A thermostat library

By combining an inner and outer double-layer load-bearing structure with an intermediate insulation layer, the design solves the problems of insufficient insulation capacity and high energy consumption in traditional constant temperature warehouses, achieving low energy consumption, high stability, and modular construction, making it suitable for various environments and extreme climates.

CN224349545UActive Publication Date: 2026-06-12LV HAO

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
LV HAO
Filing Date
2025-06-06
Publication Date
2026-06-12

AI Technical Summary

Technical Problem

Traditional constant temperature warehouses have insufficient insulation capacity, high energy consumption, and low modularity, making it difficult to achieve rapid construction and stable equipment installation.

Method used

The design adopts an inner and outer double-layer load-bearing structure combined with an intermediate insulation layer. The inner load-bearing structure independently supports heavy equipment, while the outer load-bearing structure securely installs facilities such as solar panels. The thickness of the intermediate insulation layer is adjustable to avoid thermal bridging effects, and energy consumption is reduced by using solar and wind power.

Benefits of technology

It significantly reduces energy consumption, improves the stability and safety of equipment installation, supports modular design, is suitable for various environments, adapts to extreme climates, reduces operating costs, and enhances environmental friendliness and construction efficiency.

✦ Generated by Eureka AI based on patent content.

Smart Images

  • Figure CN224349545U_ABST
    Figure CN224349545U_ABST
Patent Text Reader

Abstract

The application discloses a constant-temperature warehouse, which comprises a bearing box serving as a base of a storage chamber, the storage chamber being located on the bearing box and comprising an inner bearing structure, an outer bearing structure and a heat preservation layer, and a temperature adjusting device located outside the storage chamber and connected with the inside of the storage chamber through a pipeline to adjust the temperature in the storage chamber, wherein the outer bearing structure and the inner bearing structure are connected with the bearing box respectively, a gap is formed between the outer bearing structure and the inner bearing structure, and the heat preservation layer is located between the outer bearing structure and the inner bearing structure. The constant-temperature warehouse adopts the inner and outer double-layer bearing structures combined with the intermediate heat preservation layer, can effectively isolate the influence of external temperature, can expand the selection range of the thickness of the heat preservation layer through the decoupled double-layer bearing structure, improve the thickness of the heat preservation layer and enhance the heat preservation capacity. Meanwhile, the green energy supply is realized through the solar panel, the energy storage device and the optional wind power generation device, the operation cost is reduced, and the environmental protection performance is enhanced.
Need to check novelty before this filing date? Find Prior Art

Description

Technical Field

[0001] This utility model relates to the field of building technology, and more specifically, to a constant temperature warehouse. Background Technology

[0002] Temperature-controlled storage rooms are essential equipment widely used in the food, pharmaceutical, and chemical industries. Their core function is to maintain a constant internal temperature to meet the specific needs of storage or production processes. Temperature-controlled storage rooms need to maintain a stable temperature within a set range, minimizing temperature fluctuations to ensure the quality of stored goods.

[0003] For seasonal and perishable commodities such as fruits, vegetables, and flowers, there is a cyclical demand for temperature-controlled storage. Traditional temperature-controlled storage facilities are usually permanent buildings with low utilization rates and require daily maintenance. Furthermore, the long-term operation of traditional temperature-controlled storage facilities generates high energy costs, which is not conducive to energy conservation and environmental protection requirements.

[0004] Traditional cold storage facilities typically employ a single-layer frame design, with insulation material directly sprayed or installed on the outer or inner layer of the frame. This structure has significant drawbacks: if the insulation layer is on the outside, solar panels, decorative materials, drainage channels, and other equipment cannot be securely installed externally, as relying solely on adhesive fixation can easily lead to detachment accidents; if bolts are used to penetrate the insulation layer and connect it to the internal frame, the insulation performance is severely compromised, significantly increasing the cold storage's energy consumption. Similarly, if the insulation layer is on the inside, equipment cannot be installed internally, and securing the equipment still requires penetrating the insulation layer and connecting it to the frame, also resulting in thermal bridging and increased energy consumption.

[0005] Existing cold storage facilities lack modularity, and installation is limited by weather conditions, making rapid, all-weather construction difficult. Furthermore, the coupled design of the insulation layer and load-bearing frame in traditional structures restricts the thickness and performance optimization of the insulation layer, making it difficult to meet high energy efficiency requirements.

[0006] Therefore, developing a new type of constant temperature warehouse that is low in energy consumption and easy to disassemble has become a technical problem that urgently needs to be solved in the field of construction engineering. Utility Model Content

[0007] The purpose of this invention is to provide a constant temperature storage facility to improve the problems of insufficient insulation and high energy consumption of existing constant temperature storage facilities.

[0008] According to one aspect of this utility model, a constant temperature cold storage is provided, comprising: a load-bearing box as the base of a storage room; a storage room located on the load-bearing box, the storage room including an inner load-bearing structure, an outer load-bearing structure, and an insulation layer, thus reducing the curing time and cycle of foundation pouring for traditional fixed cold storage; a temperature regulating device located outside the storage room, the temperature regulating device being connected to the interior of the storage room through a pipeline to regulate the temperature inside the storage room; wherein, the outer load-bearing structure and the inner load-bearing structure are respectively connected to the load-bearing box, a gap exists between the outer load-bearing structure and the inner load-bearing structure, and the insulation layer is located between the outer load-bearing structure and the inner load-bearing structure.

[0009] Optionally, it also includes an energy storage device connected to the temperature regulating device for supplying power to the temperature regulating device.

[0010] Optionally, the energy storage device is installed inside the load-bearing box to enhance the stability of the load-bearing box. The load-bearing box replaces the foundation of the traditional fixed cold storage, which greatly reduces the construction time and cycle of the cold storage and also brings convenience to the later disassembly and assembly of the cold storage.

[0011] Optionally, the device may also include a solar panel connected to the energy storage device for charging the energy storage device using solar energy.

[0012] Optionally, the solar panel is disposed on the top or side of the storage room, and the solar panel is foldable.

[0013] Optionally, the energy storage device also includes an AC power supply interface for switching to grid power when solar energy is insufficient.

[0014] Optionally, it also includes a limiting damper, which is located between the inner bearing structure and the outer bearing structure. The limiting damper is L-shaped, and its bottom is fixed to the load-bearing box by bolts. The limiting damper is used to limit the movement of the inner bearing structure.

[0015] The aforementioned constant temperature storage chamber has a water storage cavity inside the load-bearing box for storing liquids to enhance stability or for emergency use.

[0016] Optionally, the insulation layer is made of furnace insulation material.

[0017] Optionally, the insulation layer located at the bottom of the storage room is made of high-density, high-thermal-resistance material, which ensures stability and high thermal resistance while supporting ground goods, thereby minimizing heat loss from the cold storage.

[0018] The constant-temperature storage facility provided in this embodiment of the invention employs an inner and outer double-layer load-bearing structure combined with an intermediate insulation layer. This effectively isolates the effects of external temperature while increasing the thickness of the intermediate insulation layer through the decoupled double-layer load-bearing structure, resolving the conflict between the insulation layer and equipment installation. The inner load-bearing structure can independently support heavy equipment, while the outer load-bearing structure securely mounts solar panels, decorative layers, and other facilities. An ultra-thick insulation layer can be filled between the two, and no penetrating connection is required between the inner and outer load-bearing structures, completely avoiding thermal bridging effects. Compared to traditional cold storage facilities, energy consumption is significantly reduced, while the stability and safety of the internal and external equipment installation are also significantly improved. Green energy power supply is achieved through solar panels, energy storage devices, and optional wind power generation devices, reducing operating costs and enhancing environmental friendliness.

[0019] This solution also features a modular design for the temperature-controlled warehouse. Its load-bearing box can integrate energy storage devices, power supply systems, and water storage. The modular design supports factory prefabrication and all-weather on-site assembly, significantly improving construction efficiency. The double-frame structure not only broadens the range of insulation layer thickness options but also gives the temperature-controlled warehouse stronger environmental adaptability, making it suitable for extreme climate regions and facilitating future equipment upgrades and maintenance. Furthermore, the intelligent temperature monitoring system provides real-time feedback on the internal environmental status, ensuring the efficient and safe operation of the temperature-controlled warehouse, suitable for various precision storage scenarios such as food and pharmaceuticals. This temperature-controlled warehouse has a simple structure and is easy to assemble and disassemble, making it suitable for various environments and meeting the needs of diverse geographical locations and scenarios. Attached Figure Description

[0020] The above and other objects, features and advantages of the present invention will become clearer from the following description of embodiments of the present invention with reference to the accompanying drawings.

[0021] Figure 1 A schematic diagram of a constant temperature chamber according to an embodiment of the present invention is shown. Detailed Implementation

[0022] The present invention will now be described in more detail with reference to the accompanying drawings. To facilitate understanding of this application, a more complete description will be provided below with reference to the accompanying drawings. Preferred embodiments of the present application are shown in the drawings. However, the present application may be implemented in different forms and is not limited to the embodiments described herein. Rather, these embodiments are provided to provide a thorough and complete understanding of the disclosure of this application.

[0023] References to "one embodiment" or "some embodiments" as described in this specification mean that one or more embodiments of this application include a specific feature, structure, or characteristic described in connection with that embodiment. Therefore, the phrases "in one embodiment," "in some embodiments," "in other embodiments," "in still other embodiments," etc., appearing in different parts of this specification do not necessarily refer to the same embodiment, but rather mean "one or more, but not all, embodiments," unless otherwise specifically emphasized. The terms "comprising," "including," "having," and variations thereof mean "including but not limited to," unless otherwise specifically emphasized.

[0024] In the description of this application, the words "exemplary" or "for example" are used to indicate that they are examples, illustrations, or descriptions. Any embodiment described as "exemplary" or "for example" in this application should not be construed as being more preferred or advantageous than other embodiments. "And / or" in this document describes an association relationship between related objects, indicating that three relationships can exist. For example, A and / or B can represent: A alone, A and B simultaneously, or B alone. "Connection" describes a connection relationship between related objects. For example, A and B are connected, which can indicate a direct connection between A and B, or an indirect connection between A and B through other devices / units / modules. "Multiple" refers to two or more. Furthermore, to facilitate a clear description of the technical solutions of the embodiments of this application, the terms "first," "second," etc., are used to distinguish identical or similar items with substantially the same function and effect. Those skilled in the art will understand that the terms "first," "second," etc., do not limit the quantity or execution order, and that "first," "second," etc., do not necessarily imply differences.

[0025] Furthermore, the same reference numerals in the figures denote the same or similar structures, thus repeated descriptions of them will be omitted. That is, the various parts in this specification are described using a combination of parallel and progressive methods, with each part focusing on its differences from the others. Similar or identical parts can be referred to interchangeably. Terms expressing position and direction described in this application are illustrative based on the accompanying drawings, but changes can be made as needed, and all such changes are included within the scope of protection of this application. The accompanying drawings in this application are for illustrating relative positional relationships only and do not represent actual scale.

[0026] This application describes many specific details of the present invention, such as the specific structure, dimensions, connection relationships, and techniques of the modules, in order to provide a clearer understanding of the present invention. However, as those skilled in the art will understand, the present invention may be implemented without following these specific details.

[0027] This utility model can be presented in various forms, some of which will be described below.

[0028] Figure 1 The diagram shows a constant temperature warehouse according to an embodiment of the present invention. The constant temperature warehouse includes: a load-bearing box 100, a storage room 200 located on the load-bearing box 100, and a temperature regulating device 300. The load-bearing box 100 serves as the base of the storage room 200, and its size matches that of the storage room 200. The load-bearing box 100 replaces the traditional foundation of the fixed storage room 200, which greatly reduces the construction time and cycle of the storage room 200 and also brings convenience to the later disassembly and assembly of the storage room 200. Storage chamber 200 includes an inner load-bearing structure 210, an outer load-bearing structure 220, and an insulation layer 230. The outer load-bearing structure 220 and the inner load-bearing structure 210 are connected to the load-bearing box 100, with a gap between them. The insulation layer 230 is located between the outer load-bearing structure 220 and the inner load-bearing structure 210. This design decouples the outer load-bearing structure 220 from the inner load-bearing structure 210 and avoids the problem of the insulation layer 230 being easily damaged and detached when located on the outermost side of the storage chamber. Furthermore, the insulation layer 230, located between the outer load-bearing structure 220 and the inner load-bearing structure 210, expands the range of thickness options for the insulation layer 230, allowing it to be thicker for better insulation. This decoupling design effectively reduces the transmission of vibrations and deformations from the outer load-bearing structure 220 to the inner load-bearing structure 210, ensuring the stability and safety of the inner load-bearing structure 210 and the interior of the storage chamber 200. The external load-bearing structure 220 can be used to support external decorations and other external structures such as water channels.

[0029] Of course, the constant temperature storage also includes a temperature regulating device 300, which is, for example, located on the outer surface of the outer support structure 220 outside the storage room 200. Specifically, the constant temperature storage is, for example, a cold storage, and the temperature regulating device 300 is, for example, a refrigeration unit. The temperature regulating device 300 is connected to a cold air channel 310 inside the storage room 200 via pipes, and the cold air channel 310 is, for example, located in the top area of ​​the storage room 200. Furthermore, the constant temperature storage also includes an energy storage device 400 for supplying energy to the temperature regulating device 300. The energy storage device 400 can, for example, be connected to a solar panel 500, which supplies power to the energy storage device 400. Of course, the energy storage device 400 may also include a power outlet, so that conventional mains power can be used when solar energy is insufficient. Figure 1The image only shows the solar panel 500 installed on the top of the storage room 200. Of course, the solar panel 500 can also be installed on the side of the storage room 200. The solar panel 500 can also be designed to be flexible for easy installation and can be unfolded and retracted as needed. Furthermore, since the energy storage device 400 is typically heavy, it can also be installed inside the load-bearing box 100 to enhance its stability. This not only integrates the energy storage device 400 into the load-bearing box 100, but also integrates the power supply and control system of the entire temperature-controlled warehouse within the load-bearing box 100, significantly enhancing the integration, construction, and ease of power use of the temperature-controlled warehouse. Of course, a wind power generation device can also be installed on the top of the storage room 200; different green energy power generation devices can be selected depending on the application scenario.

[0030] When external winds or impacts occur, the external load and impact are borne by the outer load-bearing structure 220, reducing swaying within the storage compartment 200 and ensuring internal stability and the safety of personnel and property. Naturally, the insulation layer 230 at the bottom of the inner load-bearing structure 210 is made of, for example, a high-density, high-thermal-resistance material, ensuring stability and high thermal resistance while supporting goods on the ground, minimizing heat loss from the cold storage. Specifically, the insulation layer 230 may use, for example, a furnace-enclosed thermal insulation material to achieve better insulation performance.

[0031] Furthermore, a limiting damper is provided between the inner bearing structure 210 and the outer bearing structure 220. The limiting damper is, for example, L-shaped, with its horizontal bottom edge fixed to the load-bearing box 100 by bolts. One of its vertical sides is connected to the outer bearing structure 220, and the other side is provided with an elastic damping rod. The elastic damping rod points towards the inner bearing structure 210 to limit the inner bearing structure 210 and the outer bearing structure 220, thereby decoupling the inner bearing structure 210 and the outer bearing structure 220 and preventing the inner bearing structure 210 and the outer bearing structure 220 from contacting or colliding.

[0032] Furthermore, the load-bearing tank 100 can also hold liquid. Under normal circumstances, the liquid in the load-bearing tank 100 can significantly enhance its stability. Of course, the liquid in the load-bearing tank 100 can also be extracted for fire fighting or plant irrigation in the storage chamber 200 above it. The liquid, for example, is water. Water has a high specific heat capacity, which can further reduce temperature fluctuations in the storage chamber 200 and enhance its insulation effect. In the event of disasters such as floods, the constant temperature storage facility can quickly drain the liquid from the load-bearing tank 100, allowing the load-bearing tank 100 and the storage chamber 200 above it to float on the water's surface, preventing the storage chamber 200 from being destroyed by the flood. The storage chamber 200 is also equipped with temperature sensors to monitor the operation of the constant temperature storage facility and issue timely warnings based on abnormalities.

[0033] The constant-temperature storage facility provided in this embodiment of the invention employs an inner and outer double-layer load-bearing structure combined with an intermediate insulation layer. This effectively isolates the effects of external temperature while increasing the thickness of the intermediate insulation layer through the decoupled double-layer load-bearing structure, resolving the conflict between the insulation layer and equipment installation. The inner load-bearing structure can independently support heavy equipment, while the outer load-bearing structure securely mounts solar panels, decorative layers, and other facilities. An ultra-thick insulation layer can be filled between the two, and no penetrating connection is required between the inner and outer load-bearing structures, completely avoiding thermal bridging effects. Compared to traditional cold storage facilities, energy consumption is significantly reduced, while the stability and safety of the internal and external equipment installation are also significantly improved. Green energy power supply is achieved through solar panels, energy storage devices, and optional wind power generation devices, reducing operating costs and enhancing environmental friendliness.

[0034] This solution also features a modular design for the temperature-controlled warehouse. Its load-bearing box can integrate energy storage devices, power supply systems, and water storage. The modular design supports factory prefabrication and all-weather on-site assembly, significantly improving construction efficiency. The double-frame structure not only broadens the range of insulation layer thickness options but also gives the temperature-controlled warehouse stronger environmental adaptability, making it suitable for extreme climate regions and facilitating future equipment upgrades and maintenance. Furthermore, the intelligent temperature monitoring system provides real-time feedback on the internal environmental status, ensuring the efficient and safe operation of the temperature-controlled warehouse, suitable for various precision storage scenarios such as food and pharmaceuticals. This temperature-controlled warehouse has a simple structure and is easy to assemble and disassemble, making it suitable for various environments and meeting the needs of diverse geographical locations and scenarios.

[0035] The embodiments of this utility model described above are examples of specific examples. These embodiments do not exhaustively describe all details, nor do they limit the utility model to only specific embodiments. Obviously, many modifications and variations can be made based on the above description. This specification selects and specifically describes these embodiments to better explain the principles and practical applications of this utility model, thereby enabling those skilled in the art to make good use of this utility model and its modifications.

Claims

1. A constant temperature storage room, characterized in that, include: The load-bearing box serves as the base for the storage room; The storage room is located on the load-bearing box. The storage room includes an inner load-bearing structure, an outer load-bearing structure, and an insulation layer, which reduces the curing time and cycle of foundation pouring for traditional fixed cold storage. A temperature regulating device is located outside the storage room and is connected to the interior of the storage room through a pipeline to regulate the temperature inside the storage room; The outer load-bearing structure and the inner load-bearing structure are respectively connected to the load-bearing box, and there is a gap between the outer load-bearing structure and the inner load-bearing structure. The insulation layer is located between the outer load-bearing structure and the inner load-bearing structure.

2. The constant temperature warehouse according to claim 1, characterized in that, It also includes an energy storage device, which is connected to the temperature regulation device and is used to supply power to the temperature regulation device.

3. The constant temperature warehouse according to claim 2, characterized in that, The energy storage device is installed inside the load-bearing box to enhance its stability.

4. The constant temperature warehouse according to claim 2, characterized in that, It also includes a solar panel, which is connected to the energy storage device and is used to charge the energy storage device using solar energy.

5. The constant temperature warehouse according to claim 4, characterized in that, The solar panel is installed on the top or side of the storage room, and the solar panel is foldable.

6. The constant temperature warehouse according to claim 4, characterized in that, The energy storage device also includes an AC power supply interface for switching to grid power when solar energy is insufficient.

7. The constant temperature warehouse according to claim 1, characterized in that, It also includes a limiting damper, which is located between the inner bearing structure and the outer bearing structure. The limiting damper is L-shaped, and its bottom is fixed to the load-bearing box by bolts. The limiting damper is used to limit the movement of the inner bearing structure.

8. The constant temperature warehouse according to claim 1, characterized in that, The insulation layer uses furnace insulation material.

9. The constant temperature warehouse according to claim 1, characterized in that, The insulation layer located at the bottom of the storage room is made of high-density, high-thermal-resistance material, which ensures stability and high thermal resistance while supporting goods on the ground, minimizing heat loss from the cold storage.