Elastic sheet type heat sink
By improving the radiator structure and material combination, the problems of insufficient protection and heat conduction were solved, resulting in better heat dissipation and protection performance.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- SHEN YANG YA TE DIAN QI ZHI ZAO YOU XIAN GONG SI
- Filing Date
- 2025-07-03
- Publication Date
- 2026-07-10
AI Technical Summary
Existing heat sinks have poor protection and heat conduction capabilities, resulting in ineffective protection and rapid heat conduction, thus affecting heat dissipation performance.
It adopts a combination of structures such as a supporting base plate, rubber buffer pad, fixing screw holes, fixing ring, connecting end, and adjustment interface, combined with materials such as graphene layer, metal fiber layer, carbon fiber layer, and polyamide fiber layer to improve protection and heat conduction capabilities.
It achieves effective protection and rapid heat conduction during use of flexible plate radiators, improves heat dissipation, and enhances fixation and corrosion resistance.
Smart Images

Figure CN224480082U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of radiator technology, specifically to a flexible plate radiator. Background Technology
[0002] Radiators are an important and basic component of hot water (or steam) heating systems. Hot water is cooled inside the radiator (or steam is condensed inside the radiator) to supply heat to the room, thus achieving the purpose of heating. The metal consumption and cost of radiators account for a considerable proportion of the heating system. Therefore, the correct selection of radiators is related to the economic indicators and operating performance of the system.
[0003] The prior art patent document CN209089326U discloses a radiator. Two circulating moving devices are installed, located at the middle of the left and right sides of a fixed frame. Each circulating moving device also includes a power component, which is synchronously connected to an active component. A limiting groove is S-shaped and surrounds the active component. The driven component is connected to a support frame via a rotating shaft. The radiator includes a fixed frame, an adjusting device, a circulating moving device, and at least two rows of heat sinks. The adjusting device is located at the four corners of the fixed frame, and the circulating moving device is located on one side of the fixed frame and connected to a row of heat sinks. The circulating moving device circulates the position of the heat sinks, enhancing their mobility and creating airflow to accelerate heat dissipation. The adjusting device includes a moving plate, a bevel gear, and a limiting component. The moving plate has a first gear structure that matches the bevel gear. One end of the limiting component is movably connected to the housing of the adjusting device, and the other end is located within the gear space of the bevel gear. A torsion spring is installed between the bevel gear and the housing. The rotation of the gear drives the moving plate to move, thus adapting it to different locations, improving its efficiency, and expanding its application range. The circulating moving device includes a driving component, a driven component, a support frame, and a movable plate. The driving component has a limiting groove, and the driven component is connected to the driving component through a limiting post, with the limiting post located within the limiting groove. Both the driving and driven components are movably connected to the support frame, and the driven component has a half-gear structure. The movable plate has a second gear structure that meshes with the half-gear structure. The movable plate is fixedly connected to the heat sink. The circulating moving device effectively moves the position of the heat sink, ensuring its mobility and creating effective airflow turbulence, thus expanding the heat dissipation effect. The width of the heat sink can be adjusted by an adjustment device, making it suitable for heat dissipation in different locations, expanding its application range, and reducing manufacturing costs. At the same time, the continuous movement of the heat sink position by the circulating moving device enhances its airflow turbulence, improving the heat dissipation effect and efficiency.
[0004] However, in the existing technology CN209089326U patent, the heat sink's protection and heat conduction capabilities are poor, which makes it impossible to effectively protect the elastic plate heat sink as needed during actual use. This makes it difficult to quickly conduct the heat absorbed by the heat sink, thus affecting the heat dissipation effect of the heat sink. Utility Model Content
[0005] (a) Technical problems to be solved
[0006] The purpose of this invention is to provide a flexible plate heat sink to solve the problems of poor protection and heat conduction of heat sinks mentioned in the background art.
[0007] (II) Technical Solution
[0008] To achieve the above objectives, this utility model provides the following technical solution: an elastic plate radiator, comprising a heat dissipation box, a supporting base plate fixedly disposed at the lower end of the heat dissipation box, a rubber buffer pad fixedly disposed at the lower end of the supporting base plate, a fixing screw hole fixedly disposed at the upper end of the supporting base plate, a heat dissipation elastic plate fixedly disposed at the upper end of the heat dissipation box, a fixing ring fixedly disposed at one end of the heat dissipation box, a connecting end fixedly disposed at one end of the fixing ring, and an adjustment interface fixedly disposed at one end of the heat dissipation box.
[0009] The adjustment interface is fixedly equipped with a connection button on its upper side, and the heat sink is fixedly equipped with a connection layer at its lower end. Through the improvement of the plate heat sink, the protection and heat conduction capabilities of the plate heat sink are improved. In the actual use of the plate heat sink, the elastic plate heat sink can be effectively protected as needed, which facilitates the rapid conduction of the heat absorbed by the heat sink and improves the heat dissipation effect of the elastic plate heat sink.
[0010] The lower end of the connecting layer is fixedly provided with a waterproof coating, the lower end of the waterproof coating is fixedly provided with a metal fiber layer, and the lower end of the metal fiber layer is fixedly provided with a graphene layer. The use of the supporting base plate and rubber buffer pad facilitates the installation of the heat sink. The use of fixing screw holes improves the fixing effect of the elastic plate heat sink. The use of fixing rings and connecting ends facilitates the connection and fixing of the elastic plate heat sink.
[0011] The graphene layer is fixedly provided with a carbon fiber layer at its lower end, the carbon fiber layer is fixedly provided with a polyamide fiber layer at its lower end, and the heat dissipation elastic sheet is fixedly provided with a heat-conducting plate at its lower end. The use of the adjustment interface and connection button facilitates the adjustment and use of the elastic sheet heat sink.
[0012] The heat-conducting plate is fixedly provided with a connecting pipe at its lower end, and a heat-absorbing plate is fixedly provided at its lower end. The use of a connecting layer, a waterproof coating, a metal fiber layer, and a graphene layer improves the corrosion resistance of the elastic sheet heat sink. The use of a carbon fiber layer and a polyamide fiber layer improves the protection of the elastic sheet heat sink. Finally, the temperature sensing end and the connecting wire are used for sensing.
[0013] The heat-absorbing plate has a temperature sensing end fixedly installed at its lower end, and a connecting wire is fixedly installed at one end of the temperature sensing end. By using the heat-absorbing plate, heat is absorbed and then conducted through the heat-conducting plate and connecting pipe, which improves the heat dissipation effect of the elastic plate heat sink.
[0014] Compared with the prior art, the beneficial effects of this utility model are:
[0015] 1. This flexible finned radiator, through improvements to the finned radiator, enhances its protection and heat conduction capabilities. In actual use, the flexible finned radiator can be effectively protected as needed, facilitating the rapid conduction of heat absorbed by the radiator and improving its heat dissipation effect.
[0016] 2. This flexible plate radiator facilitates the installation of the radiator box through the use of a supporting base plate and rubber buffer pads. The use of fixing screw holes improves the fixing effect of the flexible plate radiator. The use of fixing rings and connecting ends facilitates the connection and fixing of the flexible plate radiator. The use of adjustment interface and connection button facilitates the adjustment and use of the flexible plate radiator.
[0017] 3. This flexible sheet heat sink improves its corrosion resistance through the use of connecting layers, waterproof coatings, metal fiber layers, and graphene layers. It further enhances its protective effect through the use of carbon fiber layers and polyamide fiber layers. Finally, it improves its heat dissipation effect through the sensing of temperature sensing terminals and connecting wires, the absorption of heat by heat-absorbing plates, and the conduction of heat through heat-conducting plates and connecting pipes.
[0018] The parts of this device not covered herein are the same as or can be implemented using existing technologies. This utility model has a simple structure and is easy to operate. Attached Figure Description
[0019] Figure 1 This is a three-dimensional structural diagram of the present invention;
[0020] Figure 2 This is a schematic cross-sectional view of the present invention.
[0021] Figure 3This is a schematic diagram of the heat-conducting plate structure of this utility model;
[0022] Figure 4 This is a schematic diagram of the temperature sensing end structure of this utility model.
[0023] In the diagram: 1. Heat sink; 2. Support base plate; 3. Rubber buffer pad; 4. Fixing screw hole; 5. Heat dissipation elastic sheet; 6. Fixing ring; 7. Connecting end; 8. Adjustment interface; 9. Connecting button; 10. Connecting layer; 11. Waterproof coating; 12. Metal fiber layer; 13. Graphene layer; 14. Carbon fiber layer; 15. Polyamide fiber layer; 16. Heat-conducting plate; 17. Connecting pipe; 18. Heat-absorbing plate; 19. Temperature sensing end; 20. Connecting wire. Detailed Implementation
[0024] The technical solutions of the present utility model will be clearly and completely described below with reference to the accompanying drawings of the embodiments. Obviously, the described embodiments are only some embodiments of the present utility model, and not all embodiments. Based on the embodiments of the present utility model, all other embodiments obtained by those of ordinary skill in the art without creative effort are within the protection scope of the present utility model.
[0025] Please see Figures 1-4 This utility model provides a technical solution: an elastic plate heat sink, including a heat sink box 1, a supporting base plate 2 fixedly installed at the lower end of the heat sink box 1, a rubber buffer pad 3 fixedly installed at the lower end of the supporting base plate 2, a fixing screw hole 4 fixedly installed at the upper end of the supporting base plate 2, a heat dissipation elastic plate 5 fixedly installed at the upper end of the heat sink box 1, a fixing ring 6 fixedly installed at one end of the heat sink box 1, a connecting end 7 fixedly installed at one end of the fixing ring 6, and an adjustment interface 8 fixedly installed at one end of the heat sink box 1.
[0026] A connection button 9 is fixedly installed on the upper side of the adjustment interface 8. A connection layer 10 is fixedly installed at the lower end of the heat sink 1. A waterproof coating 11 is fixedly installed at the lower end of the connection layer 10. A metal fiber layer 12 is fixedly installed at the lower end of the waterproof coating 11. A graphene layer 13 is fixedly installed at the lower end of the metal fiber layer 12. The use of the support base plate 2 and the rubber buffer pad 3 facilitates the installation of the heat sink 1. The use of the fixing screw hole 4 improves the fixing effect of the elastic plate heat sink. The use of the fixing ring 6 and the connection end 7 facilitates the connection and fixing of the elastic plate heat sink. The use of the adjustment interface 8 and the connection button 9 facilitates the adjustment and use of the elastic plate heat sink.
[0027] A carbon fiber layer 14 is fixedly disposed at the lower end of the graphene layer 13, and a polyamide fiber layer 15 is fixedly disposed at the lower end of the carbon fiber layer 14. A heat-conducting plate 16 is fixedly disposed at the lower end of the heat-dissipating elastic sheet 5, a connecting pipe 17 is fixedly disposed at the lower end of the heat-conducting plate 16, a heat-absorbing plate 18 is fixedly disposed at the lower end of the connecting pipe 17, a temperature sensing end 19 is fixedly disposed at the lower end of the heat-absorbing plate 18, and a connecting wire 20 is fixedly disposed at one end of the temperature sensing end 19. The use of the connecting layer 10, the waterproof coating 11, the metal fiber layer 12, and the graphene layer 13 improves the corrosion resistance of the elastic sheet heat sink. The use of the carbon fiber layer 14 and the polyamide fiber layer 15 improves the protection effect of the elastic sheet heat sink. The heat is absorbed by the temperature sensing end 19 and the connecting wire 20, and then conducted through the heat-absorbing plate 18. The heat is then conducted through the heat-conducting plate 16 and the connecting pipe 17, thus improving the heat dissipation effect of the elastic sheet heat sink.
[0028] Working principle: First, the use of the supporting base plate 2 and rubber buffer pad 3 facilitates the installation of the heat sink 1. Then, the use of fixing screw holes 4 improves the fixing effect of the elastic plate heat sink. Then, the use of fixing ring 6 and connecting end 7 facilitates the connection and fixing of the elastic plate heat sink. Then, the use of adjustment interface 8 and connecting button 9 facilitates the adjustment and use of the elastic plate heat sink. Then, the use of connecting layer 10, waterproof coating 11, metal fiber layer 12, and graphene layer 13 improves the corrosion resistance of the elastic plate heat sink. Then, the use of carbon fiber layer 14 and polyamide fiber layer 15 improves the protection effect of the elastic plate heat sink. Then, the temperature sensing end 19 and connecting wire 20 sense the heat, and the use of heat absorption plate 18 absorbs the heat. Then, the heat conduction plate 16 and connecting pipe 17 conduct heat, improving the heat dissipation effect of the elastic plate heat sink.
[0029] Finally, it should be noted that the above content is only used to illustrate the technical solution of this utility model, and is not intended to limit the scope of protection of this utility model. Simple modifications or equivalent substitutions made by those skilled in the art to the technical solution of this utility model do not depart from the essence and scope of the technical solution of this utility model.
Claims
1. A flexible plate-type radiator, comprising a heat dissipation box (1), characterized in that: The lower end of the heat sink (1) is fixedly provided with a support base plate (2), the lower end of the support base plate (2) is fixedly provided with a rubber buffer pad (3), the upper end of the support base plate (2) is fixedly provided with a fixing screw hole (4), the upper end of the heat sink (1) is fixedly provided with a heat dissipation elastic sheet (5), one end of the heat sink (1) is fixedly provided with a fixing ring (6), one end of the fixing ring (6) is fixedly provided with a connecting end (7), and one end of the heat sink (1) is fixedly provided with an adjustment interface (8).
2. The flexible plate heat sink according to claim 1, characterized in that: A connection button (9) is fixedly provided on the upper side of the adjustment interface (8), and a connection layer (10) is fixedly provided on the lower end of the heat sink (1).
3. The flexible plate heat sink according to claim 2, characterized in that: A waterproof coating (11) is fixedly provided at the lower end of the connecting layer (10), a metal fiber layer (12) is fixedly provided at the lower end of the waterproof coating (11), and a graphene layer (13) is fixedly provided at the lower end of the metal fiber layer (12).
4. A flexible plate-type heat sink according to claim 3, characterized in that: A carbon fiber layer (14) is fixedly disposed at the lower end of the graphene layer (13), a polyamide fiber layer (15) is fixedly disposed at the lower end of the carbon fiber layer (14), and a heat-conducting plate (16) is fixedly disposed at the lower end of the heat dissipation elastic sheet (5).
5. A flexible plate-type heat sink according to claim 4, characterized in that: A connecting pipe (17) is fixedly installed at the lower end of the heat-conducting plate (16), and a heat-absorbing plate (18) is fixedly installed at the lower end of the connecting pipe (17).
6. A flexible plate-type heat sink according to claim 5, characterized in that: A temperature sensing end (19) is fixedly provided at the lower end of the heat absorption plate (18), and a connecting wire (20) is fixedly provided at one end of the temperature sensing end (19).