CN219476765U - Formation all-in-one machine equipment - Google Patents

Abstract

The application relates to a formation integrated machine device, and relates to the field of battery formation devices, which comprises a cabinet body, a power module, a heat exchange assembly, a temperature sensor and a controller; the cabinet body is provided with a power supply cavity and a formation cavity; the power module is positioned in the power cavity, the formation cavity is used for placing the battery monomer, the formation cavity is thermally isolated from the power cavity, and the formation cavity is thermally isolated from the outside of the cabinet body; the heat exchange component exchanges heat with air in the formation cavity; the temperature sensor is used for measuring and quantifying the temperature in the cavity and is connected with the controller in a signal manner; the controller is in signal connection with the heat exchange component and is used for controlling the heat exchange component to heat the formation cavity when the temperature sensor measures that the temperature in the formation cavity is lower than a set value. The formation cavity, the power cavity and the outside are thermally isolated in the cabinet body, and the energy consumption and the occupied area of formation equipment are reduced.

Description

Formation all-in-one machine equipment

Technical Field

The application relates to the field of battery formation equipment, in particular to formation integrated machine equipment.

Background

At present, the formation of the lithium battery is important to the influence of the performance of the lithium battery, and the formation is the first charging process of the battery monomer after the liquid injection of the lithium battery, and the process can activate active substances in the battery monomer to activate the lithium battery.

The production plant is provided with a formation room and a device room. The formation cabinet is arranged in the formation room, the battery monomer is arranged in the formation cabinet, the battery monomer is formed in the formation cabinet, the temperature in the formation room is regulated to be about 45 ℃ by an air conditioning system, and the formation cabinet is communicated with the formation room, so that the temperature in the formation cabinet is controlled to be about 45 ℃.

The power supply cabinet is arranged in the equipment room, the power supply module is arranged in the power supply cabinet, and a large amount of heat is generated when the power supply module works, so that the power supply module needs to be radiated. The temperature in the equipment room is regulated to be less than 30 ℃ through the air conditioning system, and the battery cell cabinet is communicated with the equipment room, so that the temperature in the battery cell cabinet is controlled to be below 30 ℃.

The arrangement of the formation room and the equipment room occupies a larger space, and the temperature energy consumption of the formation room is maintained to be higher.

Disclosure of Invention

The application provides a formation all-in-one machine equipment, which has the effects of reducing the energy consumption and the occupied area of the formation equipment.

The application provides a formation integrated machine device, which comprises a cabinet body, a power module, a heat exchange assembly, a temperature sensor and a controller; the cabinet body is provided with a power supply cavity and a formation cavity; the power module is positioned in the power cavity, the formation cavity is used for placing a battery monomer, the formation cavity is thermally isolated from the power cavity, and the formation cavity is thermally isolated from the outside of the cabinet body; the heat exchange component exchanges heat with air in the formation cavity; the temperature sensor measures the temperature in the formation cavity, and is in signal connection with the controller; the controller is in signal connection with the heat exchange component, and the controller is used for controlling the heat exchange component to heat the formation cavity when the temperature sensor measures that the temperature in the formation cavity is lower than a set value.

In the technical scheme, the formation cavity and the power cavity are arranged in the same cabinet body, and the power module does not need to occupy an equipment room additionally; the formation cavity is thermally isolated from the power cavity and the external environment of the cabinet body, so that the normal operation of the power module in the cabinet body is ensured; the temperature sensor measures the temperature of the formation cavity, and the controller controls the heat exchange assembly to work by acquiring the temperature measured by the temperature sensor, so that the temperature of the formation cavity is kept to be the design environment temperature of battery monomer formation; only the temperature of the formation cavity is controlled to be the temperature of the battery monomer with relatively high room temperature during formation, the temperature of the formation room where the cabinet body is positioned is controlled to be the room temperature, the energy consumption of the formation room is reduced, and the energy consumption of the formation integrated machine equipment is reduced.

Drawings

FIG. 1 is a schematic elevational structural view of an embodiment;

FIG. 2 is a schematic diagram of the relative positions of a forming chamber tray and a forming assembly according to one embodiment.

1. A cabinet body; 11. a power supply cavity; 12. forming a cavity; 13. a heat insulating plate; 14. a heat radiation hole; 15. a first door; 16. a second door; 2. a heat exchange assembly; 21. a heat exchanger; 22. a second fan; 23. a third fan; 3. a power module; 4. a temperature sensor; 51. a first fan; 52. an air heat exchanger; 6. a tray; 7. forming the assembly.

Detailed Description

The present application is further described in detail below by way of the accompanying drawings and examples. The features and advantages of the present application will become more apparent from the description.

The word "exemplary" is used herein to mean "serving as an example, embodiment, or illustration. Any embodiment described herein as "exemplary" is not necessarily to be construed as preferred or advantageous over other embodiments. Although various aspects of the embodiments are illustrated in the accompanying drawings, the drawings are not necessarily drawn to scale unless specifically indicated.

In addition, the technical features described below in the different embodiments of the present application may be combined with each other as long as they do not collide with each other.

The embodiment of the application discloses a formation integrated machine device which is used when a battery monomer is formed, wherein the battery monomer is placed into the formation integrated machine device, and the formation of the battery monomer is carried out within a set temperature range.

Referring to fig. 1, a chemical-mechanical device includes a cabinet 1, a heat exchange assembly 2, a power module 3, a temperature sensor 4, and a controller.

The cabinet body 1 is provided with a power supply cavity 11 and a formation cavity 12; the power module 3 is located in the power cavity 11, and the formation cavity 12 is used for placing a battery cell.

Illustratively, the power supply chamber 11 and the formation chamber 12 are disposed in a vertical order, with the power supply chamber 11 being located above the formation chamber 12. Alternatively, the power supply cavities 11 have two formation cavities 12 located between the two power supply cavities 11, and the power supply cavities 11, the formation cavities 12, and the power supply cavities 11 are sequentially disposed in the horizontal direction. Optionally, the cabinet body 1 includes a power cavity 11, a heat insulation cavity and a formation cavity 12, where the power cavity 11, the heat insulation cavity and the formation cavity 12 are sequentially arranged from top to bottom.

When in use, the battery monomer is placed in the formation cavity 12, and the power module 3 converts high-voltage alternating current in the power grid into low-voltage direct current for formation of the power supply monomer.

In the prior art, a power module is placed in a power cabinet, and the power cabinet is placed between power supplies. The battery monomer is placed in the formation cabinet, and the formation cabinet is placed in the formation room, and the power supply cabinet and the formation cabinet occupy a large amount of factory space.

In the scheme, the power module 3 and the battery monomer are placed in the same cabinet body 1, so that the factory space occupied by formation equipment can be reduced.

The formation cavity 12 is thermally isolated from the power cavity 11, and the formation cavity 12 is thermally isolated from the outside of the cabinet 1.

The power module 3 and the battery are formed by single body, and the environmental temperature needs to be controlled. In this embodiment, the environment temperature of the power module 3 during operation is 30 degrees celsius or less, and the environment temperature during battery cell formation is 40 to 50 degrees celsius. The temperature in the factory is room temperature, which is illustrated by way of example at 25 degrees celsius.

In the prior art, the power module and the battery monomer are required to be used in different environmental temperatures, so that the power module is placed between power supplies, and the formation cabinet is placed between formation rooms. The temperature between the power supplies is room temperature, the temperature between the formation cabinets is controlled to be 40-50 ℃, the formation cabinets are communicated with each other, air between the formation cabinets is circulated, and the temperature in the formation cabinets is kept to be 40-50 ℃. However, the whole space between the chemical reaction is large, and the heat loss is large.

In this scheme, the formation cavity 12 is thermally isolated from the power cavity 11, the formation cavity 12 is thermally isolated from the outside of the cabinet body 1, and the temperature of the formation cavity 12 in the cabinet body 1 needs to be controlled between 40 and 50 ℃, so that the outside temperature of the cabinet body 1 can be room temperature. The temperature in the power cavity 11 and the formation cavity 12 have a temperature difference, the temperature in the formation cavity 12 is controlled between 40 and 50 ℃, and the temperature in the power cavity 11 is below 30 ℃, so that a battery monomer and a power module 3 can be simultaneously placed in different cavities of the cabinet body 1, the power module 3 can be placed in the cabinet body, and the single battery can be formed in the cabinet body 1.

The heat exchange assembly 2, the temperature sensor 4 and the controller form a temperature control system to control the temperature in the formation chamber 12. The heat exchange assembly 2 exchanges heat with air within the forming chamber 12. The temperature sensor 4 is located in the formation cavity 12, and the temperature sensor 4 is in signal connection with the controller.

The controller is in signal connection with the heat exchange assembly 2, and is used for controlling the heat exchange assembly 2 to heat the formation cavity 12 when the temperature sensor 4 measures that the temperature in the formation cavity 12 is lower than a set value.

Specifically, the temperature sensors 4 are disposed in a plurality of forming chambers 12, the plurality of temperature sensors 4 acquire temperatures at different positions in the forming chambers 12, and after the controller acquires temperature values measured by the plurality of temperature sensors 4, the temperature condition of the forming chambers 12 is determined, and the controller controls the heat exchange assembly 2 to heat the forming chambers 12.

It should be noted that, since the temperature in the formation chamber 12 is higher than the temperature of the outside of the cabinet 1 and the power supply chamber 11, the formation chamber 12 will transfer heat to the outside, and the heat exchange assembly 2 is used to heat the temperature in the formation chamber 12 to supplement the heat loss of the formation chamber 12. The controller may control the heat exchange assembly 2 to cease operation when the temperature within the formation chamber 12 exceeds a set maximum temperature, which in this embodiment is illustrated by way of example at 49 degrees celsius.

In this scheme, through the temperature in the formation chamber 12 is regulated and controlled to the heat exchange component 2, the temperature sensor 4 and the controller, the temperature in the formation chamber 12 is in the set temperature interval, so that the environment temperature when the single battery is formed can be maintained only by controlling the temperature in the formation chamber 12, and the energy loss required for relatively maintaining the temperature between the formation cabinets is reduced.

Referring to fig. 1, as an alternative, the heat insulation board 13 is further included, the heat insulation board 13 is fixedly connected with the cabinet 1, and the heat insulation board 13 is located between the power cavity 11 and the formation cavity 12.

The heat insulating plate 13 is a plate having a heat insulating effect, so that thermal insulation is formed between the power supply chamber 11 and the formation chamber 12. Illustratively, the heat insulating plate 13 is a rigid plate, the heat insulating plate 13 has a hollow square inner cavity, and the square inner cavity of the partition plate is filled with heat insulating cotton or heat insulating fiber.

The heat insulation plate 13 insulates the formation cavity 12 and the power supply cavity 11, so that heat in the formation cavity 12 is reduced to be transferred into the power supply cavity 11, heat dissipation in the formation cavity 12 is reduced, and cooling of the power supply cavity 11 is facilitated.

The power module 3 comprises an alternating current/direct current converter and a direct current/direct current converter, the working environment temperature of the power module 3 is below 30 ℃, heat can be generated when the power module 3 works, the power module 3 needs to be radiated, and the influence of the overhigh temperature in the power cavity 11 on the work of the power module 3 is avoided.

The heat isolation between the formation cavity 12 and the outside of the cabinet body 1 is illustrated, and the formation cavity 12 of the cabinet body 1 is relatively closed with the outside of the cabinet body 1 so as to reduce heat transfer between the formation cavity 12 and the cabinet body 1; and be fixed with the insulating part on the cabinet body 1, the insulating part is thermal-insulated foam, and the insulating part glues the lateral wall inboard that encloses into formation chamber 12 on the cabinet body 1, and the insulating part further reduces the heat transfer between formation chamber 12 and the cabinet body 1.

Referring to fig. 1, as an alternative, the cabinet 1 is provided with a heat dissipation hole 14, and the power cavity 11 is in communication with the heat dissipation hole 14.

Specifically, the heat dissipation holes 14 are provided in plurality, and the heat dissipation holes 14 are communicated with the power cavity 11 and the outside of the cabinet body 1. Illustratively, the plurality of heat dissipation holes 14 are respectively located at the upper ends of the side walls of the cabinet body 1, and optionally, the upper ends of the side walls of the cabinet body 1 are formed by splicing and fixing grid plates, and the heat dissipation holes 14 are mesh holes of the grid plates; or the heat dissipation hole 14 is positioned at the upper end of the cabinet 1.

After the power cavity 11 is communicated with the outside of the cabinet body 1 through the heat dissipation holes 14, air in the power cavity 11 and air outside the cabinet body 1 flow mutually, and the flowing air takes away heat generated by the power module 3 to cool the power cavity 11.

Referring to fig. 1, as an alternative, the air conditioner further includes a first fan 51, the first fan 51 is disposed in the power cavity 11, and the first fan 51 drives air to flow out of the power cavity 11.

Specifically, the first fan 51 is fixed on the side wall of the cabinet body 1, and the air outlet direction of the first fan 51 is along the horizontal direction and faces the power module.

After the first fan 51 is started, the air flow in the power cavity 11 is driven, and when the first fan 51 is turned off, the air flow rate in the power cavity 11 is increased, and the air flow rate in contact with the power module 3 is increased; when the first fan 51 drives air around the side wall of the cabinet body 1 to flow to the power supply module, air outside the cabinet body 1 enters the power supply cavity 11 through the heat dissipation holes 14, the air flow between the power supply cavity 11 and the air flow outside the cabinet body 1 is increased, and the cooling efficiency of the power supply module 3 is improved.

Referring to fig. 1, as an alternative, the air heat exchanger 52 is further included, the air heat exchanger 52 is disposed in the power cavity 11, and the air heat exchanger 52 cools the power cavity 11.

Specifically, the temperature of the liquid flowing through the air heat exchanger 52 is lower than room temperature. Illustratively, water at a temperature of 10 degrees Celsius is circulated within the air heat exchanger 52. The air heat exchanger 52 absorbs heat in the power supply cavity 11, cools the power supply cavity 11, and improves the cooling efficiency of the power supply cavity 11.

The air heat exchanger 52 and the power module 3 are sequentially arranged along a first direction, and the first direction is a direction in which the first fan 51 drives air to flow.

Illustratively, the first blower 51, the air heat exchanger 52, and the power module 3 are disposed in this order along the first direction. Optionally, the air heat exchanger 52, the first fan 51, and the power module 3 are sequentially disposed along the first direction. Or the air heat exchanger 52, the power module 3, and the first blower 51 are sequentially disposed in the first direction.

When the air conditioner is used, the first fan 51 drives the air cooled by the air heat exchanger 52 to flow to the power module 3 to cool the power module 3, the temperature of the air is increased after the air flows through the power module 3, and the air with the increased temperature flows out of the power cavity 11.

The air contacting with the power module 3 is cooled by the air heat exchanger 52, and the air flowing out of the power cavity 11 is the air absorbing the heat of the power module 3, so that the cooling efficiency of the first fan 51 and the air heat exchanger 52 to the power cavity 11 is higher.

Referring to fig. 1, as an alternative, the heat exchange assembly 2 includes a heat exchanger 21 and a second fan 22; the second fan 22 drives the air in the formation chamber 12 to flow to the heat exchanger 21.

The controller is configured to control the rotation speed of the second fan 22 to increase and/or the flow rate of the medium in the heat exchanger 21 to increase when the temperature measured by the temperature sensor 4 is lower than a set value.

The heat exchanger is filled with water having a temperature higher than that in the formation chamber 12, and the temperature of the air increases after passing through the heat exchanger. Illustratively, the temperature of the water circulated within the heat exchanger is 60 degrees celsius.

The second fan 22 is fixed in the cabinet 1, and the second fan 22 drives the air passing through the heat exchanger 21 to flow, and the flowing direction faces the battery cell.

In the present embodiment, the controller controls the rotation speed of the second fan 22 to increase and the flow rate of the medium in the heat exchanger 21 to increase. In other embodiments, the controller controls the rotational speed of the second fan 22 to increase, and the flow rate of the medium in the heat exchanger 21 is kept stable. Or the controller controls the flow rate of the medium in the heat exchanger 21 to increase, and the rotation speed of the second fan 22 is kept stable.

In other embodiments, the cabinet 1 is not provided with the heat dissipation hole 14, the power cavity 11 is thermally isolated from the outside of the cabinet 1, the air heat exchanger 52 is disposed in the power cavity 11, and the air heat exchanger 52 absorbs heat in the power cavity 11.

Further, in order to improve the heat absorption efficiency of the air heat exchanger 52, a fan is disposed in the power cavity 11, and the fan drives air in the power cavity 11 to flow through the air heat exchanger 52.

Referring to fig. 1, as an alternative, the integrated machine further includes a tray 6 located in the forming chamber 12, and the tray 6 is used for placing the battery cells.

Specifically, the battery cells are placed on the tray 6, the tray 6 is provided with a plurality of trays 6, and the plurality of trays 6 are stacked in sequence along the vertical direction.

The tray 6 includes a body on which the battery cells are placed, and a plurality of protrusions supporting the body and separating two bodies of adjacent two trays 6. The body is a rectangular plate, the bulges are positioned at the upper end of the tray 6, the bulges are four, and the four bulges are respectively positioned at the end corners of the body one by one. When two trays 6 are stacked in proper order along vertical, the tray 6 that defines the top is the second tray, and the tray 6 of below is first tray, and the body lower surface of second tray contacts with the protruding upper surface of first tray, and the battery monomer on the first tray sets up along vertical interval with the second tray.

The heat exchange assemblies 2 are arranged at two sides opposite to the tray 6, the two heat exchange assemblies 2 are respectively positioned at two opposite sides of the tray 6, and the blowing direction of the two heat exchange assemblies 2 is towards the tray 6.

In particular, the blowing directions of the two heat exchange assemblies 2 are opposite. The heat exchange assemblies 2 are blown relatively towards the tray 6, so that the heat exchange areas of the single heat exchange assemblies 2 to the battery cells on the tray 6 are relatively less, and the consistency of the temperature of the battery cells on the tray 6 is improved.

The heat exchange assembly 2 further comprises a third fan 23, and the third fan 23 is located in the formation chamber 12; the third fan 23 and the second fan 22 drive the air in the formation chamber 12 to circulate.

Specifically, the third fan 23 and the second fan 22 are arranged at intervals along the vertical direction, the second fan 22 is located at the top end of the formation cavity 12, and the third fan 23 is located at the bottom end of the formation cavity 12. The air inlet of the third fan 23 is horizontally arranged, and the air outlet faces the second fan 22 along the vertical direction.

Referring to fig. 2, the opposite ends of the cabinet body 1 are respectively provided with a first hole and a second hole, the first hole is located at the front end of the cabinet body 1, and the second hole is located at the rear end of the cabinet body 1.

The integrated formation machine equipment further comprises a formation assembly 7, a first door 15 and a second door 16; wherein, the formation component 7 is located in the formation cavity 12, and the formation component 7 is used for forming the battery cell.

The formation assemblies 7 are positioned on two sides of the tray 6, and probes on the formation assemblies 7 are in conductive connection with poles on the battery cells. The formation assembly 7 is in sliding connection with the cabinet body 1, and the sliding direction is along the front-back direction of the cabinet body 1.

The first door 15 closes the first hole and the second door 16 closes the second hole. The first hole accommodates the pallet 6 in and out of the forming chamber 12, and the second hole accommodates the forming assembly 7 in and out of the forming chamber 12.

After the first door 15 is opened, the tray 6 can be moved into or out of the tray 6, the battery cells are placed on the tray 6, and the battery cells enter and exit the formation chamber 12 along with the tray 6. When the formation assembly 7 needs to be maintained, the second door 16 is opened, the formation assembly 7 is moved out of the cabinet body 1 from the rear end of the cabinet body 1, and the formation assembly 7 is convenient to overhaul.

In the description of the present application, it should be noted that the directions or positional relationships indicated by the terms "upper", "lower", "inner", "outer", "front", "rear", "left", "right", etc. are based on the directions or positional relationships in the working state of the present application, are merely for convenience of description and simplification of description, and do not indicate or imply that the apparatus or element to be referred to must have a specific orientation, be configured and operated in a specific orientation, and thus should not be construed as limiting the present application.

In the description of the present application, it should be noted that the terms "mounted," "connected," and "connected" are to be construed broadly, unless explicitly specified and limited otherwise. The specific meaning of the terms in this application will be understood by those of ordinary skill in the art in a specific context.

The present application has been described in connection with the preferred embodiments, but these embodiments are merely exemplary and serve only as illustrations. On the basis of this, many alternatives and improvements can be made to the present application, which fall within the scope of protection of the present application.

Claims (10)

1. The integrated equipment for formation is characterized by comprising a cabinet body, a power module, a heat exchange component, a temperature sensor and a controller; wherein,,

the cabinet body is provided with a power supply cavity and a formation cavity; the power module is positioned in the power cavity, the formation cavity is used for placing a battery monomer, the formation cavity is thermally isolated from the power cavity, and the formation cavity is thermally isolated from the outside of the cabinet body;

the heat exchange component exchanges heat with air in the formation cavity;

the temperature sensor measures the temperature in the formation cavity, and is in signal connection with the controller;

the controller is in signal connection with the heat exchange component, and the controller is used for controlling the heat exchange component to heat the formation cavity when the temperature sensor measures that the temperature in the formation cavity is lower than a set value.

2. The integrated chemical-mechanical device of claim 1, further comprising a heat shield fixedly coupled to the cabinet, the heat shield positioned between the power cavity and the chemical-mechanical cavity.

3. The integrated machine equipment according to claim 1, wherein the cabinet body is provided with a heat dissipation hole, and the power supply cavity is communicated with the heat dissipation hole.

4. The integrated machine apparatus of claim 3, further comprising a first fan disposed in the power cavity, the first fan driving air out of the power cavity.

5. The integrated machine equipment of claim 4, further comprising an air heat exchanger disposed within the power cavity, the air heat exchanger configured to cool the power cavity.

6. The integrated machine equipment of claim 5, wherein the air heat exchanger and the power module are arranged in sequence along a first direction, the first direction being a direction in which a first fan drives air to flow.

7. The integrated machine apparatus of any one of claims 1 to 6, wherein the heat exchange assembly comprises a heat exchanger and a second fan;

the second fan drives air in the formation cavity to flow through the heat exchanger;

the controller is used for controlling the rotation speed of the second fan to be increased and/or controlling the medium flow rate in the heat exchanger to be increased when the temperature measured by the temperature sensor is lower than a set value.

8. The formation all-in-one apparatus of claim 7, further comprising a tray located within the formation chamber, the tray for placement of the battery cells;

the two heat exchange assemblies are respectively and correspondingly positioned at two opposite sides of the tray;

the blowing directions of the two heat exchange assemblies face the tray.

9. The integrated machine apparatus of claim 7, wherein the heat exchange assembly further comprises a third fan;

the third fan is positioned in the formation cavity, and the third fan and the second fan drive air in the formation cavity to circularly flow.

10. The integrated machine equipment according to any one of claims 1 to 6, wherein first holes and second holes are respectively formed on two opposite sides of the cabinet;

the integrated formation machine equipment also comprises a tray, a formation assembly, a first door and a second door; wherein,,

the tray is positioned in the formation cavity and is used for placing the battery monomers;

the formation component is positioned in the formation cavity and is used for forming the battery monomers;

the first hole accommodates the tray to enter and exit the formation cavity, and the second hole accommodates the formation component to enter and exit the formation cavity;

the first door closes to close the first aperture and the second door closes to close the second aperture.