An aluminum-plastic radiator that can improve heat dissipation efficiency
By installing guide vanes on both sides of the aluminum-plastic heat exchange fins and heat conduction components on the front and back of the heat exchange fins, the problem of insufficient contact area between the heat exchange fins and the airflow in aluminum-plastic heat exchangers is solved, achieving a more efficient heat dissipation effect.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- ANHUI JIAHE AUTOMOBILE TECHNOLOGY CO LTD
- Filing Date
- 2025-08-05
- Publication Date
- 2026-06-30
AI Technical Summary
The limited contact area between the heat sink fins and the airflow in existing aluminum-plastic radiators results in poor heat dissipation.
Multiple airflow guides are installed on both sides of the aluminum-plastic flow sheet, and heat conduction components are installed on both the front and back of the heat sink to increase the contact area with the airflow. At the same time, the heat is diffused through the heat conduction components, and the airflow is increased in conjunction with the heat dissipation components to assist in heat dissipation.
By increasing the contact area between the heat sink and the airflow and by designing the heat-conducting components, the heat dissipation efficiency of aluminum-plastic radiators has been significantly improved.
Smart Images

Figure CN224439501U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of aluminum-plastic radiator technology, and in particular to an aluminum-plastic radiator that can improve heat dissipation efficiency. Background Technology
[0002] Aluminum-plastic radiators are a new type of composite radiator that uses high-polymer environmentally friendly materials as water pipes and aluminum alloy profiles as the surface heat dissipation material. Its core structure is usually made of copper pipes and aluminum profiles through precision processes. It has the characteristics of corrosion resistance and high temperature resistance, and is suitable for home, office and other scenarios.
[0003] Aluminum-plastic radiators are typically made of aluminum and consist of three parts: an inlet chamber, an outlet chamber, and a radiator core. The coolant flows inside the radiator core and conducts heat to the air through the aluminum fins, achieving heat exchange. The aluminum heat dissipation unit transfers heat to the plastic pipes or end caps through thermal conduction, and then dissipates heat through the flow of external air.
[0004] Existing aluminum-plastic radiators have limited heat exchange area, resulting in limited contact area between the heat sink and the airflow, which affects the heat dissipation effect of the aluminum-plastic radiators.
[0005] Therefore, it is necessary to provide an aluminum-plastic radiator that can improve heat dissipation efficiency to solve the above-mentioned technical problems. Utility Model Content
[0006] This invention provides an aluminum-plastic radiator that can improve heat dissipation efficiency, solving the problem that the limited contact area between the heat sink and the air in traditional aluminum-plastic radiators reduces their heat dissipation effect.
[0007] To solve the above-mentioned technical problems, the aluminum-plastic radiator provided by this utility model, which can improve heat dissipation efficiency, includes: a mounting frame;
[0008] Two mounting slots are respectively opened at the bottom and top of the inner wall of the mounting frame. Multiple heat sinks are installed inside the mounting frame. Multiple connecting pipes are installed at the top and bottom of the multiple heat sinks. The heat sinks include aluminum-plastic flow plates and guide plates. The guide plates are located on both sides of the aluminum-plastic flow plates. Heat conduction components are installed on the front and back of the heat sinks.
[0009] A water inlet pipe is fixedly connected to the top of the mounting frame near one side, and a drain pipe is installed at the top of the mounting frame near the other side. Both the water inlet pipe and the drain pipe have flanges installed at their tops, and both the water inlet pipe and the drain pipe have connecting pipes fixedly connected to their bottom ends.
[0010] One side of the mounting frame is detachable. The connecting pipe is used to connect multiple heat sinks to facilitate liquid flow. The connecting pipe is a square tube that can be inserted into the mounting groove. The aluminum-plastic flow plate and the guide plate are connected to each other to facilitate liquid diversion and increase the contact area with air. The heat-conducting component is made of the same material as the aluminum-plastic flow plate, but the connection between the heat-conducting component and the heat sink is not connected. The heat-conducting component is mainly used to increase the heat conduction area and improve the heat dissipation effect. The flange is used to connect to the pipe to facilitate liquid entry and exit. The two connecting pipes are respectively connected to the top of the heat sinks located on both sides inside the mounting frame.
[0011] Preferably, a monitoring component is mounted on the top of the mounting frame, the monitoring component comprising a fixed base and monitoring parts.
[0012] Preferably, a mounting component is mounted on the back of the mounting frame, and a heat dissipation component is mounted on the back of the mounting component.
[0013] Activating the heat dissipation components can increase airflow and assist in heat dissipation.
[0014] Preferably, the mounting assembly includes a docking structure, a limiting structure, and a fixing bracket. The fixing bracket is used to fix the limiting structure to the back of the mounting frame, and the docking structure is inserted from one side of the limiting structure to fix the heat dissipation assembly.
[0015] The limiting structure and the docking structure are reinforced with bolts after being snapped together. The limiting structure is T-shaped.
[0016] Preferably, the heat dissipation assembly includes a heat dissipation frame and a heat dissipation component, wherein the heat dissipation frame is used to install the heat dissipation component inside.
[0017] Preferably, the heat-conducting component includes horizontal heat-conducting plates and vertical heat-conducting plates, which are arranged in a cross shape.
[0018] Compared with related technologies, the aluminum-plastic radiator with improved heat dissipation efficiency provided by this utility model has the following beneficial effects:
[0019] This invention provides an aluminum-plastic radiator with improved heat dissipation efficiency. To enhance the heat dissipation efficiency, multiple guide vanes are installed on both sides of the aluminum-plastic flow plate to ensure communication between the guide vanes and the flow plate, facilitating liquid flow. Simultaneously, heat-conducting components are installed on both the front and back of the radiator to increase the contact area with airflow, further improving heat dissipation efficiency. In actual use, liquid enters the radiator through the inlet pipe, flows between the multiple radiators through the connecting pipe, and finally exits through the drain pipe. During this process, the heat-conducting components diffuse heat, and the airflow, combined with the guide vanes, increases the heat dissipation contact area, allowing the liquid to dissipate heat more quickly. This design increases the heat dissipation area, effectively improving the heat dissipation efficiency of the aluminum-plastic radiator. Attached Figure Description
[0020] Figure 1 A schematic diagram of a preferred embodiment of the aluminum-plastic radiator that improves heat dissipation efficiency provided by this utility model;
[0021] Figure 2 A structural schematic diagram of the monitoring component is provided for this utility model;
[0022] Figure 3 A schematic diagram of the heat sink structure is provided for this utility model;
[0023] Figure 4 Provided for this utility model Figure 3 An enlarged view of point A shown;
[0024] Figure 5 Provided for this utility model Figure 3 A magnified view of point B shown.
[0025] The following are the labeling elements in the diagram: 1. Mounting frame; 2. Heat dissipation assembly; 201. Heat dissipation frame; 202. Heat dissipation component; 3. Water inlet pipe; 4. Flange; 5. Monitoring assembly; 501. Fixed base; 502. Monitoring component; 6. Drain pipe; 7. Heat conduction assembly; 701. Horizontal heat conduction plate; 702. Vertical heat conduction plate; 8. Heat sink; 801. Aluminum-plastic flow plate; 802. Flow guide plate; 9. Mounting assembly; 901. Butt joint structure; 902. Limiting structure; 903. Fixing bracket; 10. Mounting groove; 11. Connecting pipe; 12. Connecting pipe. Detailed Implementation
[0026] The present invention will be further described below with reference to the accompanying drawings and embodiments.
[0027] Please refer to the following: Figure 1 , Figure 2 , Figure 3 , Figure 4 and Figure 5 ,in, Figure 1A schematic diagram of a preferred embodiment of the aluminum-plastic radiator that improves heat dissipation efficiency provided by this utility model; Figure 2 A structural schematic diagram of the monitoring component is provided for this utility model; Figure 3 A schematic diagram of the heat sink structure is provided for this utility model; Figure 4 Provided for this utility model Figure 3 An enlarged view of point A shown; Figure 5 Provided for this utility model Figure 3 The enlarged view at point B is shown. The aluminum-plastic heat sink, which improves heat dissipation efficiency, includes: mounting frame 1;
[0028] Two mounting slots 10 are respectively opened at the bottom and top of the inner wall of the mounting frame 1. Multiple heat sinks 8 are installed inside the mounting frame 1. Multiple connecting pipes 11 are installed at the top and bottom of the multiple heat sinks 8. The heat sink 8 includes an aluminum-plastic flow plate 801 and a guide plate 802. The guide plate 802 is located on both sides of the aluminum-plastic flow plate 801. Heat conduction components 7 are installed on both the front and back of the heat sink 8.
[0029] Water inlet pipe 3 is fixedly connected to the top of the mounting frame 1 near one side. A drain pipe 6 is installed at the top of the mounting frame 1 near the other side. A flange 4 is installed at the top of both the water inlet pipe 3 and the drain pipe 6. A connecting pipe 12 is fixedly connected to the bottom of both the water inlet pipe 3 and the drain pipe 6.
[0030] One side of the mounting frame 1 is detachable. The connecting pipe 11 is used to connect multiple heat sinks 8 to facilitate liquid flow. The connecting pipe 11 is a square pipe that can be inserted into the mounting groove 10. The aluminum-plastic flow plate 801 and the guide plate 802 are connected to each other to facilitate liquid diversion and increase the contact area with air. The heat-conducting component 7 is made of the same material as the aluminum-plastic flow plate 801, but the heat-conducting component 7 is not connected to the heat sink 8. The heat-conducting component 7 is mainly used to increase the heat-conducting area and improve the heat dissipation effect. The flange 4 is used to connect with the pipe to facilitate liquid entry and exit. The two connecting pipes 12 are respectively connected to the top of the heat sinks 8 located on both sides inside the mounting frame 1 to facilitate liquid entry and exit from the heat sinks 8.
[0031] A monitoring component 5 is mounted on the top of the mounting frame 1. The monitoring component 5 includes a fixed base 501 and a monitoring part 502.
[0032] The monitoring component 502 can monitor the temperature inside the mounting frame 1.
[0033] A mounting component 9 is mounted on the back of the mounting frame 1, and a heat dissipation component 2 is mounted on the back of the mounting component 9.
[0034] The activation of heat dissipation component 2 can increase airflow and assist in heat dissipation. The installation component 9 can enable quick assembly and disassembly of heat dissipation component 2.
[0035] The mounting assembly 9 includes a docking structure 901, a limiting structure 902, and a fixing bracket 903. The fixing bracket 903 is used to fix the limiting structure 902 to the back of the mounting frame 1. The docking structure 901 is inserted from one side of the limiting structure 902 to fix the heat dissipation assembly 2.
[0036] The limiting structure 902 and the docking structure 901 are snapped together and then reinforced with bolts. The limiting structure 902 is T-shaped.
[0037] The heat dissipation assembly 2 includes a heat dissipation frame 201 and a heat dissipation component 202, wherein the heat dissipation frame 201 is used to install the heat dissipation component 202 inside;
[0038] The heat dissipation component 202 is a cooling fan.
[0039] The heat-conducting component 7 includes a horizontal heat-conducting plate 701 and a vertical heat-conducting plate 702, which are arranged in a cross shape.
[0040] Both the horizontal heat-conducting plate 701 and the vertical heat-conducting plate 702 are made of heat-conducting materials.
[0041] The working principle of the aluminum-plastic radiator with improved heat dissipation efficiency provided by this utility model is as follows:
[0042] Multiple guide vanes 802 are installed on both sides of the aluminum-plastic flow plate 801 to ensure that the guide vanes 802 and the aluminum-plastic flow plate 801 are connected to facilitate liquid flow. At the same time, heat-conducting components 7 are installed on both the front and back of the heat sink 8 to increase the contact area with the air and improve the heat dissipation efficiency of the heat sink 8. In actual use, the liquid enters the interior of the heat sink 8 through the water inlet pipe 3, flows between the multiple heat sinks 8 through the connecting pipe 11, and finally exits from the drain pipe 6. During this process, the heat-conducting components 7 diffuse the heat, and when the air blows over the heat sink 8, it works with the guide vanes 802 to increase the heat dissipation contact area, allowing the liquid to dissipate heat more quickly.
[0043] Compared with related technologies, the aluminum-plastic radiator with improved heat dissipation efficiency provided by this utility model has the following beneficial effects:
[0044] To improve the heat dissipation efficiency of the aluminum-plastic radiator, multiple guide vanes 802 are installed on both sides of the aluminum-plastic flow plate 801 to ensure that the guide vanes 802 and the aluminum-plastic flow plate 801 are connected, facilitating liquid flow. At the same time, heat-conducting components 7 are installed on both the front and back of the heat sink 8 to increase the contact area with the air and improve the heat dissipation efficiency of the heat sink 8. In actual use, the liquid enters the interior of the heat sink 8 through the water inlet pipe 3, flows between the multiple heat sinks 8 through the connecting pipe 11, and finally exits from the drain pipe 6. During this process, the heat-conducting components 7 diffuse the heat, and the air blowing over the heat sink 8, in conjunction with the guide vanes 802, increases the heat dissipation contact area, allowing the liquid to dissipate heat more quickly. This design increases the heat dissipation area and effectively improves the heat dissipation efficiency of the aluminum-plastic radiator.
[0045] The above description is merely an embodiment of this utility model and does not limit the patent scope of this utility model. Any equivalent structural or procedural transformations made based on the content of this utility model specification and drawings, or direct or indirect applications in other related technical fields, are similarly included within the patent protection scope of this utility model.
Claims
1. An aluminum-plastic radiator that improves heat dissipation efficiency, characterized in that, include: Install borders; Two mounting slots are respectively opened at the bottom and top of the inner wall of the mounting frame. Multiple heat sinks are installed inside the mounting frame. Multiple connecting pipes are installed at the top and bottom of the multiple heat sinks. The heat sinks include aluminum-plastic flow plates and guide plates. The guide plates are located on both sides of the aluminum-plastic flow plates. Heat conduction components are installed on the front and back of the heat sinks. A water inlet pipe is fixedly connected to the top of the mounting frame near one side, and a drain pipe is installed at the top of the mounting frame near the other side. Both the water inlet pipe and the drain pipe have flanges installed at their tops, and both the water inlet pipe and the drain pipe have connecting pipes fixedly connected to their bottom ends.
2. The aluminum-plastic radiator with improved heat dissipation efficiency according to claim 1, characterized in that, A monitoring component is mounted on the top of the mounting frame, the monitoring component comprising a fixed base and monitoring parts.
3. The aluminum-plastic radiator with improved heat dissipation efficiency according to claim 1, characterized in that, A mounting component is mounted on the back of the mounting frame, and a heat dissipation component is mounted on the back of the mounting component.
4. The aluminum-plastic radiator with improved heat dissipation efficiency according to claim 3, characterized in that, The mounting assembly includes a docking structure, a limiting structure, and a fixing bracket. The fixing bracket is used to fix the limiting structure to the back of the mounting frame, and the docking structure is inserted from one side of the limiting structure to fix the heat dissipation assembly.
5. The aluminum-plastic radiator with improved heat dissipation efficiency according to claim 3, characterized in that, The heat dissipation assembly includes a heat dissipation frame and heat dissipation components, wherein the heat dissipation frame is used to install the heat dissipation components inside.
6. The aluminum-plastic radiator with improved heat dissipation efficiency according to claim 1, characterized in that, The heat-conducting component includes horizontal heat-conducting plates and vertical heat-conducting plates, which are arranged in a cross shape.