Thermostat and energy storage device

By combining support components and temperature control components, the problem of low heat dissipation efficiency in battery energy storage devices is solved, achieving improved temperature control and safety, and extending battery life.

CN224328743UActive Publication Date: 2026-06-05BYD CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
BYD CO LTD
Filing Date
2025-04-18
Publication Date
2026-06-05

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Abstract

The embodiment of the present application provides a temperature adjusting device and an energy storage device. The temperature adjusting device is installed in a box body, the box body has a containing cavity, the temperature adjusting device comprises a supporting assembly and a temperature adjusting assembly, the supporting assembly is sealingly connected to the box body to form a top wall of the box body, and the temperature adjusting assembly is arranged on the supporting assembly and is used for adjusting the temperature in the containing cavity. The present application can solve the problem that the battery energy storage device has low heat dissipation efficiency, the working temperature of the battery is increased, and the safety is low.
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Description

Technical Field

[0001] This application relates to the field of air conditioning technology, and in particular to a temperature control device and an energy storage device. Background Technology

[0002] A battery energy storage device is an energy storage device consisting of battery clusters and an inverter.

[0003] During the use of battery energy storage devices, heat is generated when the battery clusters store or release electrical energy.

[0004] In related technologies, battery energy storage devices suffer from low heat dissipation efficiency, which leads to higher battery operating temperatures and lower safety. Summary of the Invention

[0005] This application provides a temperature regulating device and an energy storage device to solve the problem that the low heat dissipation efficiency of battery energy storage devices leads to higher battery operating temperatures and lower safety.

[0006] In a first aspect, embodiments of this application provide a temperature regulating device installed in a housing, the housing having a receiving cavity, the temperature regulating device comprising:

[0007] The support assembly is sealed to the enclosure to form the top wall of the enclosure;

[0008] A temperature control component is installed on the support component and is used to control the temperature inside the receiving cavity.

[0009] In some embodiments, the temperature control component is located on the side of the support component away from the receiving cavity; the temperature control component is connected to the housing.

[0010] In some embodiments, the temperature control assembly has an air vent, and the support assembly has an opening communicating with the receiving cavity;

[0011] The air vent is opposite to the opening and is connected to the housing cavity through the opening. The temperature control component delivers temperature-controlled airflow into the housing cavity through the air vent and the opening.

[0012] In some implementations, it also includes:

[0013] The first sealing element is arranged around the outer periphery of the support assembly and sandwiched between the outer peripheral wall of the support assembly and the inner side wall of the housing to form a sealing interface between the support assembly and the housing.

[0014] In some implementations, it also includes:

[0015] The second seal is sandwiched between the support assembly and the temperature control assembly along the height direction of the temperature control device to form a sealing interface between the support assembly and the temperature control assembly.

[0016] In some embodiments, the second seal includes a sealing portion and a through hole formed in the sealing portion;

[0017] Along the height direction of the temperature control device, the sealing part is sandwiched between the support component and the temperature control component, and the through hole is opposite to the opening and the air outlet, and the opening and the air outlet are connected through the through hole.

[0018] In some implementations, it also includes:

[0019] The mounting component is located between the outer peripheral wall of the temperature control component and the inner side wall of the housing.

[0020] The temperature control component is connected to the inner wall of the enclosure via a mounting component.

[0021] In some embodiments, along the height direction perpendicular to the temperature control device, the mounting component is located on the side of the first seal opposite to the support component, and the mounting component protrudes outward on the outer peripheral wall of the temperature control component on the side opposite to the center of the temperature control component.

[0022] In some embodiments, mounting components are provided on opposite sides of the temperature regulating component along a second direction perpendicular to the height direction of the temperature regulating device.

[0023] In some implementations, the mounting components include:

[0024] The first mounting component protrudes outward from the outer peripheral wall of the temperature control component along the height direction perpendicular to the temperature control device and facing away from the center of the temperature control component, and extends along the circumference of the temperature control component.

[0025] Along the height direction of the temperature control device, the side of the first mounting component close to the support component is connected to the support component, and the side of the first mounting component away from the support component forms a mounting surface.

[0026] In some implementations, the mounting components further include:

[0027] The second mounting component is connected to the outer peripheral wall of the temperature control component; along the height direction of the temperature control device, the second mounting component is located on the side of the first mounting component away from the support component and is connected to the mounting surface of the first mounting component.

[0028] In some embodiments, multiple second mounting members are provided, and the multiple second mounting members are spaced apart along the extension direction of the first mounting member.

[0029] In some implementations, multiple air vents are provided, and the multiple air vents are spaced apart along the circumference of the temperature control component;

[0030] There are multiple openings, which are spaced apart along the circumference of the support component;

[0031] Multiple air vents and multiple openings are arranged in a one-to-one correspondence and are interconnected.

[0032] In some embodiments, multiple sealing parts are provided, and multiple sealing parts are spaced apart along the circumference of the temperature control component; the through holes of the multiple sealing parts are connected to multiple air outlets in a one-to-one correspondence.

[0033] Alternatively, the sealing part extends circumferentially along the temperature control component and has multiple through holes; multiple through holes are spaced apart along the circumferential direction of the temperature control component; multiple through holes are connected to multiple air outlets one by one.

[0034] In some embodiments, the side peripheral wall of the temperature control component is provided with an air guide shroud, one end of which is connected to an air outlet and the other end of which is connected to an opening.

[0035] The air vents and openings are connected by an air guide shroud.

[0036] In some implementations, the multiple air outlets include multiple air supply outlets and multiple air return outlets;

[0037] Along the first direction, multiple air outlets are located on opposite sides of the temperature control component, and a number of return air outlets are located on opposite sides of the temperature control component.

[0038] On the same side of the temperature control component perpendicular to the height direction, multiple air outlets are placed on both sides of the return air outlet along the second direction.

[0039] Along the second direction, another number of return air vents are located on opposite sides of the temperature control assembly;

[0040] The first direction and the second direction are perpendicular to each other, and both are perpendicular to the height direction of the temperature control device.

[0041] In some implementations, the support components include:

[0042] The support component has its outer peripheral wall connected to the inner side wall of the housing, and the air vent is located on the support component.

[0043] The first heat insulation component is sandwiched between the support component and the temperature control component along the height direction of the temperature control device.

[0044] In some embodiments, the support member includes multiple sub-support members;

[0045] Along the height direction perpendicular to the temperature control device, multiple sub-supports are arranged in an array, with adjacent sub-supports connected to each other.

[0046] In some embodiments, the first insulation element includes a plurality of first sub-insulation elements;

[0047] Along the height direction of the vertical temperature control device, multiple first sub-insulation elements are arranged in an array, and two adjacent first sub-insulation elements are connected to each other.

[0048] Multiple sub-support components and multiple first sub-insulation components are stacked one-to-one.

[0049] In some implementations, the support components further include:

[0050] The second heat insulation element is connected to the side of the support element away from the first heat insulation element.

[0051] In some embodiments, the second insulation element includes a plurality of second sub-insulation elements;

[0052] Along the height direction perpendicular to the temperature control device, multiple second sub-insulation elements are arranged in an array, with adjacent second sub-insulation elements connected to each other.

[0053] In some embodiments, multiple sub-support members and multiple first sub-insulation members are spaced apart along a first direction; the first direction is perpendicular to the height direction of the temperature regulating device.

[0054] In some implementations, the support components further include:

[0055] A first connector extends along a first direction and is connected to one side of a plurality of first sub-insulation members away from the support member.

[0056] In some implementations, the support components further include:

[0057] The second connector extends along the second direction and connects between two adjacent sub-support members and between two adjacent first sub-insulation members;

[0058] The two ends of the second connector in the extension direction are connected to the inner side wall of the box;

[0059] The second direction is perpendicular to the height direction of the temperature control device and perpendicular to the first direction;

[0060] The first connector and the second connector are connected to each other at the intersection of their extending directions.

[0061] In some embodiments, multiple first connectors are provided, and the multiple first connectors are spaced apart along the second direction;

[0062] Multiple second connectors are provided, and the multiple second connectors are spaced apart along the first direction;

[0063] Multiple first connectors and multiple second connectors form a grid structure.

[0064] In some implementations, it also includes:

[0065] The third connector extends along the first direction and connects between two adjacent second sub-insulation members.

[0066] In some implementations, it also includes:

[0067] The reinforcing member is sandwiched between the second sealing member and the supporting member along the height direction of the temperature regulating device.

[0068] Along the height direction perpendicular to the temperature control device, the reinforcing member is located on the side of the through hole of the second seal opposite to the edge of the second seal; the reinforcing member extends along the extension direction of the second seal.

[0069] In some embodiments, the temperature control component has an air duct cavity that communicates with an air outlet and an air return outlet.

[0070] In some embodiments, the duct cavity includes:

[0071] The first cavity section is connected to the return air vent.

[0072] The second cavity section is connected to the air outlet.

[0073] Along the height direction of the temperature control device, the first cavity is located on the side of the second cavity closer to the support assembly.

[0074] In some embodiments, the temperature control component includes:

[0075] The first fan is installed inside the air duct cavity. The air inlet of the first fan is connected to the first cavity section, and the air outlet of the first fan is connected to the second cavity section. The first fan is used to transport the airflow from the first cavity section to the second cavity section.

[0076] An evaporator is disposed within the second chamber; and / or a heater is disposed within the second chamber.

[0077] In some embodiments, the temperature control component further includes:

[0078] The heat exchange chamber and the air duct chamber are arranged adjacent to each other and are interconnected along a first direction perpendicular to the height of the temperature control device.

[0079] In some embodiments, two air duct cavities are provided, and along the first direction, the two air duct cavities are provided on opposite sides of the heat exchange cavity.

[0080] In some embodiments, the temperature control component includes:

[0081] The housing is connected to the support assembly;

[0082] The first partition is disposed in the cavity of the housing. A portion of the housing along the height direction of the temperature control device is enclosed with the first partition to form a first cavity segment, and another portion of the housing along the height direction of the temperature control device is enclosed with the first partition to form a second cavity segment.

[0083] In some embodiments, the temperature control component further includes:

[0084] The second partition is disposed in the shell cavity. The second partition extends along a second direction perpendicular to the height of the temperature control device and separates the air duct cavity and the heat exchange cavity.

[0085] In some embodiments, the temperature control component further includes:

[0086] The condenser is located in the heat exchange chamber;

[0087] And / or, a second fan, located in the heat exchange chamber;

[0088] And / or, a compressor, located in the heat exchange chamber.

[0089] In some implementations, it also includes:

[0090] The protective cover is installed along the height of the temperature control device on the side of the temperature control component away from the support component.

[0091] Secondly, this application provides an energy storage device, including a housing and a temperature control device, wherein the support component of the temperature control device is sealed to the housing and forms the top wall of the housing.

[0092] The temperature control device in this structure uses a support assembly to support the temperature control component. This support assembly is sealed to the housing to form the top wall of the housing, reducing the ingress of water or dust from the external environment. This provides waterproofing or leak-proof protection for the interior of the housing, improving the safety performance of the energy storage device. The temperature control component regulates the temperature within the housing cavity to prevent overheating or overcooling, further enhancing the safety of the energy storage device. It also maintains the housing cavity within a suitable temperature range, thereby extending the lifespan of the batteries within the energy storage device.

[0093] Therefore, the temperature control device provided in this application embodiment can solve the problem that the low heat dissipation efficiency of battery energy storage devices leads to higher battery operating temperatures and lower safety. Attached Figure Description

[0094] The accompanying drawings, which are incorporated in and form part of this specification, illustrate embodiments consistent with this application and, together with the description, serve to explain the principles of this application.

[0095] Figure 1 A schematic diagram of the main structure of the temperature control device provided in this application;

[0096] Figure 2 An exploded structural diagram of the temperature control device provided in this application;

[0097] Figure 3 A schematic diagram of the main structure of the supporting components provided for this application;

[0098] Figure 4 An exploded structural diagram of the supporting components provided in this application;

[0099] Figure 5 A schematic diagram of the connection structure of the support component, the second seal, and the reinforcing rib provided in this application;

[0100] Figure 6 This is a schematic diagram of the main structure of the temperature control component provided in this application.

[0101] Figure label:

[0102] 100 - Support assembly; 101 - Support member; 102 - First thermal insulation member; 103 - Second thermal insulation member; 104 - First connector; 105 - Second connector; 106 - Opening;

[0103] 200-Temperature control assembly; 201-Housing; 202-First partition; 203-Evaporator; 204-Heater; 205-First fan; 206-Second partition; 207-Condenser; 208-Second fan; 209-Compressor; 210-Air duct cavity; 2101-First cavity section; 2102-Second cavity section; 211-Heat exchange cavity; 212-Air outlet; 2121-Return air outlet; 2122-Air outlet; 214-Air guide shroud;

[0104] 300 - Mounting component; 301 - First mounting component; 3011 - Mounting surface; 302 - Second mounting component;

[0105] 400 - First seal;

[0106] 500 - Second seal; 501 - Sealing part; 502 - Through hole;

[0107] 600 - Reinforcing component;

[0108] 700-Shield;

[0109] X - First direction;

[0110] Y - Second direction;

[0111] Z - Height direction of the temperature control device.

[0112] The accompanying drawings have illustrated specific embodiments of this application, which will be described in more detail below. These drawings and descriptions are not intended to limit the scope of the concept in any way, but rather to illustrate the concept of this application to those skilled in the art through reference to specific embodiments. Detailed Implementation

[0113] Exemplary embodiments will now be described in detail, examples of which are illustrated in the accompanying drawings. When the following description relates to the drawings, unless otherwise indicated, the same numbers in different drawings denote the same or similar elements. The embodiments described in the following exemplary embodiments do not represent all embodiments consistent with this application. Rather, they are merely examples of apparatuses and methods consistent with some aspects of this application as detailed in the appended claims.

[0114] In related technologies, multiple batteries are stacked inside the battery energy storage device. When the batteries are working, they generate heat, which is then dissipated naturally. This leads to a decrease in the heat dissipation efficiency of the battery energy storage device, and the inability to dissipate heat in time causes the battery temperature to rise continuously, resulting in a decrease in the safety of the battery and the battery energy storage device.

[0115] The support assembly provided in the embodiments of this application is used to support the temperature regulating assembly, and the support assembly is sealed to the housing to form the top wall of the housing. This reduces the ingress of water or dust from the external environment into the housing, thereby providing waterproof or leak-proof protection for the interior of the housing and improving its safety performance. The temperature regulating assembly is located on the support assembly, reducing the space occupied by the temperature regulating assembly at the bottom of the housing. This frees up more space at the bottom of the housing for placing batteries or battery packs, thereby increasing the energy density of the energy storage device. Furthermore, the temperature regulating assembly can regulate the temperature within the housing to prevent overheating or overcooling, improving the safety performance of the energy storage device and maintaining it within a suitable temperature range, thus extending the lifespan of the energy storage device.

[0116] Therefore, the temperature control device provided in this application embodiment can solve the problem that the low heat dissipation efficiency of battery energy storage devices leads to higher battery operating temperatures and lower safety.

[0117] like Figure 1 and Figure 2 As shown, the temperature control device provided in the embodiment of this application is installed in a housing, the housing having a receiving cavity. The temperature control device includes a support assembly 100 and a temperature control assembly 200. The support assembly 100 is sealed to the housing to form the top wall of the housing. The temperature control assembly 200 is disposed on the support assembly 100 and is used to control the temperature inside the receiving cavity.

[0118] It should be noted that the support component 100 and the temperature control component 200 can be an integrated structure, a detachable connection, or a fixed connection. There are no restrictions here, and they can be selected according to actual usage requirements.

[0119] Understandably, the above structure can improve the flexibility of the setup between the support component 100 and the temperature control component 200.

[0120] Furthermore, the support component 100 and the temperature control component 200 are an integrated structure. The support component 100 can be the base plate or the outer side plate of the temperature control component 200. There are no restrictions here, and it can be selected according to the actual use requirements.

[0121] Furthermore, the support assembly 100 and the temperature control assembly 200 are detachably connected, and can be connected by bolts, clips, quick-release parts or other detachable components. There are no restrictions on this, and the appropriate method can be selected according to actual usage requirements.

[0122] Furthermore, the support component 100 and the temperature control component 200 are fixedly connected, which can be done by welding, gluing, or other fixing methods. There are no restrictions on this, and the method can be selected according to the actual use requirements.

[0123] It should be noted that the temperature control component 200 provided in the embodiments of this application is disposed on the side of the support component 100 away from the receiving cavity, and the temperature control component 200 is connected to the housing.

[0124] Understandably, the temperature control component 200 is positioned on the side of the support component 100 away from the housing cavity. This reduces the space occupied by the temperature control component 200 within the housing cavity, thereby improving the utilization rate of the internal space and allowing more batteries or battery packs to be placed inside. The connection between the temperature control component 200 and the housing increases the stability of the connection. Furthermore, this connection further reduces the ingress of water or dust from the external environment into the housing, thus improving the safety performance of the energy storage device.

[0125] The temperature control component 200 provided in the embodiments of this application has an air outlet 212, and the support component 100 has an opening 106 communicating with the receiving cavity. The air outlet 212 is opposite to the opening 106 and communicates with the receiving cavity through the opening 106. The temperature control component 200 delivers temperature-controlled airflow into the receiving cavity through the air outlet 212 and the opening 106.

[0126] It is understandable that the temperature-regulating airflow generated by the temperature-regulating component 200 can enter the receiving cavity after passing through the air vent 212 and the opening 106. The air vent 212 and the opening 106 are opposite each other, which can shorten the travel path of the temperature-regulating airflow between the air vent 212 and the opening 106, thereby improving the delivery efficiency of the temperature-regulating airflow.

[0127] It should be noted that, in some embodiments, the air vent 212 and the opening 106 can be connected by a conveying pipe, with one end of the conveying pipe connected to the air vent 212 and the other end of the conveying pipe connected to the opening 106.

[0128] It is understandable that the connection between the air outlet 212 and the opening 106 via a conveying pipe can reduce the waste of cold or heat energy in the temperature-regulating airflow, thereby improving the utilization rate of the cold or heat energy in the temperature-regulating airflow. In addition, the setting of the conveying pipe can improve the flexibility of the setting between the air outlet 212 and the opening 106.

[0129] The temperature control device provided in the embodiments of this application further includes: a first sealing member 400, which is arranged around the outer periphery of the support assembly 100 and sandwiched between the outer peripheral wall of the support assembly 100 and the inner side wall of the box, so as to form a sealing interface between the support assembly 100 and the box.

[0130] It is understandable that by setting the first sealing element 400, the outer peripheral wall of the support component 100 and the inner side wall of the box can be sealed together, thereby reducing the occurrence of water or dust in the external environment entering the box through the gap between the outer peripheral wall of the support component 100 and the inner side wall of the box, thereby improving the safety performance of the energy storage device.

[0131] It should be noted that the first sealing element 400 can be one or a combination of several of the following: rubber strip, rubber gasket, O-ring, or other components that can perform a sealing function. There are no restrictions on this, and the element can be selected according to actual usage requirements.

[0132] It should be noted that the first sealing element 400 is made of the aforementioned material, which allows for a sealed connection between the outer peripheral wall of the support assembly 100 and the inner side wall of the box.

[0133] The temperature control device provided in the embodiments of this application further includes: a second sealing member 500, which is sandwiched and connected between the support component 100 and the temperature control component 200 along the height direction of the temperature control device, so as to form a sealing interface between the support component 100 and the temperature control component 200.

[0134] It is understandable that by setting the second seal 500, a sealing interface can be formed between the support component 100 and the temperature control component 200, so that the temperature control airflow generated by the temperature control component 200 can enter the receiving cavity through the opening 106 on the support component 100, thereby reducing the occurrence of the temperature control airflow generated by the temperature control component 200 entering the installation gap between the temperature control component 200 and the support component 100.

[0135] Furthermore, the second seal 500 includes a sealing portion 501 and a through hole 502 formed on the sealing portion 501; along the height direction of the temperature control device, the sealing portion 501 is sandwiched between the support assembly 100 and the temperature control assembly 200, and the through hole 502 is opposite to the opening 106 and the air vent 212, and the opening 106 and the air vent 212 are connected through the through hole 502.

[0136] Understandably, the sealing part 501 is used to clamp and connect the support assembly 100 and the temperature regulating assembly 200, which can seal the installation gap between the support assembly 100 and the temperature regulating assembly 200, and can also improve the connection strength between the support assembly 100 and the temperature regulating assembly 200. The through hole 502 opened on the sealing part 501 can allow the temperature regulating airflow generated by the temperature regulating assembly 200 to be delivered to the receiving cavity after passing through the air outlet 212, the through hole 502 and the opening 106.

[0137] The temperature control device provided in the embodiments of this application further includes: a mounting component 300, which is disposed between the outer peripheral wall of the temperature control component 200 and the inner side wall of the housing; the temperature control component 200 is connected to the inner side wall of the housing through the mounting component 300.

[0138] It is understandable that by setting the mounting component 300, the temperature regulating component 200 can be connected to the inner wall of the enclosure. The mounting component 300 can increase the connection strength between the outer peripheral wall of the temperature regulating component 200 and the inner wall of the enclosure, and can seal the installation gap between the outer peripheral wall of the temperature regulating component 200 and the inner wall of the enclosure, so as to reduce the occurrence of water or dust in the external environment entering the enclosure after passing through the installation gap between the outer peripheral wall of the temperature regulating component 200 and the inner wall of the enclosure, thereby improving the safety performance of the energy storage device.

[0139] Furthermore, along the height direction perpendicular to the temperature control device, the mounting component 300 is located on the side of the first seal 400 away from the support component 100, and the mounting component 300 is protruding outward on the outer peripheral wall of the temperature control component 200 on the side away from the center of the temperature control component 200.

[0140] It is understandable that the mounting component 300 is protruding outward on the outer peripheral wall of the temperature control component 200 on the side opposite to the center of the temperature control component 200, so that the mounting component 300 can fill or seal the installation gap between the outer peripheral wall of the temperature control component 200 and the inner side wall of the housing.

[0141] Furthermore, in a second direction perpendicular to the height direction of the temperature control device, mounting components 300 are provided on opposite sides of the temperature control component 200.

[0142] It is understandable that, along the second direction perpendicular to the height of the temperature regulating device, mounting components 300 are provided on both sides of the temperature regulating component 200. This can further reduce the occurrence of water or dust in the external environment entering the housing after passing through the mounting gap between the outer peripheral wall of the temperature regulating component 200 and the inner side wall of the housing, thereby improving the safety performance of the energy storage device.

[0143] Furthermore, the mounting assembly 300 includes: a first mounting member 301, which protrudes outward from the outer peripheral wall of the temperature control assembly 200 along the height direction perpendicular to the temperature control device and facing away from the center of the temperature control assembly 200, and extends circumferentially along the temperature control assembly 200; along the height direction of the temperature control device, the side of the first mounting member 301 close to the support assembly 100 is connected to the support assembly 100, and the side of the first mounting member 301 away from the support assembly 100 forms a mounting surface 3011.

[0144] It is understandable that by setting the first mounting component 301, the installation gap between the outer peripheral wall of the temperature regulating component 200 and the inner side wall of the box can be filled or sealed to reduce the occurrence of water or dust in the external environment entering the box after passing through the installation gap between the outer peripheral wall of the temperature regulating component 200 and the inner side wall of the box, thereby improving the safety performance of the energy storage device.

[0145] Furthermore, the mounting assembly 300 also includes: a second mounting member 302, connected to the outer peripheral wall of the temperature regulating assembly 200; along the height direction of the temperature regulating device, the second mounting member 302 is located on the side of the first mounting member 301 away from the support assembly 100, and is connected to the mounting surface 3011 of the first mounting member 301.

[0146] It is understood that by providing the second mounting member 302, mounting points can be formed on the outer peripheral wall of the temperature regulating component 200, allowing the temperature regulating component 200 to be mounted to the inner wall of the housing via the second mounting member 302 and the first mounting member 301. Furthermore, in some embodiments, by connecting the second mounting member 302 with the mounting surface 3011 of the first mounting member 301, the installation gap between the side wall of the first mounting member 301 facing away from the housing and the outer peripheral wall of the temperature regulating component 200 can be reduced, thereby blocking or isolating water or dust from the external environment.

[0147] Furthermore, the second mounting component 302 is connected to the mounting surface 3011 of the first mounting component 301. This connection can be achieved by the second mounting component 302 overlapping the mounting surface, or by the second mounting component 302 being detachably connected to the mounting surface, or by the second mounting component 302 being fixedly connected to the mounting surface, or by other connection methods. No restrictions are imposed here, and the appropriate method can be selected according to actual usage requirements.

[0148] In some embodiments, the second mounting component has a first threaded through hole, and the mounting surface has a second threaded through hole, and the first threaded through hole and the second threaded through hole are connected by bolts.

[0149] It is understood that, through the above implementation method, the first mounting component 301 and the second mounting component 302 can be detachably connected, thereby facilitating the connection of the temperature control component 200 to the housing.

[0150] The embodiments of this application provide a plurality of second mounting members 302, which are spaced apart along the extending direction of the first mounting member 301.

[0151] It is understandable that increasing the number of second mounting parts 302 can increase the contact area between the second mounting parts 302 and the mounting surface, thereby making the connection between the temperature control component 200 and the first mounting part 301 more stable.

[0152] It should be noted that the number of the second mounting component 302 can be any number greater than or equal to 2, and there is no restriction here. It can be selected according to actual usage needs.

[0153] The embodiments of this application provide multiple air vents 212, which are spaced apart along the circumference of the temperature control component 200; multiple openings 106 are provided, which are spaced apart along the circumference of the support component 100; the multiple air vents 212 and the multiple openings 106 are arranged opposite each other in a one-to-one correspondence and are interconnected.

[0154] Understandably, increasing the number of air vents 212 and openings 106 allows the temperature-regulating airflow generated by the temperature-regulating component 200 to be delivered to multiple different locations within the receiving cavity via multiple air vents 212 and openings 106, thereby making the temperature within the receiving cavity more uniform. Multiple air vents 212 are spaced apart circumferentially along the temperature-regulating component 200, and multiple openings 106 are spaced apart circumferentially along the support component 100. The multiple air vents 212 and openings 106 are arranged in a one-to-one correspondence and are interconnected, which can reduce the occurrence of localized overcooling or overheating caused by the temperature-regulating airflow generated by the temperature-regulating component 200.

[0155] It should be noted that the number of openings 106 can be any value greater than or equal to 1, and there is no restriction. It can be selected according to actual usage needs. Furthermore, there is no restriction on the number of air vents 212, as long as the number of openings 106 and air vents 212 are the same.

[0156] In some embodiments, there are 10 openings 106 and 10 air vents 212, and the 10 openings 106 and 10 air vents 212 are connected in a one-to-one correspondence.

[0157] In one embodiment, multiple sealing portions 501 are provided, and multiple sealing portions 501 are spaced apart along the circumference of the temperature regulating component 200; the through holes 502 of the multiple sealing portions 501 are connected to multiple air vents 212 in a one-to-one correspondence.

[0158] It is understood that, through the above implementation method, the occurrence of temperature-regulating airflow generated by the temperature-regulating component 200 entering the installation gap between the temperature-regulating component 200 and the support component 100 can be further reduced.

[0159] In one embodiment, the sealing part 501 extends circumferentially along the temperature regulating component 200 and has a plurality of through holes 502; the plurality of through holes 502 are spaced apart along the circumferential direction of the temperature regulating component 200; the plurality of through holes 502 are connected to the plurality of air vents 212 in a one-to-one correspondence.

[0160] It is understood that, through the above implementation method, the occurrence of temperature-regulating airflow generated by the temperature-regulating component 200 entering the installation gap between the temperature-regulating component 200 and the support component 100 can be further reduced. The sealing part 501 extends circumferentially along the temperature-regulating component 200 and has multiple through holes 502, which can allow multiple through holes 502 on a second sealing member 500 to connect to multiple air outlets 212.

[0161] The temperature control component 200 provided in the embodiments of this application has an air guide hood 214 on its side peripheral wall. One end of the air guide hood 214 is connected to the air outlet 212, and the other end of the air guide hood 214 is connected to the opening 106. The air outlet 212 and the opening 106 are connected through the air guide hood 214.

[0162] It is understandable that by setting the air guide hood 214, the air outlet 212 and the opening 106 can be connected, thereby reducing the waste of the cooling or heating energy of the temperature-controlled airflow and improving the utilization rate of the cooling or heating energy of the temperature-controlled airflow. In addition, the setting of the delivery pipe can improve the flexibility of the setting between the air outlet 212 and the opening 106.

[0163] The embodiments of this application provide multiple air vents 212, including multiple air outlets 2122 and multiple air return vents 2121; along a first direction, multiple air outlets 2122 are disposed on opposite sides of the temperature control component 200, and a number of air return vents 2121 are disposed on opposite sides of the temperature control component 200; on the same side of the temperature control component 200 perpendicular to the height direction, multiple air outlets 2122 are distributed on both sides of the air return vents 2121 along a second direction; along the second direction, another number of air return vents 2121 are disposed on opposite sides of the temperature control component 200; the first direction and the second direction are perpendicular to each other and both are perpendicular to the height direction of the temperature control device.

[0164] It is understood that, through the above implementation method, the mutual interference between multiple air outlets 2122 and multiple air return outlets 2121 can be reduced, and the coverage of air outlets 2122 and air return outlets 2121 can be made more dispersed, thereby making the delivery position of the temperature-regulating airflow generated by the temperature-regulating component 200 more dispersed, thereby reducing the occurrence of local overcooling or local overheating inside the containment cavity.

[0165] In some embodiments, along the first direction, each side of the temperature control component 200 is provided with two air outlets 2122, and the two air outlets 2122 on the same side are spaced apart along the second direction; the two air outlets 2122 on different sides are spaced apart along the first direction; and a return air outlet 2121 is provided between the two air outlets 2122 spaced apart along the second direction, and the two return air outlets 2121 on different sides are spaced apart along the first direction; that is, along the first direction, each side of the temperature control component 200 has two air outlets 2122 and one return air outlet 2121.

[0166] Furthermore, along the second direction, each side of the temperature control component 200 is provided with two return air inlets 2121. The two return air inlets 2121 on the same side are spaced apart along the first direction, and the two return air inlets 2121 on different sides are spaced apart along the second direction.

[0167] Therefore, the temperature control component 200 can have 4 air outlets 2122 and 6 air return outlets 2121, which corresponds to 10 air outlets 212 mentioned above.

[0168] like Figure 3 and Figure 4 As shown, the support component 100 provided in the embodiment of this application includes: a support member 101 and a first heat insulation member 102. The outer peripheral wall of the support member 101 is connected to the inner side wall of the box, and the air vent 212 is opened on the support member 101. Along the height direction of the temperature control device, the first heat insulation member 102 is sandwiched between the support member 101 and the temperature control component 200.

[0169] It is understood that, through the above implementation method, the support member 101 can support the temperature regulating component 200, and by providing the first heat insulation member 102, the occurrence of heat convection between the temperature regulating component 200 and the support member 101 can be reduced.

[0170] The support member 101 provided in the embodiments of this application includes a plurality of sub-support members; the plurality of sub-support members are arranged in an array along the height direction perpendicular to the temperature control device, and adjacent sub-support members are connected to each other.

[0171] It is understandable that the above-described implementation method allows for more flexible arrangement of the support member 101.

[0172] It should be noted that the number of sub-support components can be any value greater than 1, and there is no restriction here. It can be selected according to the actual use requirements.

[0173] In some embodiments, three sub-support members are provided, which are arranged along a first direction and adjacent sub-support members are connected to each other.

[0174] It is understood that the above implementation method allows for more flexible arrangement of the sub-support members, thereby making the arrangement of the support member 101 more flexible.

[0175] The first heat insulation component 102 provided in the embodiments of this application includes a plurality of first sub-heat insulation components; the plurality of first sub-heat insulation components are arranged in an array along the height direction of the vertical temperature control device, and two adjacent first sub-heat insulation components are connected to each other; a plurality of sub-support components and a plurality of first sub-heat insulation components are stacked one-to-one.

[0176] It is understood that, through the above implementation method, the arrangement of the first heat insulation member 102 can be more flexible, and multiple first sub-heat insulation members can be distributed on multiple sub-support members, so as to further reduce the occurrence of heat convection between the temperature regulating component 200 and the support member 101.

[0177] Furthermore, when there are three sub-support members, there are three first sub-insulation members, and the three first sub-insulation members are arranged along the first direction.

[0178] It is understood that the above-described embodiments allow for more flexible configuration of the first sub-insulation element and further reduce heat convection between the temperature control component 200 and the support member 101.

[0179] The support component 100 provided in the embodiments of this application further includes: a second heat insulation member 103, which is connected to the side of the support component 101 away from the first heat insulation member 102.

[0180] Understandably, by providing the second heat insulation element 103, the occurrence of heat convection between the receiving cavity and the support element 101 can be reduced.

[0181] The second heat insulation element 103 provided in the embodiments of this application includes a plurality of second sub-heat insulation elements; the plurality of second sub-heat insulation elements are arranged in an array along the height direction perpendicular to the temperature control device, and adjacent second sub-heat insulation elements are connected to each other.

[0182] It is understood that, through the above-described embodiments, the arrangement of the second heat insulation member 103 can be made more flexible, and multiple second sub-heat insulation members can be distributed on multiple sub-support members to further reduce the occurrence of heat convection between the receiving cavity and the support member 101.

[0183] Furthermore, when there are three sub-support members, there are also three second sub-insulation members, and the three second sub-insulation members are arranged along the first direction.

[0184] It is understood that the above-described embodiments allow for more flexible arrangement of the second sub-insulation member and further reduce heat convection between the receiving cavity and the support member 101.

[0185] Furthermore, multiple sub-support members and multiple first sub-insulation members are all spaced apart along a first direction; the first direction is perpendicular to the height direction of the temperature regulating device.

[0186] It is understood that, through the above implementation method, multiple sub-support members and multiple first sub-insulation members can cover a larger area along the first direction to form the top wall of the box.

[0187] The support component 100 provided in the embodiments of this application further includes: a first connector 104 extending along a first direction, the first connector 104 being connected to one side of a plurality of first sub-insulation members away from the support component 101.

[0188] It is understandable that by setting the first connector 104, the connection strength between multiple first sub-insulation components can be improved, thereby making the connection between multiple first sub-insulation components more stable and improving the service life of the support assembly 100.

[0189] The support assembly 100 provided in the embodiments of this application further includes: a second connector 105 extending along a second direction, the second connector 105 being connected between two adjacent sub-supports and between two adjacent first sub-insulations; the two ends of the extension direction of the second connector 105 being connected to the inner sidewall of the housing; the second direction being perpendicular to the height direction of the temperature control device and perpendicular to the first direction; the first connector 104 and the second connector 105 being connected to each other at the intersection of their extension directions.

[0190] It is understandable that by providing the first connector 104, the connection strength between the multiple first sub-insulation components can be improved, and the first connector 104 can connect to the inner wall of the housing, thereby improving the connection strength between the first sub-insulation components and the inner wall of the housing. The first connector 104 and the second connector 105 are connected to each other at the intersection in the extending direction, which can improve the connection strength between the first connector 104 and the second connector 105.

[0191] The embodiments of this application provide a plurality of first connectors 104, which are spaced apart along a second direction; a plurality of second connectors 105 are provided, which are spaced apart along a first direction; the plurality of first connectors 104 and the plurality of second connectors 105 form a grid structure.

[0192] Understandably, increasing the number of first connectors 104 and second connectors 105 can further improve the connection strength between multiple first sub-insulation components and the connection strength between the first sub-insulation components and the inner wall of the housing. Furthermore, the good stability of the grid structure can extend the service life of the support assembly 100.

[0193] The temperature control device provided in the embodiments of this application further includes: a third connector extending along a first direction and connected between two adjacent second sub-insulation members.

[0194] Understandably, by setting a third connector, the connection strength between two adjacent second sub-insulation components can be improved.

[0195] like Figure 5 As shown, the temperature control device provided in the embodiment of this application further includes: a reinforcing member 600, which is sandwiched between the second sealing member 500 and the support member 101 along the height direction of the temperature control device; the reinforcing member 600 is located on the side of the through hole 502 of the second sealing member 500 away from the edge of the second sealing member 500 along the height direction perpendicular to the temperature control device; the reinforcing member 600 extends along the extension direction of the second sealing member 500.

[0196] Understandably, by providing the reinforcing member 600, the connection strength between the second seal 500 and the support member 101 can be improved. In some embodiments, the reinforcing member 600 can also fill the gap between the second seal 500 and the support member 101, thereby facilitating the connection between the second seal 500 and the support member 101.

[0197] like Figure 6 As shown, the temperature control component 200 provided in the embodiment of this application has an air duct cavity 210, which is connected to the air outlet 2122 and the air return vent 2121.

[0198] It is understandable that the air duct cavity 210 is connected to the return air port 2121 and the air outlet 2122, so that the temperature-regulating airflow can flow between the air duct cavity 210, the return air port 2121 and the air outlet 2122.

[0199] The air duct cavity 210 provided in the embodiments of this application includes: a first cavity section 2101 and a second cavity section 2102. The first cavity section 2101 is connected to the return air port 2121, and the second cavity section 2102 is connected to the air outlet 2122. Along the height direction of the temperature control device, the first cavity section 2101 is located on the side of the second cavity section 2102 close to the support assembly 100.

[0200] It is understood that, through the above implementation method, the first cavity segment 2101 and the second cavity segment 2102 can be arranged adjacent to each other along the height direction of the temperature control device, which can reduce the space occupied by the first cavity segment 2101 and the second cavity segment 2102 in the temperature control assembly 200, thereby reducing the volume of the temperature control assembly 200.

[0201] The temperature control component 200 provided in the embodiments of this application includes: a first fan 205, which is disposed in the air duct cavity 210. The air inlet of the first fan 205 is connected to the first cavity section 2101, and the air outlet of the first fan 205 is connected to the second cavity section 2102. The first fan 205 is used to transport the airflow of the first cavity section 2101 to the second cavity section 2102.

[0202] It is understandable that by setting up the first fan 205, the airflow efficiency between the first cavity 2101 and the second cavity 2102 can be improved.

[0203] It should be noted that the number of the first fan 205 can be any number greater than or equal to 1, and there is no restriction here. It can be selected according to the actual needs of use.

[0204] In some embodiments, four first fans 205 are provided in a duct cavity, and the four first fans 205 are spaced apart along a second direction.

[0205] The temperature control assembly 200 provided in the embodiments of this application further includes an evaporator 203, which is disposed in the second cavity section 2102.

[0206] It is understandable that by setting up the evaporator 203, the evaporator 203 can reduce the fluid temperature of the airflow in the second cavity section 2102 during operation, thereby making the airflow blown into the receiving cavity have cooling capacity to reduce the internal temperature of the receiving cavity.

[0207] The temperature control assembly 200 provided in the embodiments of this application further includes a heater 204, which is disposed in the second cavity 2102.

[0208] It is understandable that by setting up heater 204, the heater 204 can increase the fluid temperature of the airflow in the second cavity section 2102 during operation, thereby giving the airflow blown into the receiving cavity heat and increasing the internal temperature of the receiving cavity.

[0209] The temperature control assembly 200 provided in the embodiments of this application further includes: a heat exchange chamber 211, which is arranged adjacent to and connected to the air duct chamber 210 along a first direction perpendicular to the height of the temperature control device.

[0210] It is understandable that by setting up the heat exchange cavity 211, heat exchange can occur between the air duct cavity 210 and the heat exchange cavity 211, so that the internal stability of the air duct cavity 210 is more stable.

[0211] The embodiments of this application provide two air duct cavities 210, which are disposed on opposite sides of the heat exchange cavity 211 along the first direction.

[0212] It is understandable that increasing the number of air duct cavities 210 can make the extension area of ​​the air duct cavities 210 larger, thereby improving the heat or cold energy transfer efficiency of the temperature-regulating airflow.

[0213] Furthermore, when there are two air duct cavities 210, four first fans 205 are respectively installed in the two air duct cavities 210, that is, there are eight first fans 205.

[0214] The temperature control assembly 200 provided in the embodiments of this application includes: a housing 201 and a first partition 202. The housing 201 is connected to the support assembly 100. The first partition 202 is disposed in the cavity of the housing 201. A portion of the housing 201 along the height direction of the temperature control device and the first partition 202 enclose each other to form a first cavity segment 2101. Another portion of the housing 201 along the height direction of the temperature control device and the first partition 202 enclose each other to form a second cavity segment 2102.

[0215] It is understandable that by providing the housing 201, it can be easily installed onto the support assembly 100, and the cavity of the housing 201 can also accommodate and protect other components. By providing the first partition 202, the space occupied by the first cavity section 2101 and the second cavity section 2102 inside the housing 201 can be reduced.

[0216] The temperature control assembly 200 provided in the embodiments of this application further includes: a second partition 206, which is disposed in the shell cavity and extends along a second direction perpendicular to the height of the temperature control device, and separates the air duct cavity 210 and the heat exchange cavity 211.

[0217] Understandably, by setting the second partition 206, the air duct cavity 210 and the heat exchange cavity 211 can be separated.

[0218] Furthermore, the second partition 206 is provided with ventilation holes, and the air duct cavity 210 and the heat exchange cavity 211 are connected through the ventilation holes.

[0219] It is understood that, through the above implementation method, the airflow in the air duct cavity 210 and the airflow in the heat exchange cavity 211 can be convected and exchanged through the ventilation holes, thereby making the airflow temperature in the air duct cavity 210 more uniform.

[0220] It should be noted that when there are two air duct cavities 210 along the first direction, and the two air duct cavities 210 are located on opposite sides of the heat exchange cavity 211, there are two second partitions 206, and the two second partitions 206 are spaced apart along the first direction.

[0221] The temperature control assembly 200 provided in the embodiments of this application further includes a condenser 207 disposed in the heat exchange chamber 211.

[0222] It is understandable that by setting up the condenser 207, the heat exchange chamber 211 can exchange heat with the outside of the box through the condenser 207, so as to reduce the internal temperature of the heat exchange chamber 211.

[0223] The temperature control component 200 provided in the embodiments of this application further includes: a second fan 208, disposed in the heat exchange chamber 211.

[0224] It is understandable that by setting up the second fan 208, the fluid velocity of the airflow inside the heat exchange chamber 211 can be increased, thereby reducing the internal temperature of the heat exchange chamber 211.

[0225] The temperature control assembly 200 provided in the embodiments of this application further includes a compressor 209 disposed in the heat exchange chamber 211.

[0226] It is understandable that by setting up compressor 209, the refrigerant inside compressor 209 can be delivered to condenser 207.

[0227] It should be noted that the compressor 209 contains refrigerant, and the temperature control device provided in the embodiments of this application also includes a throttling valve and connecting pipes. The compressor 209, condenser 207, throttling valve, and evaporator 203 are connected end to end in sequence through connecting pipes, and refrigerant flows through the compressor 209, condenser 207, throttling valve, evaporator 203, and connecting pipes.

[0228] It should be noted that this configuration allows the refrigerant to circulate within the compressor 209, condenser 207, expansion valve, evaporator 203, and connecting pipes, enabling the refrigerant's heat or cold energy to exchange heat with the air duct cavity 210 and heat exchange cavity 211.

[0229] The temperature control device provided in the embodiments of this application further includes a protective cover 700, which covers the temperature control component 200 on the side away from the support component 100 along the height direction of the temperature control device.

[0230] Understandably, by setting up the protective cover 700, the aesthetics of the temperature control component 200 can be improved, and water or dust from the external environment can be isolated.

[0231] This application provides an energy storage device, including a housing and a temperature control device provided in any of the above embodiments. The support component 100 of the temperature control device is sealed to the housing and forms the top wall of the housing.

[0232] It should be noted that the container can be an energy storage container, a commercial or industrial energy storage cabinet, a home energy storage device, or other types of energy storage equipment.

[0233] Finally, it should be noted that other embodiments of the invention will readily occur to those skilled in the art upon consideration of the specification and practice of the invention disclosed herein. This invention is intended to cover any variations, uses, or adaptations of the invention that follow the general principles of the invention and include common knowledge or customary techniques in the art not disclosed herein, and is not limited to the precise structures described above and shown in the accompanying drawings, and various modifications and changes can be made without departing from its scope. The scope of the invention is limited only by the appended claims.

Claims

1. A temperature regulating device, characterized in that, Installed in a housing, the housing having a receiving cavity, the temperature regulating device includes: A support assembly (100) is sealed to the housing to form the top wall of the housing; and A temperature control component (200) is disposed on the support component (100), and the temperature control component (200) is used to control the temperature inside the receiving cavity.

2. The temperature regulating device according to claim 1, characterized in that, The temperature control component (200) is disposed on the side of the support component (100) away from the receiving cavity; the temperature control component (200) is connected to the housing.

3. The temperature regulating device according to claim 1 or 2, characterized in that, The temperature control component (200) has an air vent (212), and the support component (100) has an opening (106) communicating with the receiving cavity. The air vent (212) is opposite to the opening (106) and is connected to the receiving cavity through the opening (106). The temperature regulating component (200) delivers temperature regulating airflow into the receiving cavity through the air vent (212) and the opening (106).

4. The temperature regulating device according to any one of claims 1-3, characterized in that, Also includes: The first sealing element (400) is arranged around the outer periphery of the support assembly (100) and sandwiched between the outer peripheral wall of the support assembly (100) and the inner side wall of the box, so as to form a sealing interface between the support assembly (100) and the box.

5. The temperature regulating device according to claim 3, characterized in that, Also includes: The second seal (500) is sandwiched between the support assembly (100) and the temperature control assembly (200) along the height direction of the temperature control device to form a sealing interface between the support assembly (100) and the temperature control assembly (200).

6. The temperature regulating device according to claim 5, characterized in that, The second seal (500) includes a sealing portion (501) and a through hole (502) formed on the sealing portion (501). Along the height direction of the temperature control device, the sealing part (501) is sandwiched between the support assembly (100) and the temperature control assembly (200). The through hole (502) is opposite to the opening (106) and the air vent (212). The opening (106) and the air vent (212) are connected through the through hole (502).

7. The temperature regulating device according to any one of claims 1-6, characterized in that, Also includes: Mounting assembly (300) is disposed between the outer peripheral wall of the temperature regulating assembly (200) and the inner side wall of the housing; The temperature control component (200) is connected to the inner wall of the housing via the mounting component (300).

8. The temperature regulating device according to claim 7, characterized in that, Along the height direction perpendicular to the temperature control device, the mounting assembly (300) is located on the side of the first seal (400) away from the support assembly (100), and the mounting assembly (300) protrudes outward on the outer peripheral wall of the temperature control assembly (200) away from the center of the temperature control assembly (200).

9. The temperature regulating device according to claim 7 or 8, characterized in that, Along a second direction perpendicular to the height direction of the temperature control device, the mounting components (300) are provided on opposite sides of the temperature control assembly (200).

10. The temperature regulating device according to claim 7 or 8, characterized in that, The mounting component (300) includes: The first mounting member (301) is located in a direction perpendicular to the height of the temperature regulating device and facing away from the center of the temperature regulating assembly (200). The first mounting member (301) protrudes outward from the outer peripheral wall of the temperature regulating assembly (200) and extends along the circumference of the temperature regulating assembly (200). Along the height direction of the temperature control device, the first mounting member (301) is connected to the support assembly (100) on the side close to the support assembly (100), and the first mounting member (301) forms a mounting surface (3011) on the side away from the support assembly (100).

11. The temperature regulating device according to claim 10, characterized in that, The mounting assembly (300) also includes: The second mounting member (302) is connected to the outer peripheral wall of the temperature regulating component (200); along the height direction of the temperature regulating device, the second mounting member (302) is located on the side of the first mounting member (301) away from the support component (100) and is connected to the mounting surface (3011) of the first mounting member (301).

12. The temperature regulating device according to claim 10 or 11, characterized in that, Multiple second mounting members (302) are provided, and the multiple second mounting members (302) are spaced apart along the extension direction of the first mounting member (301).

13. The temperature regulating device according to claim 3, characterized in that, Multiple air vents (212) are provided, and the multiple air vents (212) are arranged at intervals along the circumference of the temperature control component (200); The opening (106) is provided in multiple ways, and the multiple openings (106) are provided at intervals along the circumferential direction of the support component (100); The multiple air vents (212) and the multiple openings (106) are arranged opposite each other in a one-to-one correspondence and are interconnected.

14. The temperature regulating device according to claim 6, characterized in that, Multiple sealing portions (501) are provided, and multiple sealing portions (501) are spaced apart along the circumference of the temperature regulating component (200); the through holes (502) of the multiple sealing portions (501) are connected to the multiple air vents (212) in a one-to-one correspondence; Alternatively, the sealing part (501) extends circumferentially along the temperature regulating component (200) and has a plurality of through holes (502); the plurality of through holes (502) are spaced apart along the circumferential direction of the temperature regulating component (200); the plurality of through holes (502) are connected to the plurality of air vents (212) one by one.

15. The temperature regulating device according to claim 3 or 5, characterized in that, The temperature control component (200) is provided with an air guide hood (214) on its side wall. One end of the air guide hood (214) is connected to the air outlet (212), and the other end of the air guide hood (214) is connected to the opening (106). The air vent (212) and the opening (106) are connected by the air guide shroud (214).

16. The temperature regulating device according to claim 3 or 5, characterized in that, The plurality of air vents (212) include a plurality of air outlets (2122) and a plurality of air return vents (2121); Along the first direction, a plurality of the air outlets (2122) are disposed on opposite sides of the temperature control assembly (200), and a portion of the return air outlets (2121) are disposed on opposite sides of the temperature control assembly (200); On the same side of the temperature control assembly (200) perpendicular to the height direction, a plurality of air outlets (2122) are respectively placed on both sides of the return air inlet (2121) along the second direction; Along the second direction, another number of the return air vents (2121) are disposed on opposite sides of the temperature control assembly (200); The first direction and the second direction are perpendicular to each other and both are perpendicular to the height direction of the temperature control device.

17. The temperature regulating device according to any one of claims 1-16, characterized in that, The support component (100) includes: A support member (101) is provided, the outer peripheral wall of which is connected to the inner side wall of the housing, and an air vent (212) is provided on the support member (101). The first heat insulation element (102) is sandwiched between the support (101) and the temperature regulating component (200) along the height direction of the temperature regulating device.

18. The temperature regulating device according to claim 17, characterized in that, The support member (101) includes multiple sub-support members; Along the height direction perpendicular to the temperature control device, a plurality of sub-support members are arranged in an array, and two adjacent sub-support members are connected to each other.

19. The temperature regulating device according to claim 18, characterized in that, The first heat insulation element (102) includes a plurality of first sub-heat insulation elements; Along the vertical direction of the temperature control device, a plurality of first sub-insulation elements are arranged in an array, and two adjacent first sub-insulation elements are connected to each other. Multiple sub-support members and multiple first sub-insulation members are stacked one-to-one.

20. The temperature regulating device according to claim 19, characterized in that, The support component (100) also includes: The second heat insulation element (103) is connected to the side of the support element (101) away from the first heat insulation element (102).

21. The temperature regulating device according to claim 20, characterized in that, The second thermal insulation element (103) includes a plurality of second sub-thermal insulation elements; Along the height direction perpendicular to the temperature control device, a plurality of second sub-insulation elements are arranged in an array, and two adjacent second sub-insulation elements are connected to each other.

22. The temperature regulating device according to claim 21, characterized in that, The plurality of sub-support members and the plurality of first sub-insulation members are all spaced apart along a first direction; the first direction is perpendicular to the height direction of the temperature regulating device.

23. The temperature regulating device according to any one of claims 19-22, characterized in that, The support component (100) also includes: A first connector (104) extends along a first direction and is connected to a plurality of first sub-insulation members on the side opposite to the support member (101).

24. The temperature regulating device according to claim 23, characterized in that, The support component (100) also includes: The second connector (105) extends along the second direction and is connected between two adjacent sub-supports and between two adjacent first sub-insulations; The two ends of the second connector (105) in the extending direction are connected to the inner sidewall of the box; The second direction is perpendicular to the height direction of the temperature regulating device and is perpendicular to the first direction; The first connector (104) and the second connector (105) are connected to each other at the intersection of their extending directions.

25. The temperature regulating device according to claim 24, characterized in that, Multiple first connectors (104) are provided, and the multiple first connectors (104) are spaced apart along the second direction; Multiple second connectors (105) are provided, and the multiple second connectors (105) are spaced apart along the first direction; A plurality of the first connectors (104) and a plurality of the second connectors (105) form a grid structure.

26. The temperature regulating device according to claim 22, characterized in that, Also includes: The third connector extends along the first direction and connects between two adjacent second sub-insulation members.

27. The temperature regulating device according to any one of claims 1-26, characterized in that, Also includes: The reinforcing member (600) is sandwiched between the second sealing member (500) and the support member (101) along the height direction of the temperature regulating device; Along the height direction perpendicular to the temperature control device, the reinforcing member (600) is located on the side of the through hole (502) of the second seal (500) away from the edge of the second seal (500); the reinforcing member (600) extends along the extension direction of the second seal (500).

28. The temperature regulating device according to claim 16, characterized in that, The temperature control component (200) has an air duct cavity (210) that is connected to the air outlet (2122) and the air return port (2121).

29. The temperature regulating device according to claim 28, characterized in that, The air duct cavity (210) includes: The first cavity section (2101) is connected to the return air vent (2121); The second cavity section (2102) is connected to the air outlet (2122); Along the height direction of the temperature control device, the first cavity (2101) is located on the side of the second cavity (2102) near the support assembly (100).

30. The temperature regulating device according to claim 29, characterized in that, The temperature control component (200) includes: A first fan (205) is disposed in the air duct cavity (210). The air inlet of the first fan (205) is connected to the first cavity section (2101), and the air outlet of the first fan (205) is connected to the second cavity section (2102). The first fan (205) is used to transport the airflow of the first cavity section (2101) to the second cavity section (2102). An evaporator (203) is disposed within the second cavity (2102); and / or a heater (204) is disposed within the second cavity (2102).

31. The temperature regulating device according to claim 28 or 29, characterized in that, The temperature control assembly (200) also includes: The heat exchange chamber (211) and the air duct chamber (210) are arranged adjacent to each other and are interconnected along a first direction perpendicular to the height of the temperature control device.

32. The temperature regulating device according to claim 31, characterized in that, Two air duct cavities (210) are provided, and along the first direction, the two air duct cavities (210) are provided on opposite sides of the heat exchange cavity (211).

33. The temperature regulating device according to claim 31 or 32, characterized in that, The temperature control component (200) includes: The housing (201) is connected to the support assembly (100); A first partition (202) is disposed in the cavity of the housing (201). A portion of the housing (201) along the height direction of the temperature control device is enclosed with the first partition (202) to form a first cavity segment (2101). Another portion of the housing (201) along the height direction of the temperature control device is enclosed with the first partition (202) to form a second cavity segment (2102).

34. The temperature regulating device according to claim 33, characterized in that, The temperature control assembly (200) also includes: The second partition (206) is disposed in the shell cavity. The second partition (206) extends along a second direction perpendicular to the height of the temperature control device and separates the air duct cavity (210) and the heat exchange cavity (211).

35. The temperature regulating device according to any one of claims 31-34, characterized in that, The temperature control assembly (200) also includes: A condenser (207) is provided in the heat exchange chamber (211); And / or, a second fan (208) is provided in the heat exchange chamber (211); And / or, a compressor (209) is disposed in the heat exchange chamber (211).

36. The temperature regulating device according to any one of claims 1-35, characterized in that, Also includes: A protective cover (700) is provided along the height direction of the temperature regulating device, covering the side of the temperature regulating component (200) away from the support component (100).

37. An energy storage device comprising a housing and a temperature regulating device according to any one of claims 1-36, wherein a support assembly (100) of the temperature regulating device is sealed to the housing and forms the top wall of the housing.