Adjustable energy storage container suitable for multi-scene installation

Through the design of the installation and adaptation mechanisms, the energy storage container has achieved multi-scenario adaptability and temperature regulation, solving the problems of insufficient installation and temperature regulation in existing technologies, and improving the flexibility and efficiency of the container.

CN122178045APending Publication Date: 2026-06-09JIANGSU ZHUOAN POWER TECH CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Applications(China)
Current Assignee / Owner
JIANGSU ZHUOAN POWER TECH CO LTD
Filing Date
2026-04-07
Publication Date
2026-06-09

AI Technical Summary

Technical Problem

Existing energy storage containers cannot adjust the installation size and temperature in real time according to different scenarios, resulting in insufficient installation flexibility and temperature regulation flexibility.

Method used

By employing an installation mechanism and an adaptation mechanism, the length and capacity of the installation mechanism can be changed through bolt connections. Temperature control components are used to regulate the temperature environment, and servo motors and worm gear systems are combined to adjust heat dissipation efficiency, thereby enabling the container to adapt to multiple scenarios and regulate temperature.

Benefits of technology

It improves the flexibility of container installation and temperature control, enabling real-time adjustment of installation size and temperature according to different scenarios and environmental needs, thus enhancing the adaptability and efficiency of containers.

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Abstract

The present application relates to the technical field of energy storage container, in particular to an adjustable energy storage container suitable for multi-scene installation, comprising a mounting mechanism and an adapting mechanism, the adapting mechanism is arranged on both sides of the mounting mechanism, the mounting mechanism comprises a box assembly, a connecting assembly, an assembling assembly, a positioning assembly and a temperature control assembly, two connecting assemblies are arranged on the front side and the rear side of the box assembly respectively, and the assembling assembly is arranged at the four corners of the connecting assembly. The present application provides an adjustable energy storage container suitable for multi-scene installation, which has a structure for adjusting the installation mode of the container according to different scenes, can adjust the installation size of the container in real time according to the current scene, improves the flexibility of the container installation, and has a structure for adjusting the internal temperature of the container according to the current environment, so that the container can be insulated or cooled according to the current environment, thereby improving the flexibility of the internal temperature adjustment of the container.
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Description

Technical Field

[0001] This invention relates to the field of energy storage container technology, specifically to an adjustable energy storage container adaptable to installation in multiple scenarios. Background Technology

[0002] As is well known, Containerized Energy Storage System (CESS) is an integrated energy storage system developed to meet the needs of the mobile energy storage market. It integrates battery cabinets, lithium battery management system (BMS), bidirectional energy storage converter (PCS), container monitoring system, fire protection system, cooling system, etc., and can also integrate energy storage converter, energy management system, etc. according to customer needs.

[0003] A search revealed a Chinese patent for an energy storage container, application publication number CN118281452B. This patent includes a frame and multiple battery racks. The frame includes multiple corner posts, each extending along the direction of gravity. The multiple battery racks are installed within the frame and spaced apart to create an installation space for battery packs between adjacent racks. Each corner post includes at least one first corner post, adjacent to a battery rack. The first corner post has an inner side facing the battery rack, with the inner portion recessed inwards in the direction away from the battery rack to form an accommodating space. This accommodating space accommodates at least a portion of the battery rack. By recessing the inner side of the first corner post in the direction away from the battery rack to form the accommodating space, the first corner post can accommodate at least a portion of the battery rack installed on the frame through this accommodating space. Its advantage is improved structural compactness of the energy storage container.

[0004] When installing energy storage containers in various scenarios, the shape of the container is adapted to the current scenario. The problem with existing technology is that, due to the lack of a structure to adjust the container installation method according to different scenarios, it is impossible to adjust the installation size of the container in real time according to the current scenario, which reduces the flexibility of container installation. Furthermore, it lacks a structure to adjust the internal temperature of the container according to the current environment, so it is impossible to insulate or cool the container according to the current environment, which reduces the flexibility of internal temperature regulation. Summary of the Invention

[0005] To address the shortcomings of existing technologies, this invention provides an adjustable energy storage container adaptable to various installation scenarios. It features a structure that adjusts the container's installation method according to different scenarios, allowing for real-time adjustment of the container's size based on the current environment, thus improving the flexibility of container installation. Furthermore, it has a structure that adjusts the container's internal temperature according to the current environment, enabling insulation or cooling of the container based on the current conditions, thereby enhancing the flexibility of internal temperature regulation.

[0006] The above-mentioned technical objective of the present invention is achieved through the following technical solution: an adjustable energy storage container adaptable to multiple installation scenarios, comprising an installation mechanism and an adaptation mechanism, wherein the adaptation mechanism is disposed on both sides of the installation mechanism, the installation mechanism comprising a container assembly, a connecting assembly, an assembly assembly, a positioning assembly, and a temperature control assembly, two connecting assemblies respectively disposed on the front and rear sides of the container assembly, the assembly assembly disposed at the four corners of the connecting assemblies, two positioning assemblies respectively disposed on both sides of the container assembly, and the temperature control assembly disposed inside the positioning assemblies, the adaptation mechanism comprising a limiting assembly, a liquid delivery assembly, a switching assembly, and an adjusting assembly, two limiting assemblies respectively disposed between opposite sides of the temperature control assembly, the liquid delivery assembly disposed inside the limiting assembly, the switching assembly disposed on the surface of the liquid delivery assembly, and the adjusting assembly disposed between opposite sides of the positioning assemblies, wherein the surface of the adjusting assembly engages with the switching assembly.

[0007] By adopting the above technical solution, and by setting up an installation mechanism and an adaptation mechanism, the installation mechanisms can be stacked one after another according to the installation requirements of the current scenario and connected with bolts, thereby changing the length and capacity of the installation mechanism. By changing the length, the effect of adapting to the current scenario can be achieved. The adaptation mechanism can adjust the temperature environment inside the installation mechanism according to the current scenario, thereby adjusting the heat dissipation capacity to achieve the effect of adjusting the temperature environment inside the installation mechanism.

[0008] The present invention is further configured such that: the box assembly includes a box plate, a box connecting block and a box connecting hole, the box connecting block is welded to both sides of the box plate respectively, and the box connecting hole passes through the front and rear sides of the box connecting block.

[0009] By adopting the above technical solution, the container panel can be combined with the container connecting block and the container connecting hole to form the bottom and top plates of the container. The container panel can be installed on the surface of the top and bottom assembly rods through the container connecting block and the container connecting hole, so that the two container panels can be combined to form the bottom and top plates of the container by using the top and bottom assembly rods as support points.

[0010] The present invention is further configured such that: the connecting assembly includes a connecting square frame, a connecting sealing sleeve, and a connecting sealing plate; the two connecting square frames are respectively bolted to the front and rear sides of the housing plate; the connecting sealing sleeve is bolted to the inner side of the connecting square frame; the connecting sealing plate is bolted between the four opposite corners of the connecting square frame; and the opposite sides of the connecting sealing plate are bolted to both sides of the housing plate.

[0011] By adopting the above technical solution, and by setting up connecting components, the connecting square frame can form a structure that provides limiting seals for the container panels, positioning shells, and container partitions, together with the connecting sealing sleeves and connecting sealing plates. The connecting square frame can be connected to the connecting sealing plates to form a cubic frame. The connecting square frame provides support for the assembly components, and the square connecting square frame can provide seals for the container panels, positioning shells, and container partitions on opposite sides through the connecting sealing sleeves. This allows the upper and lower container panels, the left and right positioning shells, and the left and right container partitions to form a container structure. Furthermore, the connecting sealing plates provide seals at the connection points between the top container panel and the positioning shells on both sides, and seals at the bottom of the bottom container panel and the bottom of the container partitions on both sides, creating a sealed space inside the container structure.

[0012] The present invention is further configured such that: the assembly component includes assembly plates, assembly blocks and assembly square rods, eight assembly plates are respectively bolted to the four corners of the front side and the four corners of the rear side of the connecting square frame, four assembly blocks are respectively welded to the four corners of the front side and the four corners of the rear side of the assembly plates, and four assembly square rods are respectively welded between opposite sides of the assembly blocks, and the surface of the assembly square rods is engaged with the inner side of the box body connection hole.

[0013] By adopting the above technical solution, and by setting up assembly components, the assembly plate can form a structure with the assembly blocks and assembly rods to provide connections for the container connecting blocks, positioning connecting blocks, and partition connecting blocks. Multiple assembled container structures can be interconnected to adapt to the current scenario. The assembly plate, with the connecting frame as a support point, provides support for the assembly blocks and assembly rods. The assembly rods can be limited by the container connecting holes, positioning connecting holes, and partition connecting holes, respectively. Therefore, the container partitions can be connected to the positioning shell and container panels to form a container structure. Furthermore, by bolting the current container structure to the assembly blocks on another container structure, multiple container structures can be interconnected, increasing the overall capacity and length of the container. This increased length allows for adaptation to different installation scenarios.

[0014] The present invention is further configured such that: the positioning component includes a positioning shell, a positioning groove, a movable groove, a positioning connecting block, and a positioning connecting hole; the positioning connecting block has positioning connecting holes extending through its front and rear sides; the two positioning connecting blocks are respectively snapped onto the surface of the top assembled square rod through the positioning connecting holes; the two positioning shells are respectively welded to the bottom of the two positioning connecting blocks; the positioning groove is formed at the top of the inner side of the positioning shell; the movable groove is formed at the bottom of the inner side of the positioning shell; and the top of the movable groove communicates with the positioning groove.

[0015] By adopting the above technical solution, the positioning shell can form a switching component limiting structure with the positioning groove, the movable groove, the positioning connecting block and the positioning connecting hole by setting the positioning component. The bottom of the positioning shell is connected to the top of the container partition, and it can form the container walls on both sides of the container with the container partition. The positioning groove can form a space for the worm gear to rotate with the movable groove. The positioning connecting block can be connected to the assembly square rods on both sides of the top through the positioning connecting hole, and the assembly square rods on both sides of the top provide support for the positioning shell as support points.

[0016] The present invention is further configured such that: the temperature control component includes a box partition, a contact arc plate, heat-conducting fins, a partition connecting block, and a partition connecting hole; two box partitions are respectively welded to both sides of the bottom of the positioning shell; the contact arc plate is welded to both sides of the box partition; the heat-conducting fins are welded to the outer surface of the contact arc plate; the partition connecting block is welded to the bottom of the box partition; the partition connecting hole extends through the front side of the partition connecting block; and the partition connecting block is snapped onto the surface of the bottom assembly square rod through the partition connecting hole.

[0017] By adopting the above technical solution, and by setting up a temperature control component, the cabinet partition can be combined with the contact arc plate, heat-conducting fins, partition connecting block, and partition connecting hole to form a structure for switching component heat dissipation. By connecting the partition connecting block and partition connecting hole to the assembly rod, the assembly rod can limit the cabinet partition to both sides of the bottom cabinet plate. Through the heat dissipation structure composed of the contact arc plate and the heat-conducting fins, the heat of the arc-shaped heat-conducting plate can be dissipated through the heat-conducting fins when the arc-shaped heat-conducting plate contacts the contact arc plate, thus achieving the effect of heat dissipation for the arc-shaped heat-conducting plate.

[0018] The present invention is further configured such that: the limiting component includes a positioning block, a rotating groove and a movable groove, the positioning block is engaged between the inner side of the box partition and the side opposite to the contact arc plate, the rotating groove is opened on the inner side of the contact arc plate, and the movable groove is opened at the bottom of the inner side of the contact arc plate.

[0019] By adopting the above technical solution, by setting a limiting component, the positioning block can form a structure that provides support and limitation for the liquid delivery component together with the rotating groove and the movable groove. The positioning block provides a limit for the coolant pipe, allowing the coolant pipe to be placed in the rotating groove. The rotating groove provides a space for the rotation of the arc-shaped heat-conducting plate, allowing the arc-shaped heat-conducting plate to rotate freely along the axial direction of the coolant pipe. The movable groove provides a space for the liquid outlet, allowing the liquid outlet to adapt to the position of the coolant circulation and delivery equipment when connected to it.

[0020] The present invention is further configured such that: the liquid delivery assembly includes a liquid inlet, a coolant pipe and a liquid outlet, the coolant pipe is snapped into the inner side of the positioning block, the surface of the coolant pipe is close to the inner side of the rotating groove, the liquid inlet is connected to the front side of the top of the coolant pipe, and the liquid outlet is connected to the front side of the bottom of the coolant pipe.

[0021] By adopting the above technical solution, and by setting up a liquid delivery component, the liquid inlet can form a coolant circulation and delivery device with the coolant pipe and the liquid outlet. The liquid inlet is connected to the output end of the coolant circulation and delivery system of the energy storage device, and the liquid outlet is connected to the input end of the coolant circulation and delivery system of the energy storage device. This allows the coolant to enter through the liquid inlet, be delivered through the coolant pipe to the liquid outlet, and finally returned to the coolant circulation and delivery system of the energy storage device. After passing through the coolant pipe and the arc-shaped heat-conducting fins for heat dissipation, further heat dissipation of the coolant can be achieved.

[0022] The invention is further configured such that: the switching assembly includes a worm gear, a rotating ring, and an arc-shaped heat-conducting plate; two rotating rings are rotatably connected to the top and bottom of the surface of the coolant pipe, respectively; the arc-shaped heat-conducting plate is welded between the top and bottom opposite sides of the rotating ring; the inner side of the arc-shaped heat-conducting plate is in contact with the surface of the coolant pipe; the surface of the arc-shaped heat-conducting plate is in contact with the inner side of the contact arc plate; the worm gear is bolted to the top of the top rotating ring; and the surface of the worm gear is close to the inner side of the movable groove.

[0023] By adopting the above technical solution and setting a switching component, the worm gear can form a heat dissipation capacity switching structure with the rotating ring and the arc-shaped heat-conducting plate. As the worm gear rotates with the worm, it can drive the rotating ring to adjust the position of the arc-shaped heat-conducting plate within the contact arc plate. By rotating the arc-shaped heat-conducting plate, the contact area between it and the contact arc plate can be changed. Thus, by changing the contact area or directly preventing it from contacting the contact arc plate, the efficiency of the arc-shaped heat-conducting plate in dissipating heat from the coolant in the coolant pipe through the contact arc plate can be adjusted. This allows the adjustment of heat dissipation efficiency to adapt to the temperature required inside the container in the current scenario.

[0024] The present invention is further configured such that: the adjustment assembly includes a servo motor, a worm gear, and a fixed plate; the servo motor is bolted to the rear side of the top between opposite sides of the housing partition; the worm gear is bolted to the output end of the front side of the servo motor; the fixed plate is bolted to the front side of the top between opposite sides of the housing partition; the front side of the worm gear is rotatably connected to the rear side of the fixed plate; and the surface of the worm gear meshes with the surface of the worm wheel.

[0025] By adopting the above technical solution, and by setting an adjustment component, the servo motor can form a structure with the worm and the fixed plate to provide transmission for the worm wheel. The servo motor drives the worm to rotate along the fixed plate, so that the worm can contact the worm wheel when rotating and gradually and continuously push the worm wheel to rotate. Thus, when the worm wheel rotates, it drives the rotating ring to rotate the arc-shaped heat-conducting plate. Therefore, the contact mode between the arc-shaped heat-conducting plate and the contact arc plate can be changed, thereby changing the heat dissipation efficiency.

[0026] Compared with existing technologies, the present invention provides an adjustable energy storage container that is adaptable to installation in multiple scenarios, and has the following beneficial effects: This adjustable energy storage container, adaptable to various installation scenarios, features a square frame as its connecting component. The sides of the container panel are welded to the connecting component. Evenly distributed container connecting blocks are welded to or installed via fasteners on the front and back of the container panel. Each connecting block has a connecting hole. A positioning shell of the positioning component and a container partition of the temperature control component are welded to the positioning shell to form the side panels of the container. The top surface of the positioning shell is evenly distributed with positioning connecting blocks, each with a positioning connecting hole. The bottom surface of the container partition is evenly distributed with partition connecting blocks, each with a partition connecting hole. The welded side panels are then installed... On both sides of the container, the positioning connecting blocks on the upper part of the side panel are placed within the gaps between the evenly distributed container connecting blocks above; the partition connecting blocks on the lower part of the side panel are placed within the gaps between the evenly distributed container connecting blocks below. At this point, the connecting holes are coaxial with the container connecting holes of the upper container connecting blocks, and the partition connecting holes are coaxial with the container connecting holes of the lower container connecting blocks. The assembly component includes assembly square rods, which are inserted into the channels formed by the coaxial connecting holes of the upper and lower container connecting blocks, respectively, and the partition connecting holes are coaxial with the container connecting holes of the lower container connecting blocks. Within the assembled passageway, the assembly components include assembly panels, which are installed on the connecting frame using bolts and nuts through drilling. These panels are present at all eight corners of the container. The other sides of the container are fitted with hinged doors, which are existing technology and will not be elaborated upon here. Specifically, the side panels on both sides of the container, formed by the positioning shell and the container partitions, can be connected to the sides of the assembly frame rod via positioning connecting blocks and holes, respectively. This allows the positioning shell, container partitions, and container panels to form the container structure. The connecting frame serves as the connection sealing sleeve and... The connecting sealing plate provides a limit, allowing the connection between the connecting frame and the container panel, positioning shell, and the front and rear sides of the container partition to be sealed. The connecting sealing plate can seal the connection between the container panel and the positioning shell and the container partition, creating a sealed space inside the container structure. The assembly plate provides a limit for the assembly blocks, allowing the assembly blocks to bolt the current container structure to the assembly blocks on another identical container structure, thereby connecting multiple container structures to each other, increasing the container's capacity and length, and using the change in container length to adapt to the current installation conditions. This adjustable energy storage container, adaptable to various installation scenarios, incorporates an adaptation mechanism. The limiting component, along with a liquid delivery component, a switching component, and an adjustment component, forms a structure for regulating the internal temperature environment of the container. A power transmission structure consisting of a servo motor, a worm gear, and a fixed plate allows the servo motor to drive the worm gear to rotate along the fixed plate, providing the necessary power for the rotating ring. A temperature switching structure, composed of a worm wheel, a rotating ring, and an arc-shaped heat-conducting plate, allows the rotating ring to change the position of the arc-shaped heat-conducting plate as the worm wheel rotates, causing the plate to rotate axially around the coolant pipe. This changes the contact area between the surface of the arc-shaped heat-conducting plate and the contact plate, adjusting the heat dissipation efficiency and thus the cooling efficiency of the coolant in the coolant pipe. Temperature regulation is ultimately achieved by adjusting the temperature of the coolant to change the temperature environment inside the container. The coolant delivery structure, consisting of an inlet, coolant pipes, and an outlet, connects to the input end of the energy storage device's coolant circulation system via the outlet and to the output end via the inlet. This allows coolant to enter through the inlet, flow through the coolant pipes, and return through the outlet, achieving coolant circulation. The coolant pipes also dissipate heat through the arc-shaped heat-conducting fins. A limiting structure, consisting of a positioning block, a rotating groove, and a movable groove, limits the rotation of the rotating ring and guides its rotation. The rotating groove provides space for the rotation of the arc-shaped heat-conducting fins, and the movable groove provides space for displacement that may occur when the inlet connects to the output end of the energy storage device's coolant circulation system. Attached Figure Description

[0027] Figure 1 This is a schematic diagram of the overall structure of the present invention; Figure 2 This is a schematic diagram of the installation mechanism in this invention; Figure 3 This is a schematic diagram of the structure of the housing assembly in this invention; Figure 4 This is a schematic diagram of the structure of the connecting component, the assembly component, and the positioning component in this invention; Figure 5 This is a schematic diagram of the temperature control component in this invention; Figure 6 This is a schematic diagram of the adaptive mechanism in this invention; Figure 7 This is a schematic diagram of the structure of the limiting component and the liquid delivery component in this invention; Figure 8 This is a schematic diagram of the switching component and the adjustment component in this invention.

[0028] In the diagram: 1. Installation mechanism; 11. Housing assembly; 111. Housing panel; 112. Housing connecting block; 113. Housing connecting hole; 12. Connecting assembly; 121. Connecting square frame; 122. Connecting sealing sleeve; 123. Connecting sealing plate; 13. Assembly assembly; 131. Assembly plate; 132. Assembly block; 133. Assembly square rod; 14. Positioning assembly; 141. Positioning shell; 142. Positioning groove; 143. Movable groove; 144. Positioning connecting block; 145. Positioning connecting hole; 15. Temperature control assembly; 151 1. Box partition; 152. Contact arc plate; 153. Heat-conducting fins; 154. Partition connecting block; 155. Partition connecting hole; 2. Adaptation mechanism; 21. Limiting component; 211. Positioning block; 212. Rotating groove; 213. Movable groove; 22. Liquid delivery component; 221. Liquid inlet; 222. Coolant pipe; 223. Liquid outlet; 23. Switching component; 231. Worm gear; 232. Rotary ring; 233. Arc-shaped heat-conducting plate; 24. Adjustment component; 241. Servo motor; 242. Worm; 243. Fixing plate. Detailed Implementation

[0029] The technical solutions of the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings. Obviously, the described embodiments are only some embodiments of the present invention, and not all embodiments. Based on the embodiments of the present invention, all other embodiments obtained by those skilled in the art without creative effort are within the scope of protection of the present invention.

[0030] Example 1: Please see Figures 1-5 An adjustable energy storage container adaptable to multiple installation scenarios includes an installation mechanism 1. The installation mechanism 1 includes a container assembly 11, a connecting assembly 12, an assembly assembly 13, a positioning assembly 14, and a temperature control assembly 15. Two connecting assemblies 12 are respectively located on the front and rear sides of the container assembly 11. The assembly assembly 13 is located at the four corners of the connecting assembly 12. Two positioning assemblies 14 are respectively located on both sides of the container assembly 11. The temperature control assembly 15 is located inside the positioning assembly 14. By setting the installation mechanism 1, the container assembly 11 can form a container structure with the connecting assembly 12, the assembly assembly 13, the positioning assembly 14, and the temperature control assembly 15. The connecting assembly 12 consists of two square frames. The two sides of the container panel 111 are welded to the connecting assembly 12. The front and rear of the container panel 111 are respectively welded or installed with fasteners. The container connecting blocks 112 are provided with container connection holes 113.

[0031] The positioning housing 141 of the positioning assembly 14 and the box partition 151 of the temperature control assembly 15 are welded to the positioning housing 141 to form the side plate of the box. The top surface of the positioning housing 141 is evenly distributed with positioning connecting blocks 144, each with a positioning connecting hole 145. The bottom surface of the box partition 151 is evenly distributed with partition connecting blocks 154, each with a partition connecting hole 155. The welded side plate is installed on both sides of the container, with the upper part of the side plate's positioning connecting blocks 144 placed within the gaps of the evenly distributed box connecting blocks 112 above. The lower part of the side plate's partition connecting blocks... Block 154 is placed in the gap between the evenly distributed box connecting blocks 112 below. At this time, the connecting hole 145 is coaxial with the box connecting hole 113 of the upper box connecting block 112, and the partition connecting hole 155 is coaxial with the box connecting hole 113 of the lower box connecting block 112. The assembly component 13 includes four assembly square rods 133, which are respectively inserted into the channel formed by the coaxial connection hole 145 and the box connecting hole 113 of the upper box connecting block 112, and the channel formed by the coaxial connection hole 155 of the partition connecting hole 155 and the box connecting hole 113 of the lower box connecting block 112.

[0032] Assembly component 13 includes assembly plate 131, which is installed on the connecting square frame 121 by means of bolts and nuts and by drilling. It has doors on all eight corners of the container. The other sides of the container are fitted with hinged doors that can be opened. This is prior art and will not be described in detail here.

[0033] Specifically, the side panels on both sides of the container, which are composed of the positioning shell 141 and the box partition 151, can be connected to both sides of the assembly square rod 133 via positioning connecting blocks 144 and positioning connecting holes 145, and to the partition connecting blocks 154 and partition connecting holes 155, respectively. This allows the positioning shell 141, the box partition 151, and the box panel 111 to form a container structure. The connecting square frame 121 provides limiting for the connecting sealing sleeve 122 and the connecting sealing plate 123, allowing the connecting square frame 121 to connect with the box panel 111, the positioning shell 141, and the box partition 151. The front and rear connections are sealed, allowing the connecting sealing plate 123 to seal the connection between the container panel 111 and the positioning shell 141 and the container partition 151, creating a sealed space inside the container structure. The assembly plate 131 provides a limit for the assembly block 132, allowing the assembly block 132 to bolt the current container structure to another assembly block 132 on the same container structure, thereby connecting multiple container structures to each other, increasing the container's capacity and length, and using the change in container length to adapt to the current installation conditions.

[0034] Please see Figure 3The container assembly 11 includes a container panel 111, a container connecting block 112, and a container connecting hole 113. The container connecting block 112 is welded to both sides of the container panel 111, and the container connecting hole 113 passes through the front and rear sides of the container connecting block 112. By setting the container assembly 11, the container panel 111 can form the bottom and top plates of the container together with the container connecting block 112 and the container connecting hole 113. Through the container connecting block 112 and the container connecting hole 113, the container panel 111 can be installed on the surface of the top and bottom assembly rods 133, so that the two container panels 111 can be formed into the bottom and top plates of the container by using the top and bottom assembly rods 133 as support points.

[0035] Please see Figure 4 The connecting assembly 12 includes a connecting square frame 121, a connecting sealing sleeve 122, and a connecting sealing plate 123. The two connecting square frames 121 are bolted to the front and rear sides of the housing plate 111, respectively. The connecting sealing sleeve 122 is bolted to the inner side of the connecting square frame 121. The connecting sealing plate 123 is bolted between the four opposite corners of the connecting square frame 121, and the opposite sides of the connecting sealing plate 123 are bolted to both sides of the housing plate 111. By setting the connecting assembly 12, the connecting square frame 121, together with the connecting sealing sleeve 122 and the connecting sealing plate 123, forms a structure that provides a limiting seal for the housing plate 111, the positioning shell 141, and the housing partition 151. 21 can be connected to the connecting sealing plate 123 to form a cubic frame. The connecting square frame 121 provides support for the assembly component 13. The square connecting square frame 121 can provide a seal for the box panel 111, positioning shell 141 and box partition 151 on opposite sides through the connecting sealing sleeve 122. Thus, the upper and lower box panels 111, the left and right positioning shells 141 and the left and right box partitions 151 form a container structure. The connecting sealing plate 123 provides a seal at the connection between the top box panel 111 and the positioning shell 141 on both sides, and seals the bottom box panel 111 and the bottom of the box partition 151 on both sides, so that a sealed space is formed inside the container structure.

[0036] Please see Figure 4The assembly component 13 includes assembly plates 131, assembly blocks 132, and assembly rods 133. Eight assembly plates 131 are bolted to the four corners of the front and four corners of the connecting frame 121, respectively. Four assembly blocks 132 are welded to the four corners of the front and four corners of the rear of the assembly plates 131, respectively. Four assembly rods 133 are welded to the opposite sides of the assembly blocks 132, respectively. The surface of the assembly rods 133 engages with the inner side of the container connection holes 113. By setting the assembly component 13, the assembly plates 131, assembly blocks 132, and assembly rods 133 can form a structure that provides connection for the container connecting blocks 112, positioning connecting blocks 144, and partition connecting blocks 154, and can interconnect and adapt multiple assembled container structures. In the current scenario, the assembly plate 131 provides support for the assembly block 132 and the assembly rod 133 by using the connecting frame 121 as a support point. The assembly rod 133 can provide limit for the box connecting block 112, the positioning connecting block 144, and the partition connecting block 154 respectively through the box connecting hole 113, the positioning connecting hole 145, and the partition connecting hole 155. Therefore, the box partition 151 can be connected to the positioning shell 141 and the box plate 111 to form a container structure. Then, the current container structure is bolted to the assembly block 132 on another container structure through the assembly block 132. This can achieve the effect of connecting multiple container structures to each other, increasing the overall capacity and length of the container, and using the increased length to adapt to different installation scenarios.

[0037] Please see Figure 4 The positioning assembly 14 includes a positioning housing 141, a positioning groove 142, a movable groove 143, a positioning connecting block 144, and a positioning connecting hole 145. Positioning connecting holes 145 penetrate the front and rear sides of the positioning connecting block 144. Two positioning connecting blocks 144 are respectively engaged with the surface of the top-assembled square rod 133 through the positioning connecting holes 145. Two positioning housings 141 are respectively welded to the bottom of the two positioning connecting blocks 144. The positioning groove 142 is formed at the top of the inner side of the positioning housing 141, and the movable groove 143 is formed at the bottom of the inner side of the positioning housing 141. The top of the movable groove 143 communicates with the positioning groove 142. The positioning component 14 is placed, and the positioning housing 141 can be combined with the positioning groove 142, the movable groove 143, the positioning connecting block 144, and the positioning connecting hole 145 to form a structure for limiting the switching component 23. The bottom of the positioning housing 141 is connected to the top of the container partition 151, and it can form the container walls on both sides of the container with the container partition 151. The positioning groove 142 can be combined with the movable groove 143 to form a space for the worm gear 231 to rotate. The positioning connecting block 144 can be connected to the assembly square rods 133 on both sides of the top through the positioning connecting hole 145, and the assembly square rods 133 on both sides of the top provide support for the positioning housing 141.

[0038] Please see Figure 5The temperature control assembly 15 includes a housing partition 151, a contact arc plate 152, heat-conducting fins 153, a partition connecting block 154, and a partition connecting hole 155. Two housing partitions 151 are welded to the bottom sides of the positioning shell 141, respectively. The contact arc plate 152 is welded to both sides of the housing partition 151. The heat-conducting fins 153 are welded to the outer surface of the contact arc plate 152. The partition connecting block 154 is welded to the bottom of the housing partition 151. The partition connecting hole 155 extends through the front side of the partition connecting block 154. The partition connecting block 154 is snapped onto the surface of the bottom assembly square rod 133 through the partition connecting hole 155. By setting the temperature control assembly 15... The enclosure partition 151 can be combined with the contact arc plate 152, heat-conducting fins 153, partition connecting block 154, and partition connecting hole 155 to form a heat dissipation structure for the switching component 23. It is connected to the assembly rod 133 through the partition connecting block 154 and partition connecting hole 155, so that the assembly rod 133 can limit the enclosure partition 151 to both sides of the bottom enclosure plate 111. Through the heat dissipation structure formed by the contact arc plate 152 and the heat-conducting fins 153, when the arc-shaped heat-conducting plate 233 contacts the contact arc plate 152, the heat of the arc-shaped heat-conducting plate 233 can be dissipated through the heat-conducting fins 153, thus achieving the effect of heat dissipation for the arc-shaped heat-conducting plate 233.

[0039] Please see Figure 7 The limiting component 21 includes a positioning block 211, a rotating groove 212, and a movable groove 213. The positioning block 211 engages with the inner side of the housing partition 151 near the opposite side of the contact arc plate 152. The rotating groove 212 is located on the inner side of the contact arc plate 152, and the movable groove 213 is located at the bottom of the inner side of the contact arc plate 152. By setting the limiting component 21, the positioning block 211, the rotating groove 212, and the movable groove 213 can form a structure that provides support and limits for the liquid delivery component 22. The structure provides a limit for the coolant pipe 222 through the positioning block 211, allowing the coolant pipe 222 to be positioned within the rotating groove 212. The rotating groove 212 provides a space for the rotation of the arc-shaped heat-conducting plate 233, allowing the arc-shaped heat-conducting plate 233 to rotate freely along the axial direction of the coolant pipe 222. The movable groove 213 provides a space for the outlet 223, allowing the outlet 223 to adapt to the position of the coolant circulation and delivery equipment when connected to it.

[0040] The working principle of this embodiment is as follows: First, when the container needs to be installed in an open area, the bottom container panel 111 is placed on the ground. Then, the container partition 151 equipped with the positioning component 14 is interlocked with the container connecting block 112 on the bottom container panel 111 via the partition connecting block 154, until the container partition 151 is perpendicular to the ground and the angle between the container partition 151 and the bottom container panel 111 is 90 degrees, while maintaining the container connection holes. Align 113 with the partition connecting hole 155, then insert the assembly square rods 133 on both sides of the bottom into the box connecting hole 113 and the partition connecting hole 155 in sequence. Then, insert the top box plate 111 into the positioning connecting block 144 through the box connecting block 112 in an alternating manner. Then, insert the assembly square rods 133 on both sides of the top into the positioning connecting hole 145 and the box connecting hole 113 in sequence. At this time, the box plate 111 will form a square tube structure with the positioning shell 141 and the box partition 151. The assembly block 132 is located at the position of the assembly square rod 133 connected to it, that is, at the front and rear four corners of the current tubular structure. Then, the connecting square frame 121 of the bolt-connected sealing sleeve 122 and the connecting sealing plate 123 is installed in the assembly plate 131. The connecting sealing plate 123 will be inserted into the connection between the box plate 111 and the positioning shell 141 and the connection between the box partition 151 and the box plate 111, respectively. The connecting sealing sleeve 122 will contact the front and rear sides of the box plate 111, the positioning shell 141 and the box partition 151, respectively. Finally, the container door is installed in the connecting square frame 121, and the assembly of the current container is completed. Then, another container assembled in the same way is placed directly behind the current container. Then, the box door between the current container and the rear container is removed, and the assembly block 132 on the rear side of the current container is connected to the assembly block 132 on the front side of the rear container by bolts, and the scene-adaptive assembly of the container is completed.

[0041] Example 2: Based on Example 1, and referring to Figures 6-8An adjustable energy storage container adaptable to multiple installation scenarios also includes an adaptation mechanism 2. The adaptation mechanism 2 includes a limiting component 21, a liquid delivery component 22, a switching component 23, and an adjusting component 24. Two limiting components 21 are respectively located between opposite sides of the temperature control component 15. The liquid delivery component 22 is located inside the limiting components 21. The switching component 23 is located on the surface of the liquid delivery component 22. The adjusting component 24 is located between opposite sides of the positioning component 14, and its surface engages with the switching component 23. By setting the adaptation mechanism 2, the limiting component 21 can engage with the liquid delivery component 22, the switching component 23, and the... The adjustment assembly 24 forms a structure for regulating the internal temperature environment of the container structure. Through the power transmission structure consisting of a servo motor 241, a worm gear 242, and a fixed plate 243, the servo motor 241 drives the worm gear 242 to rotate along the fixed plate 243, thus providing the rotational power required for the rotating ring 232. Through the temperature switching structure consisting of a worm wheel 231, a rotating ring 232, and an arc-shaped heat-conducting plate 233, the rotation of the worm wheel 231 drives the rotating ring 232 to change the position of the arc-shaped heat-conducting plate 233, allowing the arc-shaped heat-conducting plate 233 to rotate around the coolant pipe 222 as its axis. The rotation causes the contact area between the surface of the arc-shaped heat-conducting plate 233 and the contact arc plate 152 to change, thereby adjusting the heat dissipation efficiency. This adjustment in heat dissipation efficiency, in turn, alters the temperature of the coolant in the coolant pipe 222, ultimately changing the temperature environment inside the container. The coolant delivery structure, consisting of the inlet 221, coolant pipe 222, and outlet 223, connects to the input of the energy storage device's coolant circulation system via the outlet 223 and to the output of the same system via the inlet 221. Coolant enters through inlet 221, flows through coolant pipe 222 and returns through outlet 223, achieving coolant circulation. Coolant pipe 222 dissipates heat from the coolant through arc-shaped heat-conducting fins 233. The positioning block 211, rotating groove 212, and movable groove 213 form a limiting structure. The positioning block 211 limits the rotation of the rotating ring 232 and guides its rotation. The rotating groove 212 provides space for the rotation of the arc-shaped heat-conducting fins 233, and the movable groove 213 provides space for the displacement that occurs when the inlet 221 connects to the output end of the coolant circulation system of the energy storage device.

[0042] Please see Figure 7The liquid delivery assembly 22 includes an inlet 221, a coolant pipe 222, and an outlet 223. The coolant pipe 222 is snapped into the inner side of the positioning block 211, and the surface of the coolant pipe 222 is close to the inner side of the rotating groove 212. The inlet 221 is connected to the front side of the top of the coolant pipe 222, and the outlet 223 is connected to the front side of the bottom of the coolant pipe 222. By setting the liquid delivery assembly 22, the inlet 221 can form a coolant circulation and delivery device with the coolant pipe 222 and the outlet 223. The inlet 221 is connected to the output end of the coolant circulation and delivery system of the energy storage device, and the outlet 223 is connected to the input end of the coolant circulation and delivery system of the energy storage device. This allows the coolant to enter through the inlet 221, be delivered through the coolant pipe 222 to the outlet 223, and finally be returned to the coolant circulation and delivery system of the energy storage device. The coolant is further cooled by the arc-shaped heat-conducting plate 233 through the coolant pipe 222.

[0043] Please see Figure 8 The switching assembly 23 includes a worm gear 231, a rotating ring 232, and an arc-shaped heat-conducting plate 233. Two rotating rings 232 are rotatably connected to the top and bottom of the surface of the coolant pipe 222, respectively. The arc-shaped heat-conducting plate 233 is welded between the top and bottom opposite sides of the rotating rings 232. The inner side of the arc-shaped heat-conducting plate 233 contacts the surface of the coolant pipe 222, and the surface of the arc-shaped heat-conducting plate 233 contacts the inner side of the contact arc plate 152. The worm gear 231 is bolted to the top of the top rotating ring 232, and the surface of the worm gear 231 is close to the inner side of the movable groove 143. By setting the switching assembly 23, the worm gear 231 can interact with the rotating ring 232 and the arc-shaped heat-conducting plate 233. The heat-conducting plate 233 forms a switching structure for heat dissipation capacity. The worm gear 231 rotates with the worm 242, which drives the rotating ring 232 to adjust the position of the arc-shaped heat-conducting plate 233 within the contact arc plate 152. By rotating the arc-shaped heat-conducting plate 233, the contact area between it and the contact arc plate 152 can be changed. Thus, by changing the contact area or directly removing it from contact with the contact arc plate 152, the efficiency of the arc-shaped heat-conducting plate 233 in dissipating heat from the coolant in the coolant pipe 222 through the contact arc plate 152 can be adjusted. This allows the heat dissipation efficiency to be adjusted to suit the temperature required inside the container in the current scenario.

[0044] Please see Figure 8The adjustment assembly 24 includes a servo motor 241, a worm gear 242, and a fixing plate 243. The servo motor 241 is bolted to the rear side of the top between opposite sides of the housing partition 151. The worm gear 242 is bolted to the output end of the front side of the servo motor 241. The fixing plate 243 is bolted to the front side of the top between opposite sides of the housing partition 151. The front side of the worm gear 242 is rotatably connected to the rear side of the fixing plate 243. The surface of the worm gear 242 meshes with the surface of the worm wheel 231. By setting the adjustment assembly 24, the servo motor 241... The servo motor 241, together with the worm gear 242 and the fixed plate 243, forms a structure that provides transmission for the worm wheel 231. By driving the worm gear 242 to rotate along the fixed plate 243 through the servo motor 241, the worm gear 242 can contact the worm wheel 231 during rotation and gradually and continuously push the worm wheel 231 to rotate. Thus, the worm wheel 231 drives the rotating ring 232 to rotate the arc-shaped heat-conducting plate 233. Therefore, the contact mode between the arc-shaped heat-conducting plate 233 and the contact arc plate 152 can be changed, thereby changing the heat dissipation efficiency.

[0045] The working principle of this embodiment is as follows: First, connect the outlet 223 to the input end of the energy storage equipment coolant circulation system, and then connect the inlet 221 to the output end of the energy storage equipment coolant circulation system until it is ensured that the coolant of the energy storage equipment coolant circulation system can enter the coolant pipe 222 through the inlet 221 and then flow back into the energy storage equipment coolant circulation system from the outlet 223. When it is necessary to cool down the temperature environment inside the container, the servo motor 241 connected to the external remote control system is powered on again, and then the user remotely controls the servo motor 241 through the remote control system. The servo motor 241 is remotely controlled to rotate in both directions. First, the servo motor 241 rotates forward, causing the worm gear 242 to rotate as well. As the worm gear 242 rotates, it pushes the worm wheel 231, causing the worm wheel 231 to rotate along with the worm gear 242. The worm wheel 231 then drives the rotating ring 232 to rotate the arc-shaped heat-conducting plate 233 along the rotating groove 212 and the positioning block 211. The arc-shaped heat-conducting plate 233 then rotates axially around the coolant pipe 222, gradually bringing the surface of the coolant pipe 222 into contact with the contact arc plate 152. The contact area gradually increases, and the heat transfer efficiency increases accordingly. As the coolant flows through the coolant pipe 222, the coolant in the pipe 222 transfers its heat through the arc-shaped heat-conducting fins 233 and the contact arc plate 152, and finally dissipates it into the surrounding air from the heat-conducting fins 153, thereby cooling the temperature environment inside the container until the internal temperature reaches the required level. When it is necessary to maintain the temperature inside the container, the user remotely controls the servo motor 2... When 41 is reversed, the worm gear 242 will push the worm wheel 231 in the opposite direction, which will eventually drive the arc-shaped heat-conducting plate 233 to rotate in the opposite direction along the movable groove 213. The arc-shaped heat-conducting plate 233 will rotate in the opposite direction with the coolant pipe 222 as the axis, thereby gradually reducing the contact area between the arc-shaped heat-conducting plate 233 and the contact arc plate 152 until the contact arc plate 152 no longer contacts the arc-shaped heat-conducting plate 233. At this time, the coolant in the coolant pipe 222 will not conduct heat to the outside through the arc-shaped heat-conducting plate 233, and the temperature inside the container will be maintained.

[0046] This specific embodiment is merely an explanation of the present invention and is not intended to limit the invention. Those skilled in the art can make modifications to this embodiment without contributing any inventive step after reading this specification. Although embodiments of the present invention have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and variations can be made to these embodiments without departing from the principles and spirit of the present invention. The scope of the present invention is defined by the appended claims and their equivalents.

Claims

1. An adjustable energy storage container adaptable to multiple installation scenarios, comprising an installation mechanism (1) and an adaptation mechanism (2), characterized in that: The adaptation mechanism (2) is located on both sides of the installation mechanism (1). The installation mechanism (1) includes a housing assembly (11), a connecting assembly (12), an assembly assembly (13), a positioning assembly (14), and a temperature control assembly (15). The two connecting assemblies (12) are respectively located on the front and rear sides of the housing assembly (11). The assembly assembly (13) is located at the four corners of the connecting assembly (12). The two positioning assemblies (14) are respectively located on both sides of the housing assembly (11). The temperature control assembly (15) is located inside the positioning assembly (14). On the side, the adaptation mechanism (2) includes a limiting component (21), a liquid delivery component (22), a switching component (23), and an adjustment component (24). The two limiting components (21) are respectively located between opposite sides of the temperature control component (15). The liquid delivery component (22) is located inside the limiting component (21). The switching component (23) is located on the surface of the liquid delivery component (22). The adjustment component (24) is located between opposite sides of the positioning component (14). The surface of the adjustment component (24) engages with the switching component (23).

2. The adjustable energy storage container adaptable to multiple installation scenarios according to claim 1, characterized in that: The enclosure assembly (11) includes an enclosure plate (111), an enclosure connecting block (112), and an enclosure connecting hole (113). The enclosure connecting block (112) is welded to both sides of the enclosure plate (111), and the enclosure connecting hole (113) passes through the front and rear sides of the enclosure connecting block (112).

3. The adjustable energy storage container adaptable to multiple installation scenarios according to claim 2, characterized in that: The connecting assembly (12) includes a connecting square frame (121), a connecting sealing sleeve (122), and a connecting sealing plate (123). The two connecting square frames (121) are bolted to the front and rear sides of the housing plate (111), respectively. The connecting sealing sleeve (122) is bolted to the inner side of the connecting square frame (121). The connecting sealing plate (123) is bolted between the four opposite corners of the connecting square frame (121). The opposite sides of the connecting sealing plate (123) are bolted to both sides of the housing plate (111).

4. The adjustable energy storage container adaptable to multiple installation scenarios according to claim 3, characterized in that: The assembly component (13) includes an assembly plate (131), an assembly block (132), and an assembly rod (133). Eight assembly plates (131) are bolted to the four corners of the front side and the four corners of the rear side of the connecting frame (121). Four assembly blocks (132) are welded to the four corners of the front side and the four corners of the rear side of the assembly plate (131). Four assembly rods (133) are welded to the opposite side of the assembly block (132). The surface of the assembly rod (133) is engaged with the inner side of the box connection hole (113).

5. An adjustable energy storage container adaptable to multiple installation scenarios as described in claim 4, characterized in that: The positioning component (14) includes a positioning shell (141), a positioning groove (142), a movable groove (143), a positioning connecting block (144), and a positioning connecting hole (145). The positioning connecting block (144) has a positioning connecting hole (145) through its front and rear sides. The two positioning connecting blocks (144) are respectively snapped onto the surface of the top assembled square rod (133) through the positioning connecting hole (145). The two positioning shells (141) are respectively welded to the bottom of the two side positioning connecting blocks (144). The positioning groove (142) is opened on the top of the inner side of the positioning shell (141), and the movable groove (143) is opened on the bottom of the inner side of the positioning shell (141). The top of the movable groove (143) is connected to the positioning groove (142).

6. The adjustable energy storage container adaptable to multiple installation scenarios according to claim 5, characterized in that: The temperature control component (15) includes a box partition (151), a contact arc plate (152), a heat-conducting fin (153), a partition connecting block (154), and a partition connecting hole (155). The two box partitions (151) are respectively welded to the two sides of the bottom of the positioning shell (141). The contact arc plate (152) is welded to the two sides of the box partition (151). The heat-conducting fin (153) is welded to the outer surface of the contact arc plate (152). The partition connecting block (154) is welded to the bottom of the box partition (151). The partition connecting hole (155) passes through the front side of the partition connecting block (154). The partition connecting block (154) is snapped onto the surface of the bottom assembly square rod (133) through the partition connecting hole (155).

7. An adjustable energy storage container adaptable to multiple installation scenarios as described in claim 6, characterized in that: The limiting component (21) includes a positioning block (211), a rotating groove (212), and a movable groove (213). The positioning block (211) is engaged between the inner side of the box partition (151) and the opposite side of the contact arc plate (152). The rotating groove (212) is opened on the inner side of the contact arc plate (152), and the movable groove (213) is opened at the bottom of the inner side of the contact arc plate (152).

8. An adjustable energy storage container adaptable to multiple installation scenarios according to claim 7, characterized in that: The liquid delivery assembly (22) includes an inlet (221), a coolant pipe (222), and an outlet (223). The coolant pipe (222) is snapped into the inner side of the positioning block (211). The surface of the coolant pipe (222) is close to the inner side of the rotating groove (212). The inlet (221) is connected to the front side of the top of the coolant pipe (222), and the outlet (223) is connected to the front side of the bottom of the coolant pipe (222).

9. An adjustable energy storage container adaptable to multiple installation scenarios as described in claim 8, characterized in that: The switching assembly (23) includes a worm gear (231), a rotating ring (232), and an arc-shaped heat-conducting plate (233). The two rotating rings (232) are rotatably connected to the top and bottom of the surface of the coolant pipe (222), respectively. The arc-shaped heat-conducting plate (233) is welded between the top and bottom opposite sides of the rotating ring (232). The inner side of the arc-shaped heat-conducting plate (233) is in contact with the surface of the coolant pipe (222). The surface of the arc-shaped heat-conducting plate (233) is in contact with the inner side of the contact arc plate (152). The worm gear (231) is bolted to the top of the top rotating ring (232). The surface of the worm gear (231) is close to the inner side of the movable groove (143).

10. An adjustable energy storage container adaptable to multiple installation scenarios according to claim 9, characterized in that: The adjustment assembly (24) includes a servo motor (241), a worm gear (242), and a fixing plate (243). The servo motor (241) is bolted to the rear side of the top between opposite sides of the housing partition (151). The worm gear (242) is bolted to the output end of the front side of the servo motor (241). The fixing plate (243) is bolted to the front side of the top between opposite sides of the housing partition (151). The front side of the worm gear (242) is rotatably connected to the rear side of the fixing plate (243). The surface of the worm gear (242) meshes with the surface of the worm wheel (231).