A water cooling radiator
By introducing air-cooled auxiliary components and temperature sensors into the water-cooling radiator, combined with parallel heat dissipation fins and through-hole design, the problems of low heat exchange efficiency of coolant and inaccurate temperature monitoring are solved, achieving a highly efficient heat dissipation effect.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- DONGGUAN WENYANG PRECISION METAL PROD CO LTD
- Filing Date
- 2025-06-05
- Publication Date
- 2026-06-23
AI Technical Summary
Existing water-cooled radiators suffer from low heat exchange efficiency of the coolant, inaccurate temperature monitoring, and insufficient coordination between water cooling and air cooling methods, resulting in limited heat dissipation performance.
Design a water-cooled radiator that includes a water-cooled heat dissipation component and an air-cooled auxiliary component. It adopts a parallel heat dissipation fin and through-hole design to increase the heat exchange area, and uses a temperature sensor to monitor the water temperature in real time. Combined with forced airflow, it accelerates heat dissipation.
It significantly improves heat exchange efficiency and heat dissipation effect, realizes real-time temperature regulation and coordinated operation of air cooling and water cooling, and improves overall heat dissipation efficiency.
Smart Images

Figure CN224398428U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of water cooling radiator technology, specifically a heat dissipation water cooling radiator. Background Technology
[0002] In high-heat applications such as electronic equipment and industrial machinery, efficient heat dissipation systems are crucial for ensuring stable equipment operation and extending its lifespan. Traditional heat dissipation methods mainly include water cooling and air cooling. Air cooling relies primarily on forced convection by fans to remove heat, but its efficiency is greatly affected by factors such as ambient temperature and airflow velocity, making it difficult to meet heat dissipation requirements in high-heat scenarios. While water cooling can remove a significant amount of heat through coolant circulation, pure water cooling systems suffer from low coolant heat exchange efficiency and inaccurate water flow temperature monitoring, thus limiting their heat dissipation effect.
[0003] In existing water-cooled radiator structures, the heat exchange process of the coolant within the radiator is often insufficient. On the one hand, the contact area between the heat sink fins and the coolant pipes is limited, resulting in low heat transfer efficiency and difficulty in quickly dissipating the heat carried by the coolant. On the other hand, the lack of effective temperature monitoring methods prevents real-time adjustments to the cooling strategy based on actual water temperature, leading to significant coolant temperature fluctuations and impacting the stability and reliability of the water-cooling system. Furthermore, most water-cooled radiators employ only either water cooling or air cooling, failing to fully leverage the synergistic advantages of both methods and making it difficult to meet the increasing heat dissipation demands of high-heat-generating equipment. Utility Model Content
[0004] In order to overcome the shortcomings of existing technical solutions, this utility model provides a heat dissipation water cooling radiator, which can effectively solve the technical problem of poor heat dissipation effect of the currently used heat dissipation water cooling radiators.
[0005] The technical solution adopted by this utility model to solve its technical problem is:
[0006] A heat dissipation water cooling radiator includes a water cooling heat dissipation component and an air cooling auxiliary component, wherein the air cooling auxiliary component is fixed to the top of the water cooling heat dissipation component for delivering forced airflow into the water cooling heat dissipation component.
[0007] The water-cooled heat dissipation component includes a hollow shell. One end of the shell is provided with a hot water zone and a cold water zone that are isolated from each other. A first temperature sensor for detecting the water temperature in the hot water zone and a second temperature sensor for detecting the water temperature in the cold water zone are installed on the shell. The other end of the shell is provided with a fluid fusion zone. One end of the hot water zone and the fluid fusion zone are connected by several inlet pipes, and one end of the cold water zone and the fluid fusion zone are connected by several outlet pipes.
[0008] The inner side of the housing is provided with several parallel heat dissipation fins. The two ends of the heat dissipation fins are fixed to the inner wall of the housing. Several through holes are opened in the middle of the heat dissipation fins so that the heat dissipation fins are sleeved on the outside of all water inlet pipes and water outlet pipes. On both sides of the through holes, there are extensions that are closely attached to the outside of the water inlet / water outlet pipes.
[0009] The air-cooling auxiliary component includes a frame and multiple fan bodies. The frame is fixed to the top of the housing, and the fan body array is arranged on the frame, with the air outlet direction of the fan body aligned with the surface of the heat dissipation fins.
[0010] Furthermore, a water inlet and a water outlet are respectively provided on one side of the housing. One end of the water inlet is connected to the hot water area, and one end of the water outlet is connected to the cold water area.
[0011] Furthermore, the heat dissipation fins are provided with protruding mounting portions at both ends, and the inner wall of the housing is provided with mounting grooves that cooperate with the mounting portions for snap-fit fixing, thus forming a detachable structure.
[0012] Furthermore, the top and bottom of the housing are respectively provided with fixed annular plates, which cover all mounting parts on the corresponding side.
[0013] Furthermore, the heat dissipation fins are arranged perpendicularly to the water inlet / outlet pipe, and the extension extends along the length of the water inlet / outlet pipe.
[0014] Furthermore, the frame is detachably connected to the housing, and the frame is provided with several mounting holes in its circumference, and is fixed to the housing by inserting locking elements into the mounting holes.
[0015] Furthermore, the bottom of the housing is provided with several feet for support and fixation.
[0016] Compared with the prior art, the beneficial effects of this utility model are:
[0017] This invention significantly increases the contact area with the inlet and outlet pipes by using several parallel heat dissipation fins arranged inside the housing, combined with a through hole and extension in the middle. This allows for sufficient heat exchange through the heat dissipation fins, improving heat exchange efficiency and accelerating heat dissipation. During heat dissipation, it works in conjunction with a first temperature sensor and a second temperature sensor to detect the water flow temperature in the hot and cold water zones in real time and accurately, allowing for flexible adjustment of the water flow rate according to the actual temperature. The water-cooled heat dissipation component is used in conjunction with the air-cooled auxiliary component, and the forced airflow can quickly remove the heat from the surface of the heat dissipation fins, further enhancing the heat dissipation effect. The synergistic work of air cooling and water cooling greatly improves the overall heat dissipation efficiency. Attached Figure Description
[0018] Figure 1This is a schematic diagram of the overall structure of an embodiment of the present utility model;
[0019] Figure 2 This is an exploded view of the combination of the water-cooled heat dissipation component and the air-cooled auxiliary component in an embodiment of this utility model;
[0020] Figure 3 This is a schematic diagram of the internal structure of the water-cooled heat dissipation component housing according to an embodiment of the present utility model;
[0021] Figure 4 This is a schematic diagram of the internal structure of the water-cooled heat dissipation component housing according to an embodiment of the present utility model;
[0022] Figure 5 This is a schematic diagram of the heat dissipation fin structure of the water-cooled heat dissipation component according to an embodiment of the present invention;
[0023] Numbering on the map:
[0024] 100 - Water-cooled heat dissipation components, 200 - Air-cooled auxiliary components;
[0025] 1-Housing, 2-First temperature sensor, 3-Second temperature sensor, 4-Inlet pipe, 5-Outlet pipe, 6-Heat dissipation fins, 7-Frame, 8-Fan body, 9-Annular plate, 10-Locking component, 11-Foot base;
[0026] 101-Hot water zone, 102-Cold water zone, 103-Fluid mixing zone, 104-Inlet water interface, 105-Outlet water interface, 106-Installation slot;
[0027] 601 - Through hole, 602 - Extension, 603 - Mounting part;
[0028] 701 - Mounting hole. Detailed Implementation
[0029] 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.
[0030] like Figure 1-5 As shown, this utility model provides a heat dissipation water cooling radiator, which is composed of a water cooling heat dissipation component 100 and an air cooling auxiliary component 200. The air cooling auxiliary component is fixedly installed on the top of the water cooling heat dissipation component 100 to deliver forced airflow into the water cooling heat dissipation component 100. The two work together to achieve efficient heat dissipation.
[0031] In the water-cooled heat dissipation assembly 100, the hollow shell 1 is the core component, with a mutually isolated hot water zone 101 and cold water zone 102 at one end. This isolation design ensures that hot and cold water flow independently within their respective zones, preventing mixing and guaranteeing the normal operation of the heat dissipation system. A first temperature sensor 2 is installed in the hot water zone 101 to monitor the water temperature in real time; a second temperature sensor 3 is installed in the cold water zone 102 to monitor the water temperature in real time. Both the first and second temperature sensors extend their temperature-sensing structures into the hot water zone 101 and cold water zone 102. These sensors promptly feed the detected temperature information back to the control system, facilitating the monitoring and adjustment of the water flow rate.
[0032] The other end of the casing 1 is provided with a fluid fusion zone 103. The hot water zone 101 is connected to one end of the fluid fusion zone 103 through several inlet pipes 4, and the cold water zone 102 is connected to one end of the fluid fusion zone 103 through several outlet pipes 5. In actual operation, the hot water to be cooled flows from the hot water zone 101 into the fluid fusion zone 103 through the inlet pipes 4, and then flows back to the cold water zone 102 through the outlet pipes 5, forming a complete water circulation cooling path.
[0033] The inner side of the housing 1 is provided with several parallel heat dissipation fins 6. The two ends of the heat dissipation fins 6 are fixed to the inner wall of the housing 1. Specifically, the two ends of the heat dissipation fins 6 are provided with protruding mounting parts 603. The inner wall of the housing 1 is provided with mounting grooves 106 at corresponding positions to engage and fix with the mounting parts 603. Through this engagement method, the heat dissipation fins 6 and the housing 1 form a detachable structure, which facilitates the maintenance and replacement of the heat dissipation fins 6 in the future. In order to further fix the heat dissipation fins 6, fixed annular plates 9 are provided at the top and bottom of the housing 1 respectively. The annular plates 9 cover all the mounting parts 603 on the corresponding side to ensure that the heat dissipation fins 6 will not loosen during operation.
[0034] The heat dissipation fins 6 have several through holes 601 in the middle, allowing them to be fitted onto the outside of all the inlet pipes 4 and outlet pipes 5. Extensions 602, tightly attached to the outside of the inlet pipes 4 and outlet pipes 5, are provided on both sides of the through holes 601. The heat dissipation fins 6 are arranged perpendicularly to the inlet pipes 4 and outlet pipes 5, and the extensions 602 extend along the length of the inlet pipes 4 and outlet pipes 5. This design increases the contact area between the heat dissipation fins 6 and the inlet and outlet pipes 4 and 5, improving heat exchange efficiency and thus better dissipating heat from the water pipes.
[0035] The air-cooled auxiliary component includes a frame 7 and multiple fan bodies 8. The frame 7 is detachably connected to the housing 1. The frame 7 is provided with several mounting holes 701 around its circumference. The frame 7 is fixed to the housing 1 by inserting locking pieces 10 into the mounting holes 701. Alternatively, it can be fixed by mounting on an annular piece 9. This detachable connection method facilitates the installation, disassembly, and maintenance of the air-cooled auxiliary component.
[0036] The fan array 8 is mounted on the frame 7, and the airflow direction of the fan array 8 is directed towards the surface of the heat sink fins 6. During operation, the fan array 8 starts and delivers forced airflow to the surface of the heat sink fins 6, accelerating the airflow speed on the surface of the heat sink fins 6, carrying away the heat on the heat sink fins 6, and further enhancing the heat dissipation effect.
[0037] In addition, a water inlet 104 and a water outlet 105 are respectively provided on one side of the housing 1. One end of the water inlet 104 is connected to the hot water zone 101, and one end of the water outlet 105 is connected to the cold water zone 102, which facilitates connection with an external water circulation system to realize the input of hot water and the output of cold water. Several feet 11 are provided around the bottom of the housing 1 for support and fixation, so that the heat dissipation water cooling radiator can be stably placed in the working position and can enhance the air circulation at the bottom.
[0038] In actual use, external hot water to be cooled enters the hot water zone 101 through the inlet port 104, then flows into the fluid fusion zone 103 through the inlet pipe 4, and then flows from the fluid fusion zone 103 to the cold water zone 102. As the hot water flows through the inlet pipe 4 or the outlet pipe 5, heat is transferred to the heat dissipation fins 6. At this time, the fan 8 of the air-cooling auxiliary component starts, forcing airflow to accelerate heat dissipation from the surface of the heat dissipation fins 6, thus cooling the water. Finally, the water is output through the outlet port 105, completing the entire heat dissipation cycle. The first temperature sensor 2 and the second temperature sensor 3 monitor the water temperature in the hot water zone 101 and the cold water zone 102 in real time to optimize and adjust the heat dissipation system.
[0039] Compared with traditional technologies, this technical solution significantly increases the contact area with the inlet pipe 4 and outlet pipe 5 by setting several parallel heat dissipation fins 6 on the inner side of the housing 1, combined with the through hole 601 in the middle and the extension 602. This allows for sufficient heat exchange through the heat dissipation fins 6, improving heat exchange efficiency and thus accelerating heat dissipation. During heat dissipation, it is used in conjunction with the first temperature sensor 2 and the second temperature sensor 3 to detect the water flow temperature in the hot water zone 101 and the cold water zone 102 in real time and accurately, and the water flow rate can be flexibly adjusted according to the actual temperature. The water-cooled heat dissipation component 100 is used in conjunction with the air-cooled auxiliary component, and the forced airflow can quickly remove the heat from the surface of the heat dissipation fins, further enhancing the heat dissipation effect. The synergistic work of air cooling and water cooling greatly improves the overall heat dissipation efficiency.
[0040] It will be apparent to those skilled in the art that this invention is not limited to the details of the exemplary embodiments described above, and that it can be implemented in other specific forms without departing from the spirit or essential characteristics of this invention. Therefore, the embodiments should be considered illustrative and non-limiting in all respects, and the scope of this invention is defined by the appended claims rather than the foregoing description. Thus, all variations falling within the meaning and scope of equivalents of the claims are intended to be included within this invention, and no reference numerals in the claims should be construed as limiting the scope of the claims.
Claims
1. A water-cooled radiator, comprising a water-cooled heat dissipation component and an air-cooled auxiliary component, wherein the air-cooled auxiliary component is fixed to the top of the water-cooled heat dissipation component for delivering forced airflow into the water-cooled heat dissipation component, characterized in that: The water-cooled heat dissipation component includes a hollow shell. One end of the shell is provided with a hot water zone and a cold water zone that are isolated from each other. A first temperature sensor for detecting the water temperature in the hot water zone and a second temperature sensor for detecting the water temperature in the cold water zone are installed on the shell. The other end of the shell is provided with a fluid fusion zone. One end of the hot water zone and the fluid fusion zone are connected by several inlet pipes, and one end of the cold water zone and the fluid fusion zone are connected by several outlet pipes. The inner side of the housing is provided with several parallel heat dissipation fins. The two ends of the heat dissipation fins are fixed to the inner wall of the housing. Several through holes are opened in the middle of the heat dissipation fins so that the heat dissipation fins are sleeved on the outside of all water inlet pipes and water outlet pipes. Extensions that are close to the outside of the water inlet / water outlet pipes are provided on both sides of the through holes. The air-cooling auxiliary component includes a frame and multiple fan bodies. The frame is fixed to the top of the housing, and the fan body array is arranged on the frame, with the air outlet direction of the fan body aligned with the surface of the heat dissipation fins.
2. The water cooled heat sink of claim 1, wherein: The housing is provided with a water inlet and a water outlet on one side. One end of the water inlet is connected to the hot water zone, and one end of the water outlet is connected to the cold water zone.
3. The water cooled heat sink of claim 1, wherein: The heat dissipation fins have protruding mounting portions at both ends, and the inner wall of the housing has mounting grooves that engage with the mounting portions for fixing, forming a detachable structure.
4. A water cooled heat sink panel according to claim 3, wherein: The top and bottom of the housing are respectively provided with fixed annular plates, which cover all the mounting parts on the corresponding side.
5. A water-cooled radiator according to claim 1, characterized in that: The heat dissipation fins are arranged perpendicularly to the water inlet / outlet pipe, and the extension extends along the length of the water inlet / outlet pipe.
6. A water-cooled radiator according to claim 1, characterized in that: The frame is detachably connected to the housing. The frame is provided with several mounting holes around its circumference and is fixed to the housing by inserting locking elements into the mounting holes.
7. A water-cooled radiator according to any one of claims 1-6, characterized in that: The bottom circumferential of the housing is provided with several feet for support and fixation.