy storage module and is in low temperature environment, make first motor carry out low-speed rotation, this moment, the centrifugal force that the metal ball received is less, thereby can not promote L shaped plate and removal frame rebound, this moment, it is sealed that the removal frame carries out the shutoff with the filter, and simultaneously, the second through-hole staggers with first through-hole, the exhaust tube is adjusted well with first through-hole, meanwhile, the rotation of pivot drives the synchronous rotation of connecting axle and lug, when promoting the piece and offsetting the lateral wall of lug, promote piston rebound, simultaneously, the third spring is compressed, when promoting the piece and crossing the lateral wall of lug, the piston can move down and reset under the effect of third spring, thereby make the piston reciprocate from top to bottom in the service tube, when the piston moves down, make the intraductal negative pressure that produces of connecting, simultaneously, first check valve opens, the second check valve closes, this moment, air in the shell gets into the connecting tube through the exhaust tube entering connecting tube, when the piston moves up, the air extrusion, simultaneously, the second check valve closes, the interior air extrusion effect of this moment can be guaranteed to the low temperature extrusion and the inside the exhaust tube, so good air outlet pipe, thereby, the good connection effect can be formed.

Drawings

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

FIG. 2 is a schematic overall view from another perspective of the present invention;

FIG. 3 is a partial cross-sectional structural schematic of the present invention;

FIG. 4 is a partial schematic view of another aspect of the present invention;

FIG. 5 is an enlarged schematic view of the structure at A in FIG. 1;

FIG. 6 is an enlarged view of the structure at B in FIG. 2;

FIG. 7 is an enlarged view of the structure at C in FIG. 3;

FIG. 8 is an enlarged view of the structure of FIG. 3 at D;

FIG. 9 is an enlarged view of the structure at E in FIG. 4;

fig. 10 is an enlarged schematic view of F in fig. 9.

In the figure: 1. a mounting frame; 2. a first reset mechanism; 201. a fixed block; 202. a first T-shaped guide rod; 203. a first spring; 204. a support block; 3. an air draft mechanism; 301. a baffle plate; 302. a first through hole; 303. moving the plate; 304. a second through hole; 305. a support plate; 306. a rotating shaft; 307. rotating the fan; 308. a first motor; 4. a first pushing mechanism; 401. an L-shaped plate; 402. a fixed tube; 403. a sliding disk; 404. a travel bar; 405. a metal ball; 406. a second spring; 407. a fixing ring; 5. a vacuum pumping mechanism; 501. an air exhaust pipe; 502. a first check valve; 503. a connecting pipe; 504. an air outlet pipe; 505. a second one-way valve; 506. a working pipe; 507. a piston; 6. a second pushing mechanism; 601. a push rod; 602. a moving block; 603. a pushing block; 604. a connecting shaft; 605. a bump; 7. a second reset mechanism; 701. a second T-shaped guide rod; 702. a third spring; 8. an atomization mechanism; 801. a communicating box; 802. a water supply pipe; 803. an atomizing tube; 804. an atomizing spray head; 9. an on-off mechanism; 901. a fixed cover; 902. a sliding plate; 903. a third through hole; 904. a first connection block; 905. a second connecting block; 906. a fourth spring; 907. a third T-shaped guide rod; 10. a third pushing mechanism; 1001. a push plate; 1002. a bevel; 1003. a first connecting plate; 1004. a loop bar; 1005. a sleeve; 1006. a second connecting plate; 1007. a threaded rod; 1008. a threaded sleeve; 1009. a second motor; 11. mounting the cylinder; 12. a battery cell module; 13. a heat insulating frame; 14. a housing; 15. an exhaust pipe; 16. a cover plate; 17. a strip-shaped opening; 18. a filter plate; 19. and moving the frame.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Referring to fig. 1-10, the present invention provides a technical solution: an energy storage module for efficient heat dissipation management comprises an installation frame 1 and a cell module 12, wherein a plurality of installation cylinders 11 arranged in an array are integrally formed at the bottom of the installation frame 1, the cell module 12 is inserted into the installation cylinders 11, an annular heat insulation frame 13 is fixedly sleeved on the side wall of the installation frame 1, a shell 14 is fixedly sleeved on the side wall of the heat insulation frame 13, the installation cylinders 11 are inserted into the shell 14, a cover plate 16 is detachably connected to the top of the shell 14 through bolts, a strip-shaped opening 17 is formed in the side wall of the shell 14, a filter plate 18 is fixedly inserted into the strip-shaped opening 17, a movable frame 19 is slidably connected to the side wall of the shell 14 through a first resetting mechanism 2, the movable frame 19 slides on the side wall of the filter plate 18, a ventilation pipe 15 is fixedly inserted into the side wall of the shell 14, and be provided with exhaust mechanism 3 in the exhaust column 15, be provided with in the exhaust column 15 and be used for carrying out the evacuation mechanism 5 of evacuation in the shell 14, and the lateral wall that removes frame 19 is provided with and is used for carrying out atomizing mechanism 8 to the cooling water, the removal that removes frame 19 promotes through first pushing mechanism 4, and is provided with temperature sensor in the shell 14, combines together liquid cooling and air-cooling, and simultaneously, greatly increased radiating area for the heat dissipation is more high-efficient, the effect is better, and, in low temperature environment, can discharge the air in the shell 14, make its inside vacuum state that forms, thereby can play fine heat preservation effect, avoid low temperature to cause the damage to the energy storage module, guarantee its result of use and life-span.

Referring to fig. 5, the first reset mechanism 2 includes two symmetrically disposed fixed blocks 201 fixedly connected to the side wall of the housing 14, a first T-shaped guide rod 202 is inserted into the upper side wall of the fixed block 201, a supporting block 204 is fixedly connected to the upper end of the first T-shaped guide rod 202, the supporting block 204 is fixed to the side wall of the movable frame 19, and a first spring 203 is sleeved on the side wall of the first T-shaped guide rod 202 to guide and reset the movement of the movable frame 19.

Referring to fig. 7 and 9, the air pumping mechanism 3 includes a baffle 301 fixedly connected to an inner side wall of the air pumping duct 15, a first through hole 302 is formed in a side wall of the baffle 301, a moving plate 303 is fixedly connected to a lower side wall of the moving frame 19, the moving plate 303 is inserted into the air pumping duct 15 and is provided with a second through hole 304, a support plate 305 is fixedly connected to an inner side wall of the air pumping duct 15, a rotating fan 307 is rotatably connected to a side wall of the support plate 305 through the rotating shaft 306, a first motor 308 is fixedly connected to a side wall of the support plate 305, an output end of the first motor 308 is fixed to one end of the rotating shaft 306, when the temperature sensor detects a high temperature inside the casing 14, the first motor 308 is started to rotate rapidly, the first motor 308 rotates to drive the rotating shaft 306 and the rotating fan 307 to rotate synchronously, so as to perform air pumping operation, at the same time, the moving frame 19 is pushed by the first pushing mechanism 4 to move upwards, at this time, the filter plate 18 is exposed, and at the moving frame 19 moves upwards, the moving plate 303 is driven to move synchronously, so that the second through the first through hole 302, the filter plate 18 enters the casing 14, and the air is circulated to cool the battery cell 12 and the cooling module 11 and the battery cell.

Referring to fig. 7, 9 and 10, the first pushing mechanism 4 includes an L-shaped plate 401 inserted into the side wall of the exhaust pipe 15, one end of the L-shaped plate 401 is fixed to the side wall of the moving frame 19, a fixing ring 407 is fixedly sleeved on the side wall of the rotating shaft 306, a plurality of fixing tubes 402 arranged in an array are fixedly connected to the side wall of the fixing ring 407, a sliding disc 403 is slidably connected to the fixing tubes 402, a moving rod 404 is fixedly connected to the upper end of the sliding disc 403, the other end of the moving rod 404 penetrates through the end of the fixing tube 402 and is fixedly connected to a metal ball 405, and a second spring 406 is sleeved on the side wall of the moving rod 404, when the rotating shaft 306 rotates, the fixing ring 407 and the metal ball 405 are driven to rotate synchronously, so that the metal ball 405 moves in a direction away from the fixing ring 407 under the action of centrifugal force, and the second spring 406 is compressed, so that the metal ball 405 abuts against the lower side wall of the L-shaped plate 401, thereby pushing the L-shaped plate 401 and the moving frame 19 to move upward.

Referring to fig. 7, 9 and 10, the vacuum pumping mechanism 5 includes an air pumping pipe 501 fixedly inserted in the side wall of the moving plate 303, a first one-way valve 502 is fixedly connected in the air pumping pipe 501, a connecting pipe 503 is fixedly connected at the other end of the air pumping pipe 501, an air outlet pipe 504 is fixedly connected at the other end of the connecting pipe 503, a second one-way valve 505 is fixedly connected in the air outlet pipe 504, a working pipe 506 is fixedly connected to the side wall of the connecting pipe 503, a piston 507 is slidably connected in the working pipe 506, the piston 507 is moved by the second pushing mechanism 6, when the temperature sensor detects that the energy storage module is in a low temperature environment, the first motor 308 is rotated at a low speed, at this time, the centrifugal force applied to the metal ball 405 is small, so that the L-shaped plate 401 and the moving frame 19 are not pushed to move upward, at this time, the moving frame 19 seals and seals the filter plate 18, and at the same time, the second through hole 304 is staggered with the first through hole 302, the air suction pipe 501 is aligned with the first through hole 302, meanwhile, the piston 507 is pushed by the second pushing mechanism 6 to reciprocate up and down in the working pipe 506, when the piston 507 moves downwards, negative pressure is generated in the connecting pipe 503, meanwhile, the first one-way valve 502 is opened, the second one-way valve 505 is closed, at the same time, air in the shell 14 enters the connecting pipe 503 through the air suction pipe 501, when the piston 507 moves upwards, air in the connecting pipe 503 is extruded, meanwhile, the first one-way valve 502 is closed, the second one-way valve 505 is opened, at the same time, air in the connecting pipe 503 is extruded and then is exhausted through the air outlet pipe 504 and the air suction pipe 15, the reciprocating is carried out, namely, air in the shell 14 can be exhausted, the vacuum state is formed in the interior of the shell, so that a good heat preservation effect can be achieved, and the energy storage module is prevented from being damaged by low temperature, the service effect and the service life of the device are ensured.

Referring to fig. 10, the second pushing mechanism 6 includes a pushing rod 601 fixedly connected to the bottom of the piston 507, a moving block 602 is fixedly connected to the lower end of the pushing rod 601, the moving block 602 is connected to the side wall of the connecting pipe 503 through the second resetting mechanism 7, a pushing block 603 is fixedly connected to the lower side wall of the moving block 602, a connecting shaft 604 is fixedly connected to the end of the rotating shaft 306, a plurality of bumps 605 arranged in an array are fixedly connected to the side wall of the connecting shaft 604, the rotating shaft 306 rotates to drive the connecting shaft 604 and the bumps 605 to rotate synchronously, and when the pushing block 603 abuts against the side wall of the bumps 605, the piston 507 is pushed to move upwards.

Referring to fig. 10, the second reset mechanism 7 includes two symmetrically disposed second T-shaped guide rods 701 inserted into the sidewall of the moving block 602, the upper ends of the second T-shaped guide rods 701 are fixed to the sidewall of the connecting pipe 503, and a third spring 702 is sleeved on the sidewall of the second T-shaped guide rods 701 to guide and reset the movement of the piston 507.

Referring to fig. 6 and 8, the atomizing mechanism 8 includes a communication box 801 fixedly connected to a side wall of the movable frame 19, a water supply pipe 802 is fixedly connected to a top portion of the communication box 801, the water supply pipe 802 is connected to an external water supply assembly, a plurality of L-shaped atomizing pipes 803 are fixedly connected to a bottom portion of the communication box 801, an atomizing nozzle 804 is fixedly connected to a lower end of each atomizing pipe 803, and an on-off mechanism 9 for controlling on-off of each atomizing pipe 803 is disposed on a side wall of each atomizing pipe 803.

Referring to fig. 8, the on-off mechanism 9 includes a fixed cover 901 fixedly inserted in a side wall of the atomizing pipe 803, a sliding plate 902 is slidably connected in the fixed cover 901, a third through hole 903 is formed in the bottom of the sliding plate 902, two first connecting blocks 904 symmetrically arranged are fixedly connected to the side wall of the sliding plate 902, a third T-shaped guide rod 907 is fixedly connected to the side wall of the first connecting block 904, a second connecting block 905 is sleeved on the side wall of the third T-shaped guide rod 907, the second connecting block 905 is fixed to the side wall of the fixed cover 901, a fourth spring 906 is sleeved on the side wall of the third T-shaped guide rod 907, the sliding plate 902 is moved by the third pushing mechanism 10, when the moving frame 19 moves upward, the communicating box 801 is driven to move upward synchronously, when the sliding plate 902 abuts against the inclined plane 1002, the sliding plate 902 is pushed to slide in the fixed cover 901, and the fourth spring 906 is compressed, so that the third through hole 903 coincides with the atomizing pipe 803, at this time, the cooling water enters the atomizing pipe 803 through the water supply pipe 802 and the communicating box 801, and then is atomized at the atomizing head 804.

Referring to fig. 6, the third pushing mechanism 10 includes a pushing plate 1001, the pushing plate 1001 includes an inclined plane 1002, a first connecting plate 1003 is fixedly connected to a side wall of the pushing plate 1001, a sleeve 1004 is fixedly connected to a side wall of the first connecting plate 1003, a sleeve 1005 is sleeved on a side wall of the sleeve 1004, the other end of the sleeve 1005 is fixed to a side wall of the housing 14, a second connecting plate 1006 is fixedly connected to a side wall of the pushing plate 1001, a threaded rod 1007 is rotatably connected to a side wall of the second connecting plate 1006, a threaded sleeve 1008 is threadedly connected to a side wall of the threaded rod 1007, the other end of the threaded sleeve 1008 is fixed to a side wall of the housing 14, a second motor 1009 is fixedly connected to a side wall of the second connecting plate 1006, an output end of the second motor 1009 is fixed to one end of the threaded rod 1007, the second motor 1009 is started, rotation of the threaded rod 1007 drives rotation of the threaded rod 1007, so that the pushing plate 1001 moves, a distance between the pushing plate 1001 and the housing 14 is adjusted, and a moving stroke of the sliding plate 902 and a coincidence area of the third through hole 903 and the atomization pipe 803 are adjusted, thereby adjusting a flow rate of the cooling water.

The working principle is as follows: when the temperature sensor is used, when the temperature sensor detects that the temperature in the housing 14 is high, the first motor 308 is started to rotate quickly, the rotation of the first motor 308 drives the rotating shaft 306 and the rotating fan 307 to rotate synchronously, so that air draft operation is performed, meanwhile, when the rotating shaft 306 rotates, the fixed ring 407 and the metal ball 405 are driven to rotate synchronously, so that the metal ball 405 moves in a direction away from the fixed ring 407 under the action of centrifugal force, meanwhile, the second spring 406 is compressed, the metal ball 405 abuts against the lower side wall of the L-shaped plate 401, so that the L-shaped plate 401 and the moving frame 19 are pushed to move upwards, the first spring 203 is compressed, at this time, the filter plate 18 is exposed, meanwhile, when the moving frame 19 moves upwards, the moving plate 303 is driven to move synchronously, so that the second through hole 304 is aligned with the first through hole 302, at this time, external air enters the housing 14 through the filter plate 18 and is discharged through the exhaust pipe 15, the mounting cylinder 11 and the battery cell module 12 are cooled and dissipated heat through circulation of air, and meanwhile, the setting of the mounting cylinder 11 greatly increases the heat dissipation area, so that the heat dissipation effect is better and better;

meanwhile, during heat dissipation, when the moving frame 19 moves upwards, the communicating box 801 is driven to move upwards synchronously, so that the atomizing nozzle 804 is aligned with the filter plate 18, meanwhile, when the sliding plate 902 abuts against the inclined surface 1002, the sliding plate 902 is pushed to slide towards the fixed cover 901, meanwhile, the fourth spring 906 is compressed, so that the third through hole 903 is overlapped with the atomizing pipe 803, at the moment, cooling water enters the atomizing pipe 803 after passing through the water supply pipe 802 and the communicating box 801, is atomized by the atomizing nozzle 804 and then is sprayed to the filter plate 18, and enters the shell 14 along with external air, so that liquid cooling and air cooling are combined, and cooling and heat dissipation of the mounting cylinder 11 and the electric core module 12 are more efficient and better in effect;

and, when the temperature sensor detects that the energy storage module is in a low temperature environment, the first motor 308 is rotated at a low speed, at this time, the centrifugal force applied to the metal ball 405 is small, so that the L-shaped plate 401 and the moving frame 19 are not pushed to move upwards, at this time, the moving frame 19 seals and seals the filter plate 18, meanwhile, the second through hole 304 is staggered with the first through hole 302, the air suction pipe 501 is aligned with the first through hole 302, at the same time, the rotation of the rotating shaft 306 drives the connecting shaft 604 and the projection 605 to rotate synchronously, when the pushing block 603 abuts against the side wall of the projection 605, the piston 507 is pushed to move upwards, at the same time, the third spring 702 is compressed, when the pushing block 603 crosses the side wall of the projection 605, the piston 507 can move downwards under the action of the third spring 702 to reset, so that the piston 507 reciprocates up and down in the working pipe 506, when the piston 507 moves downwards, negative pressure is generated in the connecting pipe 503, at the same time, the first check valve 502 is opened, the second check valve 505 is closed, at this time, air in the connecting pipe 505 enters the working pipe 503, when the piston 507 moves upwards, the air suction pipe is pushed, the air outlet pipe 503, the air pipe is prevented from being damaged, the connecting pipe 503, the air outlet pipe 503, the connecting pipe is formed by the air outlet pipe 503, and the air outlet pipe 14, and the air outlet pipe is prevented from being damaged by the air outlet pipe by the one-way, and the one-way.

Claims

1. The utility model provides an energy storage module of high-efficient heat dissipation management, includes mounting bracket (1) and electric core module (12), its characterized in that: a plurality of mounting cylinders (11) arranged in an array are integrally formed at the bottom of the mounting rack (1), the battery cell module (12) is inserted into the mounting barrel (11), the side wall of the mounting frame (1) is fixedly sleeved with an annular heat insulation frame (13), and the side wall of the heat insulation frame (13) is fixedly sleeved with a shell (14), the installation cylinder (11) is inserted in the shell (14), and the top of the shell (14) is detachably connected with a cover plate (16) through a bolt, the side wall of the shell (14) is provided with a strip-shaped opening (17), a filter plate (18) is fixedly inserted in the strip-shaped opening (17), the side wall of the shell (14) is connected with a movable frame (19) through a first reset mechanism (2) in a sliding way, the movable frame (19) slides on the side wall of the filter plate (18), an exhaust pipe (15) is fixedly inserted into the side wall of the shell (14), an air draft mechanism (3) is arranged in the air draft pipe (15), a vacuum pumping mechanism (5) for pumping vacuum in the shell (14) is arranged in the air draft pipe (15), and the side wall of the movable frame (19) is provided with an atomizing mechanism (8) for atomizing cooling water, the moving frame (19) is moved by a first pushing mechanism (4), and a temperature sensor is arranged in the shell (14).

2. The energy storage module of high-efficient heat dissipation management of claim 1, characterized in that: the first reset mechanism (2) comprises two fixing blocks (201) which are fixedly connected to the side wall of the shell (14) and symmetrically arranged, a first T-shaped guide rod (202) is inserted into the upper side wall of each fixing block (201), a supporting block (204) is fixedly connected to the upper end of each first T-shaped guide rod (202), the supporting block (204) is fixed to the side wall of the movable frame (19), and a first spring (203) is sleeved on the side wall of each first T-shaped guide rod (202).

3. The energy storage module of high-efficient heat dissipation management of claim 1, characterized in that: convulsions mechanism (3) include baffle (301) of fixed connection at exhaust column (15) inside wall, and the lateral wall of baffle (301) has seted up first through-hole (302), the lower lateral wall fixedly connected with movable plate (303) of removal frame (19), and movable plate (303) insert and establish in exhaust column (15) and seted up second through-hole (304), the inside wall fixedly connected with backup pad (305) of exhaust column (15), and the lateral wall of backup pad (305) rotates through pivot (306) and is connected with and changes fan (307), the first motor (308) of lateral wall fixedly connected with of backup pad (305), and the output of first motor (308) is fixed with the one end of pivot (306).

4. The energy storage module of high-efficiency heat dissipation management of claim 3, wherein: first pushing mechanism (4) are including inserting L shaped plate (401) of establishing exhaust column (15) lateral wall, and the one end of L shaped plate (401) is fixed with the lateral wall that removes frame (19), the fixed cover of lateral wall of pivot (306) is equipped with solid fixed ring (407), and solid fixed tube (402) that the multiple arrays of lateral wall fixedly connected with of solid fixed ring (407) set up, sliding connection has sliding tray (403) in fixed tube (402), and upper end fixedly connected with carriage release lever (404) of sliding tray (403), the other end of carriage release lever (404) runs through the tip and the fixedly connected with metal ball (405) of fixed tube (402), and the lateral wall cover of carriage release lever (404) is equipped with second spring (406).

5. The energy storage module of high-efficiency heat dissipation management of claim 3, wherein: vacuumizing mechanism (5) is including fixed aspiration tube (501) of establishing at movable plate (303) lateral wall of inserting, and the first check valve of fixedly connected with (502) in aspiration tube (501), the other end fixedly connected with connecting pipe (503) of aspiration tube (501), and the other end fixedly connected with outlet duct (504) of connecting pipe (503), fixedly connected with second check valve (505) in outlet duct (504), and the lateral wall fixedly connected with working tube (506) of connecting pipe (503), sliding connection has piston (507) in working tube (506), and the removal of piston (507) promotes through second pushing mechanism (6).

6. The energy storage module of efficient heat dissipation management of claim 5, wherein: the second pushing mechanism (6) comprises a pushing rod (601) fixedly connected to the bottom of the piston (507), a moving block (602) is fixedly connected to the lower end of the pushing rod (601), the moving block (602) is connected with the side wall of the connecting pipe (503) through a second resetting mechanism (7), a pushing block (603) is fixedly connected to the lower side wall of the moving block (602), a connecting shaft (604) is fixedly connected to the end portion of the rotating shaft (306), and a plurality of protruding blocks (605) arranged in an array are fixedly connected to the side wall of the connecting shaft (604).

7. The energy storage module of high-efficiency heat dissipation management of claim 6, wherein: the second reset mechanism (7) comprises two symmetrically arranged second T-shaped guide rods (701) inserted into the side wall of the moving block (602), the upper ends of the second T-shaped guide rods (701) are fixed with the side wall of the connecting pipe (503), and third springs (702) are sleeved on the side wall of the second T-shaped guide rods (701).

8. The energy storage module of high-efficient heat dissipation management of claim 1, characterized in that: atomizing mechanism (8) include fixed connection at communicating box (801) of removing frame (19) lateral wall, and the top fixedly connected with delivery pipe (802) of communicating box (801), atomizing pipe (803) that a plurality of L of bottom fixedly connected with of communicating box (801) appear to set up, and the lower extreme fixedly connected with atomizer (804) of atomizing pipe (803), the lateral wall of atomizing pipe (803) is provided with on-off mechanism (9) of its break-make of control.

9. The energy storage module of high-efficiency heat dissipation management of claim 8, wherein: the on-off mechanism (9) comprises a fixed cover (901) fixedly inserted on the side wall of the atomization tube (803), a sliding plate (902) is connected in the fixed cover (901) in a sliding mode, a third through hole (903) is formed in the bottom of the sliding plate (902), two first connecting blocks (904) symmetrically arranged are fixedly connected to the side wall of the sliding plate (902), a third T-shaped guide rod (907) is fixedly connected to the side wall of the first connecting block (904), a second connecting block (905) is sleeved on the side wall of the third T-shaped guide rod (907), the second connecting block (905) is fixed to the side wall of the fixed cover (901), a fourth spring (906) is sleeved on the side wall of the third T-shaped guide rod (907), and the sliding plate (902) is moved through a third pushing mechanism (10).

10. The energy storage module of efficient heat dissipation management of claim 9, wherein: third pushing mechanism (10) is including pushing plate (1001), and pushing plate (1001) includes inclined plane (1002), the first connecting plate (1003) of the lateral wall fixedly connected with of pushing plate (1001), and lateral wall fixedly connected with loop bar (1004) of first connecting plate (1003), the lateral wall cover of loop bar (1004) is equipped with sleeve pipe (1005), and the other end of sleeve pipe (1005) is fixed with the lateral wall of shell (14), the lateral wall fixedly connected with second connecting plate (1006) of pushing plate (1001), and the lateral wall rotation of second connecting plate (1006) is connected with threaded rod (1007), the lateral wall threaded connection of threaded rod (1007) has thread bush (1008), and the other end of thread bush (1008) is fixed with the lateral wall of shell (14), the lateral wall fixedly connected with second motor (1009) of second connecting plate (1006), and the output of second motor (1007) is fixed with the one end of threaded rod (1009).