An enhanced heat sink structure

By introducing a layered structure of aluminum alloy, stainless steel and carbon fiber materials, as well as an arc-shaped reinforcing plate and fin design into the radiator, the problems of small heat dissipation area and structural instability of the radiator are solved, achieving efficient heat dissipation and structural enhancement.

CN224439460UActive Publication Date: 2026-06-30KUNSHAN COOLRIGHT ELECTRONIC TECH CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
KUNSHAN COOLRIGHT ELECTRONIC TECH CO LTD
Filing Date
2025-06-13
Publication Date
2026-06-30

AI Technical Summary

Technical Problem

Existing radiators lack a sufficient number or reasonable shape of heat dissipation fins, resulting in small heat dissipation area, poor airflow, easy deformation or damage, and insufficient stability in use.

Method used

An enhanced heat sink structure is designed, which adopts a layered structure consisting of an aluminum alloy main body, a stainless steel outer body, and carbon fiber reinforcing ribs, with an additional M-shaped continuously arranged arc-shaped reinforcing plate and arc-shaped heat dissipation fins to enhance structural strength and increase heat dissipation area.

Benefits of technology

It improves heat dissipation efficiency, enhances the structural stability and service life of the radiator, ensures that it is not easily deformed or damaged under external forces, and transfers heat to the air more quickly.

✦ Generated by Eureka AI based on patent content.

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Abstract

This utility model discloses an enhanced radiator structure, including a radiator body, a layered structure, reinforcing plates, and mounting bases. The radiator body is composed of a layered structure. Reinforcing plates are provided on both sides of the outer wall of the radiator body, and mounting bases are provided at both ends of the reinforcing plates. A fixing rod is provided through the side of each mounting base. Heat dissipation fins are provided on both sides of the surface of the radiator body. This enhanced radiator structure, with its several arc-shaped heat dissipation fins on both sides of the radiator body surface, significantly increases the contact area between the radiator and the surrounding air. According to the principle of heat dissipation, the larger the heat dissipation area, the more heat can be dissipated per unit time, thus enhancing the effectiveness of the radiator body. A radiator with external heat dissipation fins can transfer heat to the air faster than a radiator without heat dissipation fins, thereby effectively reducing the temperature of the heat source. The layered structure ensures the overall structural strength of the radiator.
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Description

Technical Field

[0001] This utility model relates to the field of radiator equipment technology, and specifically to an enhanced radiator structure. Background Technology

[0002] Heat sinks operate based on the principles of heat conduction and convection. They dissipate heat from the heat source by increasing surface area, extending heat conduction paths, and increasing the flow rate of the heat exchange medium, thereby lowering the heat source's temperature. For example, a computer CPU generates heat when it operates, and this heat is transferred to the heat sink, causing the heat sink to heat up. The higher the temperature of the heat sink, the greater the temperature difference between it and the surrounding air, and the higher the efficiency of heat transfer, making it easier to dissipate heat into the air. When the heat sink temperature reaches a certain level, the heat transfer efficiency becomes sufficient for the heat dissipated by the heat sink to equal the heat generated when the CPU is at maximum power consumption. At this point, the temperature stops rising, and a balance is reached between the CPU's heat generation and the heat sink's heat output.

[0003] Existing radiators do not have a sufficient number or reasonable shape of heat dissipation fins, resulting in a small heat dissipation area. Ordinary radiators may not have optimized the shape of the heat dissipation fins, which cannot effectively guide airflow, causing air to form dead corners around the radiator and affecting the heat dissipation effect. Existing radiators may lack effective reinforcement structures, making them prone to deformation or damage when subjected to external forces, and they are even less able to enhance the strength characteristics and stability of the radiator in use.

[0004] Therefore, it is necessary to invent an enhanced heat sink structure to solve the above problems. Utility Model Content

[0005] The purpose of this invention is to provide an enhanced radiator structure to solve the problem that the use of radiators in the present technology does not have an enhancing effect.

[0006] To achieve the above objectives, this utility model provides the following technical solution: an enhanced radiator structure, comprising a radiator body, a layered structure, reinforcing plates, mounting bases, fixing rods, and heat dissipation fins. The radiator body is composed of a layered structure. Reinforcing plates are provided on both sides of the outer wall of the radiator body. Mounting bases are provided at both ends of the reinforcing plates. Fixing rods are provided through the sides of the mounting bases. Heat dissipation fins are provided at both edges of the surface of the radiator body. Several heat dissipation fins are provided at the ends of the radiator body. The heat dissipation fins are arc-shaped, with the concave inner surface of the arc facing upwards.

[0007] Preferably, fixing holes are provided at both ends of the side wall of the radiator body, and the fixing rod is installed in accordance with the fixing holes.

[0008] Preferably, the fixing rod extends from one side of the outer wall of the mounting base into a fixing hole in the middle of one side of the outer wall of the radiator body, and the fixing rod and the fixing hole are threaded together.

[0009] Preferably, the two ends of the reinforcing plate are fixedly connected to the side wall of the mounting base, the reinforcing plates are arranged in an M-shape in a continuous manner, and the side ends of the reinforcing plates are arc-shaped.

[0010] Preferably, the sidewall of the mounting base is attached to the outer wall of the radiator body, and the height of the mounting base is greater than the thickness of the radiator body.

[0011] Preferably, the mounting base is L-shaped, and screws are installed on both sides of the surface of the mounting base. The mounting base is fixedly installed on the component to be installed by the screws.

[0012] Preferably, the layer structure includes a main layer, a surface layer, and reinforcing ribs. The main layer is the main shell layer of the radiator body shell. The surface layer is provided on both the surface and bottom of the main layer. Reinforcing ribs are provided between the main layer and the surface layer.

[0013] Preferably, the main layer is made of aluminum alloy, the outer layer is made of stainless steel, and the reinforcing ribs are made of carbon fiber.

[0014] The technical effects and advantages provided by this utility model in the above technical solution are as follows:

[0015] This enhanced radiator structure features continuously arranged M-shaped reinforcing plates with curved sides. This structure disperses external forces on the radiator, enhancing its overall strength. When the radiator is subjected to impact or pressure, the continuously arranged M-shaped reinforcing plates distribute the force to various parts, preventing excessive local stress that could lead to deformation or damage. Several curved heat dissipation fins on both sides of the radiator's surface significantly increase the contact area between the radiator and the surrounding air. According to the principle of heat dissipation, the larger the heat dissipation area, the more heat can be dissipated per unit time, thus enhancing the radiator's performance. Radiators with external heat dissipation fins can transfer heat to the air faster than those without, effectively reducing the heat source temperature. The layered structure ensures the overall structural strength of the radiator. Attached Figure Description

[0016] Figure 1 This is a schematic diagram of the overall structure of this utility model;

[0017] Figure 2 This is a side view of the structure of this utility model;

[0018] Figure 3 This is a side-view structural diagram of the present invention;

[0019] Figure 4 This is a schematic diagram of the layer structure of this utility model.

[0020] Explanation of reference numerals in the attached figures:

[0021] 1. Heat sink body; 2. Layer structure; 201. Main layer; 202. Surface layer; 203. Reinforcing rib; 3. Reinforcing plate; 4. Mounting base; 5. Fixing rod; 6. Heat dissipation fins; 7. Fixing hole. Detailed Implementation

[0022] To enable those skilled in the art to better understand the technical solution of this utility model, the present utility model will be further described in detail below with reference to the accompanying drawings.

[0023] This utility model provides, for example Figure 1-4 An enhanced radiator structure is shown, including a radiator body 1, a layer structure 2, reinforcing plates 3, and mounting bases 4. The radiator body 1 is composed of the layer structure 2, which includes a main layer 201, a surface layer 202, and reinforcing ribs 203. The main layer 201 is the main shell layer of the radiator body 1. The surface layer 202 is provided on both the surface and bottom of the main layer 201. Reinforcing ribs 203 are provided between the main layer 201 and the surface layer 202. The main layer 201 is made of aluminum alloy, the surface layer 202 is made of stainless steel, and the reinforcing ribs 203 are made of carbon fiber. Reinforcing plates 3 are provided on both sides of the outer wall of the radiator body 1. Mounting bases 4 are provided at both ends of the reinforcing plates 3. The two ends of the reinforcing plates 3 are fixedly connected to the side walls of the mounting bases 4. The reinforcing plates 3 are arranged in an M-shape in a continuous manner, and the side ends of the reinforcing plates 3 are arc-shaped.

[0024] The mounting base 4 is attached to the outer wall of the radiator body 1, and the height of the mounting base 4 is greater than the thickness of the radiator body 1. The mounting base 4 is L-shaped, and screws are installed on both sides of the surface of the mounting base 4. The mounting base 4 is fixed to the component to be installed by the screws. A fixing rod 5 is provided through the side of the mounting base 4. Heat dissipation fins 6 are provided at both edges of the surface of the radiator body 1. Several heat dissipation fins 6 are provided at the ends of the radiator body 1. The heat dissipation fins 6 are arc-shaped, and the concave surface of the arc of the heat dissipation fins 6 faces upward. Fixing holes 7 are provided at both ends of the side wall of the radiator body 1. The fixing rod 5 is installed corresponding to the fixing hole 7. The fixing rod 5 passes through one side of the outer wall of the mounting base 4 to the fixing hole 7 in the middle of one side of the outer wall of the radiator body 1. The fixing rod 5 and the fixing hole 7 are threaded together.

[0025] The working principle of this practical application is as follows:

[0026] Refer to the instruction manual appendix Figure 1-4For this type of enhanced radiator structure, during operation, the heat generated by the heat source is first conducted to the main layer 201 of the radiator body 1. Since the main layer 201 is made of aluminum alloy, it has a high thermal conductivity, enabling it to quickly transfer heat from the heat source to itself. Then, the heat is conducted through the main layer 201 to the surface layer 202 and the reinforcing ribs 203. The stainless steel surface layer 202 and the carbon fiber reinforcing ribs 203 also participate in the heat conduction process, jointly dispersing the heat and preventing localized overheating. The carbon fiber reinforcing ribs 203... During conduction, the fins assist in heat dissipation, ensuring a more even distribution of heat within the radiator and improving overall heat dissipation efficiency. Several arc-shaped heat dissipation fins 6 are arranged along the two edges of the radiator body 1, with their concave surfaces facing upwards. This increases the contact area between the radiator and the surrounding air. The presence of the heat dissipation fins 6 increases the heat exchange area, allowing heat to be transferred more effectively to the surrounding flowing air. When air flows between the heat dissipation fins 6, it carries away the heat from the fins, thus achieving convective heat transfer. The arc-shaped heat dissipation fins 6 may... To a certain extent, it guides the airflow, increases the degree of air turbulence, and enhances the convective heat transfer effect. The reinforcing plates 3 on both sides of the outer wall of the radiator body 1 are arranged in an M-shape in a continuous manner, with arc-shaped ends. This structure can enhance the strength of the radiator body 1, making it less prone to deformation when subjected to external forces. The two ends of the reinforcing plates 3 are fixedly connected to the side walls of the mounting base 4, further improving the stability of the entire radiator structure. The carbon fiber reinforcing ribs 203 set between the main layer 201 and the surface layer 202 have the advantages of high strength, light weight, corrosion resistance, and fatigue resistance. They can enhance the connection strength between the main layer 201 and the surface layer 202, preventing separation or deformation between the main layer 201 and the surface layer 202 due to thermal expansion and contraction or other factors during long-term use, thereby ensuring the overall structural strength and service life of the radiator. During use, the connection parts of the radiator should be checked regularly, such as whether the screws of the fixing rod 5 and the mounting base 4 are loose, to ensure the structural stability of the radiator. At the same time, check whether there is dust or debris accumulation on the heat dissipation fins 6, and clean them in time if necessary to ensure the heat dissipation effect.

Claims

1. An enhanced radiator structure, comprising a radiator body (1), a layered structure (2), a reinforcing plate (3), a mounting base (4), a fixing rod (5), and radiator fins (6), characterized in that, The radiator body (1) is composed of a layered structure (2). Reinforcing plates (3) are provided on both sides of the outer wall of the radiator body (1). Mounting seats (4) are provided at both ends of the reinforcing plates (3). Fixing rods (5) are provided through the side of the mounting seats (4). Heat dissipation fins (6) are provided at both edges of the surface of the radiator body (1). Several heat dissipation fins (6) are provided at the ends of the radiator body (1). The heat dissipation fins (6) are arc-shaped, and the concave surface of the arc-shaped heat dissipation fins (6) faces upward.

2. The enhanced radiator structure according to claim 1, characterized in that: Fixing holes (7) are provided at both ends of the heat sink body (1), and the fixing rod (5) is installed in the corresponding fixing holes (7).

3. The enhanced radiator structure according to claim 1, characterized in that: The fixing rod (5) extends from one side of the outer wall of the mounting base (4) into the fixing hole (7) in the middle of one side of the outer wall of the radiator body (1), and the fixing rod (5) and the fixing hole (7) are threaded together.

4. The enhanced radiator structure according to claim 1, characterized in that: The two ends of the reinforcing plate (3) are fixedly connected to the side wall of the mounting base (4). The reinforcing plates (3) are arranged in an m-shape in a continuous manner, and the side ends of the reinforcing plates (3) are arc-shaped.

5. The enhanced radiator structure according to claim 1, characterized in that: The side wall of the mounting base (4) is attached to the outer wall of the radiator body (1), and the height of the mounting base (4) is greater than the thickness of the radiator body (1).

6. The enhanced radiator structure according to claim 1, characterized in that: The mounting base (4) is L-shaped, and screws are installed on both sides of the surface of the mounting base (4). The mounting base (4) is fixedly installed on the component to be installed by the screws.

7. The enhanced radiator structure according to claim 1, characterized in that: The layer structure (2) includes a main layer (201), a surface layer (202), and reinforcing ribs (203). The main layer (201) is the main shell layer of the radiator body (1). The surface layer (202) is provided on both the surface and bottom of the main layer (201). Reinforcing ribs (203) are provided between the main layer (201) and the surface layer (202).

8. The enhanced radiator structure according to claim 7, characterized in that: The main layer (201) is made of aluminum alloy, the surface layer (202) is made of stainless steel, and the reinforcing rib (203) is made of carbon fiber.