CN216161800U - Energy storage battery thermal management system - Google Patents

Abstract

The utility model provides an energy storage battery thermal management system which comprises a box body, a cooling system and a plurality of rows of energy storage battery cabinets, wherein the cooling system and the energy storage battery cabinets are arranged in the box body; each row of energy storage battery cabinets are provided with a plurality of energy storage battery cabinets, a cabinet body frame and a plurality of energy storage battery boxes are arranged in each energy storage battery cabinet, each energy storage battery box is arranged in each cabinet body frame, and each energy storage battery box is internally provided with a liquid cooling plate and a battery cell assembly; the cooling system comprises a liquid cooling machine and a liquid cooling pipeline, and the liquid cooling machine and the liquid cooling pipeline are communicated; the liquid cooling pipeline comprises a plurality of groups of primary pipelines, a plurality of groups of secondary pipelines and a plurality of groups of tertiary pipelines which are sequentially communicated, each row of energy storage battery cabinets corresponds to one group of primary pipelines, each energy storage battery cabinet corresponds to one group of secondary pipelines, and each energy storage battery box corresponds to one group of tertiary pipelines; the third-stage pipeline is communicated with the liquid cooling plate. The utility model can realize uniform liquid feeding, effectively improve the cooling efficiency of the energy storage battery box and improve the temperature uniformity of each battery cell.

Description

Energy storage battery thermal management system

Technical Field

The utility model relates to the technical field of energy storage battery thermal management, in particular to an energy storage battery thermal management system.

Background

In the fields of household energy storage, large-scale energy storage and the like, high-capacity power batteries are gradually widely applied. The energy storage system is composed of a plurality of energy storage battery cabinets, and the energy storage battery cabinets are stacked by a plurality of battery boxes. The battery pack in the battery box is used as a core part of the whole energy storage system, and the working efficiency, the service life, the service performance and the safety of the battery pack are directly influenced by the working temperature. In the prior art, the heat dissipation of the electric core component mainly depends on the air or forced convection in the surrounding environment for heat dissipation, the heat dissipation effect is poor, and the heat dissipation structure in an air cooling mode is adopted, so that the heat dissipation time is long, and the heat dissipation efficiency is low.

Patent publication No. CN109935938A discloses an energy storage battery system and a battery thermal management system thereof, the energy storage battery system includes: the air conditioner comprises a box body, an air conditioning system and a plurality of rows of energy storage battery cabinets, wherein an air conditioning indoor unit of the air conditioning system is arranged at a preset position of each row of energy storage battery cabinets, and each row of energy storage battery cabinets corresponds to a main air duct; each row of energy storage battery cabinets, the air conditioner indoor unit and each main air duct are arranged in the box body, each row of energy storage battery cabinets comprise a plurality of energy storage battery cabinets, each energy storage battery cabinet is internally provided with a plurality of battery plug boxes, and each battery plug box is internally provided with a battery core assembly; and each energy storage battery cabinet is provided with a communicating air duct, and air blown out of each air conditioner indoor unit is conveyed to the communicating air duct of the corresponding energy storage battery cabinet through an air inlet and an air outlet of the corresponding main air duct and then is conveyed into the battery plug box through the communicating air duct. The system that this embodiment provided can realize even air supply, and is good to battery core radiating effect, improves the radiating efficiency. The battery thermal management system adopts an air cooling type heat dissipation structure, so that the heat dissipation time is long, and the heat dissipation efficiency is low.

SUMMERY OF THE UTILITY MODEL

In view of the defects in the prior art, the utility model aims to provide an energy storage battery thermal management system.

The energy storage battery thermal management system provided by the utility model comprises a box body, a cooling system and a plurality of rows of energy storage battery cabinets, wherein the cooling system and the energy storage battery cabinets are arranged in the box body;

each row of energy storage battery cabinets is provided with a plurality of energy storage battery cabinets, a cabinet body frame and a plurality of energy storage battery boxes are arranged in each energy storage battery cabinet, each energy storage battery box is arranged in the cabinet body frame, and a liquid cooling plate and a battery core assembly are arranged in each energy storage battery box;

the cooling system comprises a liquid cooling machine and a liquid cooling pipeline, and the liquid cooling machine and the liquid cooling pipeline are communicated;

the liquid cooling pipeline comprises a plurality of groups of primary pipelines, a plurality of groups of secondary pipelines and a plurality of groups of tertiary pipelines, each row of the energy storage battery cabinets corresponds to one group of the primary pipelines, each energy storage battery cabinet corresponds to one group of the secondary pipelines, and each energy storage battery box corresponds to one group of the tertiary pipelines;

the primary pipeline comprises a first liquid inlet pipeline and a first liquid return pipeline, the secondary pipeline comprises a second liquid inlet pipeline and a second liquid return pipeline, and the tertiary pipeline comprises a third liquid inlet pipeline and a third liquid return pipeline;

the liquid cooling machine is communicated with the first liquid inlet pipeline, one end, far away from the liquid cooling machine, of the first liquid inlet pipeline is communicated with the second liquid inlet pipeline, one end, far away from the first liquid inlet pipeline, of the second liquid inlet pipeline is communicated with the third liquid inlet pipeline, and one end, far away from the second liquid inlet pipeline, of the third liquid inlet pipeline is communicated with the liquid cooling board;

one end, far away from the third liquid inlet pipeline, of the liquid cooling plate is communicated with the third liquid return pipeline, one end, far away from the liquid cooling plate, of the third liquid return pipeline is communicated with the second liquid return pipeline, one end, far away from the third liquid return pipeline, of the second liquid return pipeline is communicated with the first liquid return pipeline, and one end, far away from the second liquid return pipeline, of the first liquid return pipeline is communicated with the liquid cooling machine.

Preferably, the first liquid inlet pipeline and the first liquid return pipeline are provided with a first flow regulating device;

a second flow regulating device is arranged on the second liquid inlet pipeline and the second liquid return pipeline;

and a third flow regulating device is arranged on the third liquid inlet pipeline and the third liquid return pipeline.

Preferably, a liquid inlet and a liquid outlet are arranged on the liquid cooling plate, the third liquid inlet pipeline is correspondingly communicated with the liquid inlet, and the third liquid return pipeline is correspondingly communicated with the liquid outlet.

Preferably, a pressure sensor is arranged on the liquid cooling pipeline.

Preferably, the liquid cooling pipeline is provided with a temperature sensor.

Preferably, the liquid cooling pipeline is provided with a pipeline exhaust valve.

Preferably, a heat transfer assembly is arranged between the liquid cooling plate and the electric core assembly, and the liquid cooling plate is connected with the electric core assembly through the heat transfer assembly.

Preferably, a heater is arranged in the liquid cooling machine.

Preferably, the infusion cross-sectional area of each primary pipeline is greater than or equal to the infusion cross-sectional area of each secondary pipeline, and the infusion cross-sectional area of each secondary pipeline is greater than or equal to the infusion cross-sectional area of each tertiary pipeline.

Preferably, the bottom of the energy storage battery box is provided with a sliding device and a fixing device which are matched with the cabinet body frame;

the sliding device is used for moving the energy storage battery box into the cabinet body frame, and the fixing device is used for fixedly connecting the cabinet body frame with the energy storage battery box.

Compared with the prior art, the utility model has the following beneficial effects:

1. the utility model can realize uniform liquid feeding, effectively improve the cooling efficiency of the energy storage battery box and improve the temperature uniformity of each battery cell;

2. the liquid cooling pipeline can reduce the space occupation of the energy storage system and effectively improve the space utilization rate of the energy storage system;

3. the utility model can effectively control the flow of the cooling liquid input to each battery box through the flow adjusting device, thereby reducing the temperature difference among the battery boxes;

4. the utility model can realize the heating of the battery box through the heater.

Drawings

Other features, objects and advantages of the utility model will become more apparent upon reading of the detailed description of non-limiting embodiments with reference to the following drawings:

fig. 1 is a schematic front view of an energy storage battery thermal management system of the present invention;

fig. 2 is a schematic top view of an energy storage battery thermal management system of the present invention;

FIG. 3 is a schematic structural diagram of an energy storage battery box according to the present invention;

fig. 4 is a schematic flow diagram of a coolant of the energy storage battery thermal management system of the utility model;

fig. 5 is a schematic structural view of the energy storage battery thermal management system according to the present invention, highlighting a cabinet frame;

FIG. 6 is a schematic diagram of a heater according to the present invention showing the structure of the energy storage battery thermal management system;

fig. 7 is a schematic structural diagram of the thermal management system of the energy storage battery according to the present invention, which shows the sliding device and the fixing device.

The figures show that:

box body 1 energy storage battery box 5

Cooling system 2 liquid cooling plate 6

Liquid cooling pipeline 201 electric core assembly 7

Primary line 2011 first flow regulator 8

First liquid inlet pipeline 20111 and second flow regulating device 9

First return line 20112 third flow rate adjustment device 10

Liquid inlet 11 of secondary pipeline 2012

Second liquid inlet pipe 20121 liquid outlet 12

Second liquid return pipeline 20122 pressure sensor 13

Three-stage pipeline 2013 temperature sensor 14

Third liquid inlet pipe 20131 pipe exhaust valve 15

Third liquid return line 20132 heat transfer assembly 16

Sliding device 17 of liquid cooling machine 201

Fixing device 18 for energy storage battery cabinet 3

Cabinet frame 4

Detailed Description

The present invention will be described in detail with reference to specific examples. The following examples will assist those skilled in the art in further understanding the utility model, but are not intended to limit the utility model in any way. It should be noted that it would be obvious to those skilled in the art that various changes and modifications can be made without departing from the spirit of the utility model. All falling within the scope of the present invention.

As shown in fig. 1 to 7, the utility model provides an energy storage battery thermal management system, which comprises a box body 1, a cooling system 2 and a plurality of rows of energy storage battery cabinets 3, wherein the cooling system 2 and the energy storage battery cabinets 3 are installed in the box body 1.

Every row of energy storage battery cabinet 3 is provided with a plurality of energy storage battery cabinet 3, in-service use, can set up the energy storage battery cabinet 3 of corresponding quantity according to actual need, is provided with cabinet body frame 4 and a plurality of energy storage battery case 5 in the energy storage battery cabinet 3, in-service use, can set up the energy storage battery case 5 of corresponding quantity according to actual need, and energy storage battery case 5 sets up in cabinet body frame 4, is provided with liquid cooling board 6 and electric core subassembly 7 in the energy storage battery case 5.

Be provided with heat transfer assembly 16 between liquid cold plate 6 and the electric core subassembly 7, be connected through heat transfer assembly 16 between liquid cold plate 6 and the electric core subassembly 7, electric core subassembly 7 includes a plurality of battery core, is provided with heat transfer assembly 16 between every battery core, and heat transfer assembly 16 can be for heat conduction gasket, heat conduction glue, heat conduction structure glue, structure glue or bubble cotton. A heater is arranged in the water cooler.

Cooling system 2 includes liquid cooling machine 201 and liquid cooling pipeline 201, liquid cooling machine 201 with liquid cooling pipeline 201 intercommunication sets up, and liquid cooling pipeline 201 includes a plurality of one-level pipelines 2011 of group, a plurality of second grade pipelines 2012 of group and a plurality of three-level pipelines 2013 of group, and every energy storage battery cabinet 3 that is listed as corresponds a set of one-level pipeline 2011, and every energy storage battery cabinet 3 corresponds a set of second grade pipeline 2012, and every energy storage battery case 5 corresponds a set of three-level pipeline 2013. The cross-sectional area of the primary line 2011 is not less than the cross-sectional area of the secondary line 2012, and the cross-sectional area of the secondary line 2012 is not less than the cross-sectional area of the tertiary line 2013.

In practical application, the primary pipeline 2011, the secondary pipeline 2012 and the tertiary pipeline 2013 are communicated, the tertiary pipeline 2013 is communicated with the liquid cooling plate 6, and the primary pipeline 2011, the secondary pipeline 2012 and the tertiary pipeline 2013 are made of metal, nylon or rubber. The liquid cooling machine 201 and the primary pipeline 2011 are connected through a fixing device, and the fixing device can be a clamp or a flange. The connection between the primary pipeline 2011 and the secondary pipeline 2012 is a flexible connection, which can be made of metal pieces, nylon materials or rubber materials. The second-stage pipeline 2012 and the third-stage pipeline 2013 are connected through a fixing device, and the fixing device can be a quick connector or a hoop. The third-stage pipeline 2013 and the liquid cooling plate 6 are connected through a fixing device, and the fixing device can be a quick connector or a hoop.

The primary line 2011 includes a first liquid inlet line 20111 and a first liquid return line 20112, the secondary line 2012 includes a second liquid inlet line 20121 and a second liquid return line 20122, and the tertiary line 2013 includes a third liquid inlet line 20131 and a third liquid return line 20132. The liquid cooler 201 is communicated with a first liquid inlet pipeline 20111, one end, far away from the liquid cooler 201, of the first liquid inlet pipeline 20111 is communicated with a second liquid inlet pipeline 20121, one end, far away from the first liquid inlet pipeline 20111, of the second liquid inlet pipeline 20121 is communicated with a third liquid inlet pipeline 20131, and one end, far away from the second liquid inlet pipeline 20121, of the third liquid inlet pipeline 20131 is communicated with the liquid cooling plate 6. One end of the liquid cooling plate 6, which is far away from the third liquid inlet pipeline 20131, is communicated with the third liquid return pipeline 20132, one end of the third liquid return pipeline 20132, which is far away from the liquid cooling plate 6, is communicated with the second liquid return pipeline 20122, one end of the second liquid return pipeline, which is far away from the third liquid return pipeline 20132, is communicated with the first liquid return pipeline 20112, and one end of the first liquid return pipeline 20112, which is far away from the second liquid return pipeline 20122, is communicated with the liquid cooling machine 201.

The liquid cooling plate 6 is provided with a liquid inlet 11 and a liquid outlet 12, the third liquid inlet pipe 20131 is correspondingly communicated with the liquid inlet 11, and the third liquid return pipe 20132 is correspondingly communicated with the liquid outlet 12. The primary pipe 2011 is provided with a liquid injection port 20, and the liquid injection port 20 is provided on the first return pipe. The liquid cooling pipelines 201 each include a liquid inlet and a liquid outlet, the liquid outlet on the primary pipeline 2011 corresponds to the liquid inlet on the corresponding secondary pipeline 2012, and the liquid outlet on the secondary pipeline 2012 corresponds to the liquid inlet on the corresponding tertiary pipeline 2013. The liquid cooling machine 201 is provided with a liquid outlet and a liquid return port, the liquid outlet on the liquid cooling machine 201 corresponds to the liquid inlet on the corresponding primary pipeline 2011, and the liquid return port on the liquid cooling machine 201 corresponds to the liquid outlet on the corresponding primary pipeline 2011.

The first liquid inlet pipe 20111 and the first liquid return pipe 20112 are provided with first flow adjusting devices 8, the first flow adjusting devices 8 can be flow adjusting valves, the second liquid inlet pipe 20121 and the second liquid return pipe 20122 are provided with second flow adjusting devices 9, and the third liquid inlet pipe 20131 and the third liquid return pipe 20132 are provided with third flow adjusting devices 10. Liquid cooling pipeline 201 is last to be provided with pressure sensor 13 and temperature sensor 14, and pressure sensor 13 and temperature sensor 14 set up on one-level pipeline 2011, and pressure sensor 13 sets up to two in this embodiment, and temperature sensor 14 sets up to two, and a pressure sensor 13 and a temperature sensor 14 set up on first feed liquor pipeline 20111, and a pressure sensor 13 and a temperature sensor 14 set up on first liquid return pipeline 20112. The liquid cooling pipeline 201 is provided with a pipeline exhaust valve 15, and the pipeline exhaust valve 15 is arranged on the first liquid return pipeline 20112.

The bottom of the energy storage battery box 5 is provided with a sliding device 17 and a fixing device 18 which are matched with the cabinet body frame 4, the sliding device 17 is used for moving the energy storage battery box 5 into the cabinet body frame 4, the fixing device 18 is used for fixedly connecting the cabinet body frame 4 with the energy storage battery box 5, the sliding device 17 can be a pulley, and the fixing device 18 can be a fastening bolt.

The cooling liquid flowing out of the liquid cooler 201 is conveyed to the second liquid inlet pipeline 20121 of the corresponding second-level pipeline 2012 through the first liquid inlet pipeline 20111 of the first-level pipeline 2011, is conveyed to the third liquid inlet pipeline 20131 of the corresponding third-level pipeline 2013 through the second liquid inlet pipeline 20121 of the second-level pipeline 2012, is sent into the liquid cooling plate 6 of the energy storage battery box 5, and finally flows back to the liquid cooler 201 through the third liquid return pipeline 20132, the second liquid return pipeline 20122 and the first liquid return pipeline 20112.

The liquid cooling system that this embodiment provided can realize evenly sending liquid, effectively improves energy storage battery box 5's cooling efficiency, promotes the temperature uniformity of each electric core.

In the description of the present application, it is to be understood that the terms "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", and the like indicate orientations or positional relationships based on those shown in the drawings, and are only for convenience in describing the present application and simplifying the description, but do not indicate or imply that the referred device or element must have a specific orientation, be constructed in a specific orientation, and be operated, and thus, should not be construed as limiting the present application.

The foregoing description of specific embodiments of the present invention has been presented. It is to be understood that the present invention is not limited to the specific embodiments described above, and that various changes or modifications may be made by one skilled in the art within the scope of the appended claims without departing from the spirit of the utility model. The embodiments and features of the embodiments of the present application may be combined with each other arbitrarily without conflict.

Claims (10)

1. The energy storage battery thermal management system is characterized by comprising a box body (1), a cooling system (2) and a plurality of rows of energy storage battery cabinets (3), wherein the cooling system (2) and the energy storage battery cabinets (3) are arranged in the box body (1);

each row of energy storage battery cabinets (3) is provided with a plurality of energy storage battery cabinets (3), a cabinet body frame (4) and a plurality of energy storage battery boxes (5) are arranged in each energy storage battery cabinet (3), each energy storage battery box (5) is arranged in each cabinet body frame (4), and each energy storage battery box (5) is internally provided with a liquid cooling plate (6) and a battery cell assembly (7);

the cooling system (2) comprises a liquid cooling machine (202) and a liquid cooling pipeline (201), wherein the liquid cooling machine (202) and the liquid cooling pipeline (201) are communicated;

the liquid cooling pipeline (201) comprises a plurality of groups of primary pipelines (2011), a plurality of groups of secondary pipelines (2012) and a plurality of groups of tertiary pipelines (2013), each row of the energy storage battery cabinet (3) corresponds to one group of the primary pipelines (2011), each energy storage battery cabinet (3) corresponds to one group of the secondary pipelines (2012), and each energy storage battery box (5) corresponds to one group of the tertiary pipelines (2013);

the primary pipeline (2011) comprises a first liquid inlet pipeline (20111) and a first liquid return pipeline (20112), the secondary pipeline (2012) comprises a second liquid inlet pipeline (20121) and a second liquid return pipeline (20122), and the tertiary pipeline (2013) comprises a third liquid inlet pipeline (20131) and a third liquid return pipeline (20132);

the liquid cooler (202) is communicated with the first liquid inlet pipeline (20111), one end, far away from the liquid cooler (202), of the first liquid inlet pipeline (20111) is communicated with the second liquid inlet pipeline (20121), one end, far away from the first liquid inlet pipeline (20111), of the second liquid inlet pipeline (20121) is communicated with the third liquid inlet pipeline (20131), and one end, far away from the second liquid inlet pipeline (20121), of the third liquid inlet pipeline (20131) is communicated with the liquid cooling plate (6);

one end, far away from the third liquid inlet pipeline (20131), of the liquid cooling plate (6) is communicated with the third liquid return pipeline (20132), one end, far away from the liquid cooling plate (6), of the third liquid return pipeline (20132) is communicated with the second liquid return pipeline (20122), one end, far away from the third liquid return pipeline (20132), of the second liquid return pipeline (20122) is communicated with the first liquid return pipeline (20112), and one end, far away from the second liquid return pipeline (20122), of the first liquid return pipeline (20112) is communicated with the liquid cooling machine (202).

2. The energy storage battery thermal management system according to claim 1, wherein a first flow regulating device (8) is disposed on the first liquid inlet line (20111) and the first liquid return line (20112);

a second flow regulating device (9) is arranged on the second liquid inlet pipeline (20121) and the second liquid return pipeline (20122);

and a third flow regulating device (10) is arranged on the third liquid inlet pipeline (20131) and the third liquid return pipeline (20132).

3. The energy storage battery thermal management system according to claim 1, wherein the liquid cooling plate (6) is provided with a liquid inlet (11) and a liquid outlet (12), the third liquid inlet pipeline (20131) is correspondingly communicated with the liquid inlet (11), and the third liquid return pipeline (20132) is correspondingly communicated with the liquid outlet (12).

4. The energy storage battery thermal management system of claim 1, wherein a pressure sensor (13) is disposed on the liquid cooling pipeline (201).

5. The energy storage battery thermal management system of claim 1, wherein a temperature sensor (14) is disposed on the liquid cooling pipeline (201).

6. The energy storage battery thermal management system of claim 1, wherein the liquid cooling pipeline (201) is provided with a pipeline exhaust valve (15).

7. The energy storage battery thermal management system according to claim 1, characterized in that a heat transfer assembly (16) is arranged between the liquid-cooled plate (6) and the electric core assembly (7), and the liquid-cooled plate (6) and the electric core assembly (7) are connected through the heat transfer assembly (16).

8. The energy storage battery thermal management system of claim 1, wherein a heater is disposed within the liquid cooler (202).

9. The energy storage battery thermal management system of claim 1, wherein a cross-sectional area of the infusion of each primary line (2011) is equal to or greater than a cross-sectional area of the infusion of the secondary line (2012), and a cross-sectional area of the infusion of each secondary line (2012) is equal to or greater than a cross-sectional area of the infusion of the tertiary line (2013).

10. The energy storage battery thermal management system according to claim 1, characterized in that the energy storage battery box (5) is provided at the bottom with a sliding device (17) and a fixing device (18) which are matched with the cabinet frame (4);

the sliding device (17) is used for moving the energy storage battery box (5) into the cabinet body frame (4), and the fixing device (18) is used for fixedly connecting the cabinet body frame (4) with the energy storage battery box (5).

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