Pressure-adjustable radiator

By designing adjustment components for the water supply, inlet, and outlet ends in the radiator, the problem of water pressure fluctuation in the radiator is solved, achieving stable water pressure regulation and simple and efficient operation, thereby improving heating effect and equipment lifespan.

CN224415253UActive Publication Date: 2026-06-26TIANJIN JIUDING YANGGUANG HVAC CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
TIANJIN JIUDING YANGGUANG HVAC CO LTD
Filing Date
2025-08-11
Publication Date
2026-06-26

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Abstract

The application provides a pressure-adjustable radiator, comprising: a heat dissipation assembly, the heat dissipation assembly comprising a flow-through space for water flow, and the heat dissipation assembly is provided with a water inlet and a water outlet which are communicated with the flow-through space; an adjusting assembly, the adjusting assembly is arranged on the side of the heat dissipation assembly away from the water inlet and the water outlet, and the adjusting assembly comprises a water supply end, a water inlet end and a water outlet end, the water supply end and the water outlet end are arranged on the bottom of the heat dissipation assembly, the water outlet end is communicated with the flow-through space, and the water supply end is used for connecting an external water supply device; the water inlet end is arranged on the top of the heat dissipation assembly, the water inlet end is communicated with the water supply end and the flow-through space. The radiator provided by the application can supplement water and discharge water by controlling the on-off of the water inlet end and the water outlet end when the water pressure is too high or too low, and the position of the water inlet end and the water outlet end is convenient for controlling the on-off.
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Description

Technical Field

[0001] This disclosure generally relates to the field of radiator equipment technology, and specifically to a pressure-adjustable radiator. Background Technology

[0002] Radiators are common equipment in winter heating systems, which use hot water or steam circulating inside to dissipate heat and raise the indoor temperature.

[0003] In existing technologies, radiators often experience problems with excessively high or low water pressure due to fluctuations in system water pressure during use, affecting heating efficiency and even causing equipment damage. Traditional radiators lack convenient water pressure adjustment mechanisms, requiring external tools or complex piping for water replenishment and drainage operations. Furthermore, the unreasonable design of related interface locations makes on / off control inconvenient and difficult to quickly respond to abnormal water pressure situations. Utility Model Content

[0004] In view of the above-mentioned defects or deficiencies in the prior art, it is desirable to provide a pressure-adjustable radiator to solve the above problems.

[0005] This application provides a pressure-adjustable radiator, comprising:

[0006] A heat dissipation assembly, comprising a flow space for water flow, wherein one side of the heat dissipation assembly is provided with an inlet and an outlet communicating with the flow space;

[0007] An adjustment component is provided on the side of the heat dissipation component away from the water inlet and outlet. The adjustment component includes a water supply end, a water inlet end, and a water outlet end. The water supply end and the water outlet end are located at the bottom of the heat dissipation component. The water outlet end is connected to the flow space. The water supply end is used to connect to an external water supply device. The water inlet end is located at the top of the heat dissipation component. The water inlet end is connected to the water supply end and to the flow space.

[0008] According to the technical solution provided in the embodiments of this application, the adjustment component further includes:

[0009] A first connector is fixed to the heat dissipation assembly. The first connector is provided with a first interface, a second interface and a third interface. The first interface is connected to the flow space, the second interface forms the water outlet, and the third interface is used to install a control valve that controls the on / off state of the first interface and the second interface.

[0010] The second connector is fixed to the heat dissipation assembly. The second connector is provided with a fourth interface, a fifth interface and a sixth interface. The fourth interface forms the water inlet end, and the fifth interface is used to install a control valve to control the on / off state of the fourth interface and the sixth interface.

[0011] The third connector is fixed to the first connector. The third connector is provided with a seventh interface and an eighth interface. The seventh interface forms the water supply end, and the eighth interface is connected to the sixth interface through a flow guide pipe.

[0012] According to the technical solution provided in the embodiments of this application, the second interface and the seventh interface are oriented toward the side away from the top of the heat dissipation component.

[0013] According to the technical solution provided in the embodiments of this application, the third interface and the fifth interface are oriented towards the side away from the inlet and the outlet.

[0014] According to the technical solution provided in the embodiments of this application, the third connector is welded to the second connector.

[0015] According to the technical solution provided in the embodiments of this application, a spherical cavity is formed in the first connector, the second connector and the third connector.

[0016] According to the technical solution provided in the embodiments of this application, the heat dissipation component includes:

[0017] A pair of radiator bodies are arranged in parallel and fixed by a connecting plate, and the circulation space is formed inside the radiator body;

[0018] A heat dissipation corrugated plate is disposed between a pair of radiator bodies, and the heat dissipation corrugated plate is in contact with the radiator bodies.

[0019] According to the technical solution provided in the embodiments of this application, the connecting plate includes a first connecting plate and a pair of second connecting plates. The first connecting plate is connected to the top of the pair of radiator bodies, and the second connecting plates are detachably connected to both sides of the radiator bodies.

[0020] Compared with the prior art, the beneficial effects of this application are as follows: By setting an adjustment component including a water supply end, a water inlet end, and a water outlet end on one side of the heat dissipation component, water can be released through the water outlet end when the water pressure of the radiator is too high and water can be added through the water inlet end when the water pressure is too low, so as to realize convenient water pressure adjustment and ensure its stable operation; in addition, the water inlet end is located at the top of the heat dissipation component and the water outlet end and the water supply end are located at the bottom. This position design facilitates the operation and control of the on / off of the water inlet end and the water outlet end, and the layout of the adjustment component does not affect the normal use of the water inlet and water outlet on the other side of the heat dissipation component. The overall structure is simple and the adjustment operation is simple and efficient. Attached Figure Description

[0021] Other features, objects, and advantages of this application will become more apparent from the following detailed description of non-limiting embodiments with reference to the accompanying drawings:

[0022] Figure 1 A structural schematic diagram of the pressure-adjustable radiator provided in this application;

[0023] Figure 2 for Figure 1 A schematic diagram of the adjustable pressure radiator from another perspective.

[0024] Figure 3 for Figure 1 A schematic diagram of the top surface structure of a pressure-adjustable radiator is shown.

[0025] Figure 4 A diagram illustrating the installation position of the adjustable components;

[0026] Figure 5 This is a schematic diagram of the adjustment component.

[0027] Reference numerals: 100, Heat dissipation component; 101, Water inlet; 102, Water outlet; 110, Radiator body; 120, Corrugated heat dissipation plate; 130, First connecting plate; 140, Second connecting plate; 200, Adjustment component; 210, First connector; 211, First interface; 212, Second interface; 213, Third interface; 220, Second connector; 221, Fourth interface; 222, Fifth interface; 223, Sixth interface; 230, Third connector; 231, Seventh interface; 232, Eighth interface; 240, Flow guide pipe. Detailed Implementation

[0028] The present application will now be described in further detail with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the invention and not intended to limit it. Furthermore, it should be noted that, for ease of description, only the parts relevant to the invention are shown in the accompanying drawings.

[0029] It should be noted that, unless otherwise specified, the embodiments and features described in this application can be combined with each other. This application will now be described in detail with reference to the accompanying drawings and embodiments.

[0030] Please refer to Figures 1-5 This application provides a pressure-adjustable radiator, comprising:

[0031] A heat dissipation assembly 100 includes a flow space for water flow, and an inlet 101 and an outlet 102 communicating with the flow space are provided on one side of the heat dissipation assembly 100.

[0032] An adjustment component 200 is disposed on the side of the heat dissipation component 100 away from the water inlet 101 and the water outlet 102. The adjustment component 200 includes a water supply end, a water inlet end, and a water outlet end. The water supply end and the water outlet end are disposed at the bottom of the heat dissipation component 100. The water outlet end is connected to the flow space. The water supply end is used to connect to an external water supply device. The water inlet end is disposed at the top of the heat dissipation component 100. The water inlet end is connected to the water supply end and to the flow space.

[0033] Specifically, the radiator provided in this application consists of two parts: a heat dissipation component 100 and an adjustment component 200. The heat dissipation component 100 is used to realize the normal heat dissipation function of the radiator, and the adjustment component 200 is used to adjust the water pressure when the water pressure in the radiator is too high or too low, so as to ensure that the water pressure is in a stable state.

[0034] The heat dissipation component 100 includes a circulation space, a water inlet 101, and a water outlet 102. The water inlet 101 and the water outlet 102 are located on the same side of the heat dissipation component 100. During use, hot water is introduced into the circulation space through the water inlet 101 and discharged through the water outlet 102, thereby allowing the hot water to circulate and dissipate heat outward through the circulation space, increasing the ambient temperature. The location of the water inlet 101 and the water outlet 102 on the same side of the heat dissipation component 100 facilitates the installation of the water inlet and outlet pipes. The water inlet 101 is located near the top of the heat dissipation component 100, while the water outlet 102 is located near the bottom of the heat dissipation component 100, meaning that the heat dissipation component 100 receives water from the top and exits water from the bottom.

[0035] The regulating component 200 is located on the side of the heat dissipation component 100 away from the inlet 101 and outlet 102, so as to avoid interference with the use of the inlet 101 and outlet 102. The regulating component 200 includes at least a water supply end, a water inlet end, and a water outlet end. The water inlet end is connected to the water supply end and to the flow space. The water inlet end is located near the top of the heat dissipation component 100 and the connection between the water inlet end and the flow space can be controlled by a control valve. The water outlet end is located near the bottom of the heat dissipation component 100 and is connected to the flow space. The connection between the water outlet end and the flow space can also be controlled by a control valve. When the water pressure in the circulation space is too low, the water supply end is connected to an external water supply device. The hot water provided by the water supply device enters the circulation space through the water supply end and the inlet end, thereby increasing the water pressure. When the water pressure in the circulation space is too high, some water in the circulation space is discharged by opening the outlet end, thereby reducing the water pressure. The entire process of adjusting the water pressure does not affect the normal operation of the inlet 101 and the outlet 102. Since low water pressure is more common under normal circumstances, this application sets the inlet end near the top of the heat dissipation component 100, which facilitates the adjustment of the inlet end through the control valve. The adjustment operation does not require bending over, resulting in better actual use. The outlet end and the water supply end are set near the bottom of the heat dissipation component 100, which facilitates the arrangement of the inlet and outlet pipes for water pressure adjustment.

[0036] Furthermore, the heat dissipation assembly 100 includes:

[0037] A pair of radiator bodies 110, the pair of radiator bodies 110 are arranged in parallel and fixed by a connecting plate, and the circulation space is formed inside the radiator body 110;

[0038] A heat dissipation corrugated plate 120 is disposed between a pair of radiator bodies 110, and the heat dissipation corrugated plate 120 is in contact with the radiator body 110.

[0039] Specifically, the heat dissipation assembly 100 consists of a radiator body 110 and a corrugated heat dissipation plate 120. The radiator body 110 is made of metal and has a hollow interior forming a circulation space. Since there is a pair of radiator bodies 110, in this embodiment, there are two unconnected circulation spaces. The inlet 101 and outlet 102 are connected to the two circulation spaces via two branch pipes. The pair of radiator bodies 110 are arranged in parallel with a gap between them. A corrugated heat dissipation plate 120 is installed within the gap. The corrugated heat dissipation plate 120 is made of a thermally conductive metal material, and can be selected as an aluminum plate. The corrugated heat dissipation plate 120 diffuses heat by adhering tightly to the radiator body 110. To further improve heat dissipation performance, two rows of corrugated heat dissipation plates 120 are arranged between the pair of radiator bodies 110. The two rows of corrugated heat dissipation plates 120 are respectively adhered to the two radiator bodies 110, and the two corrugated heat dissipation plates 120 are separated by a gap. To ensure relative stability between a pair of radiator bodies 110, a connecting plate is used to connect and fix the pair of radiator bodies 110.

[0040] Furthermore, the connecting plate includes a first connecting plate 130 and a pair of second connecting plates 140. The first connecting plate 130 is connected to the top of the pair of radiator bodies 110, and the second connecting plates 140 are detachably connected to both sides of the radiator body 110.

[0041] Specifically, the first connecting plate 130 connects to the top of a pair of radiator bodies 110. The first connecting plate 130 has multiple rectangular through holes, allowing for limited heat dissipation between the pair of radiator bodies 110. A pair of second connecting plates 140 are respectively installed on opposite sides of the pair of radiator bodies 110. The second connecting plates 140 fasten onto the radiator bodies 110, facilitating installation and removal. The second connecting plates 140 also have through holes for water pipes to pass through.

[0042] Furthermore, the adjustment component 200 also includes:

[0043] First connector 210, which is fixed to the heat dissipation assembly 100, is provided with a first interface 211, a second interface 212 and a third interface 213. The first interface 211 communicates with the flow space, the second interface 212 forms the water outlet, and the third interface 213 is used to install a control valve that controls the opening and closing of the first interface 211 and the second interface 212.

[0044] The second connector 220 is fixed to the heat dissipation assembly 100. The second connector 220 is provided with a fourth interface 221, a fifth interface 222 and a sixth interface 223. The fourth interface 221 forms the water inlet end, and the fifth interface 222 is used to install a control valve that controls the opening and closing of the fourth interface 221 and the sixth interface 223.

[0045] The third connector 230 is fixed to the first connector 210. The third connector 230 is provided with a seventh interface 231 and an eighth interface 232. The seventh interface 231 forms the water supply end, and the eighth interface 232 is connected to the sixth interface 223 through the guide pipe 240.

[0046] Specifically, the adjustment component 200 in this application consists of a first connector 210, a second connector 220, and a third connector 230, all three connectors being spherical in shape. The first connector 210 has three interconnected interfaces: a first interface 211, a second interface 212, and a third interface 213. Since this embodiment includes two flow spaces, two first interfaces 211 are provided to communicate with each of the two flow spaces respectively. Therefore, the first connector 210 uses a four-way pipe with four interfaces. The second interface 212 serves as the outlet for draining water when the water pressure is too high. The third interface 213 is used for installing an external control valve. The control valve at the third interface 213 can control the connection and disconnection between the first interface 211 and the second interface 212. The principle of the control valve is prior art and will not be elaborated here. The second connector 220 is provided with a fourth interface 221, a fifth interface 222, and a sixth interface 223 that are interconnected. In this embodiment, the fourth interface 221 serves as a water inlet and has two interfaces to connect to two flow spaces respectively. Therefore, the second connector 220 also adopts a four-way pipe with four interfaces. The fifth interface 222 has the same function as the third interface 213, both of which are used for the installation of an external control valve. The control valve at the fifth interface 222 can control the opening and closing of the fourth interface 221 and the sixth interface 223. The third connector 230 is provided with a seventh interface 231 and an eighth interface 232 that are interconnected. The seventh interface 231 serves as a water supply end for connecting to an external water supply device, while the eighth interface 232 is connected to the sixth interface 223 through a guide pipe 240.

[0047] The first connector 210 is fixed between a pair of radiator bodies 110 by connecting two first interfaces 211 to two radiator bodies 110 respectively. Optionally, the connection method is welding. The second connector 220 is fixed between a pair of radiator bodies 110 by connecting two fourth interfaces 221 to two radiator bodies 110 respectively. Optionally, the connection method is welding. The third connector 230 is connected to the first connector 210 as a whole. In this embodiment, the third connector 230 and the first connector 210 are fixedly connected by welding, and the third connector 230 and the first connector 210 are not internally connected.

[0048] Furthermore, the openings of the second interface 212 and the seventh interface 231 face away from the top of the heat dissipation assembly 100.

[0049] Specifically, the second interface 212 and the seventh interface 231 are oriented away from the top of the heat dissipation component 100, which allows the connecting pipes of the water outlet and the water supply end to extend along the bottom of the heat dissipation component 100, avoiding the pipes from protruding upwards. This saves space above the radiator, making it convenient for users to place items or perform other operations in the top area, and also reduces the probability of the pipes being accidentally touched or bent due to protrusion, thus extending the service life of the pipes. At the same time, this orientation conforms to the natural flow direction of drainage and water supply, which can reduce the water flow resistance in the pipes, making the water discharge and replenishment process smoother and improving the water pressure regulation efficiency.

[0050] Furthermore, the third interface 213 and the fifth interface 222 are oriented toward the side away from the inlet 101 and the outlet 102.

[0051] Specifically, the third interface 213 and the fifth interface 222 extend towards the radiator side. On the one hand, this can prevent the inconvenience of installation and maintenance caused by the cross-entanglement of pipes. On the other hand, this orientation makes the operating area of ​​the control valve independent of the inlet and outlet pipe areas, which makes it easier for personnel to quickly locate and operate the control valve, reduce the risk of accidentally touching the inlet and outlet pipes, and improve the safety and convenience of operation when adjusting water pressure.

[0052] Furthermore, spherical cavities are formed within the first connector 210, the second connector 220, and the third connector 230.

[0053] Specifically, the spherical cavity design makes the internal water flow channel smoother, reducing water resistance and eddies at the joint, reducing energy loss during water pressure regulation, and making water replenishment and discharge more efficient. At the same time, the spherical cavity can disperse the impact force of water flow on the interface, reducing wear on the joint caused by long-term water flow impact and extending the service life of the joint.

[0054] The above description is merely a preferred embodiment of this application and an explanation of the technical principles employed. Those skilled in the art should understand that the scope of the invention involved in this application is not limited to technical solutions formed by specific combinations of the above-described technical features, but should also cover other technical solutions formed by arbitrary combinations of the above-described technical features or their equivalents without departing from the inventive concept. For example, technical solutions formed by substituting the above features with (but not limited to) technical features with similar functions disclosed in this application.

Claims

1. A pressure-adjustable radiator, characterized in that, include: A heat dissipation assembly (100) includes a flow space for water flow, and an inlet (101) and an outlet (102) communicating with the flow space are provided on one side of the heat dissipation assembly (100). An adjustment component (200) is located on the side of the heat dissipation component (100) away from the water inlet (101) and the water outlet (102). The adjustment component (200) includes a water supply end, a water inlet end, and a water outlet end. The water supply end and the water outlet end are located at the bottom of the heat dissipation component (100). The water outlet end is connected to the flow space. The water supply end is used to connect to an external water supply device. The water inlet end is located at the top of the heat dissipation component (100). The water inlet end is connected to the water supply end and to the flow space.

2. The pressure-adjustable radiator according to claim 1, characterized in that, The adjustment assembly (200) further includes: The first connector (210) is fixed to the heat dissipation assembly (100). The first connector (210) is provided with a first interface (211), a second interface (212) and a third interface (213). The first interface (211) communicates with the flow space, the second interface (212) forms the water outlet, and the third interface (213) is used to install a control valve that controls the opening and closing of the first interface (211) and the second interface (212). The second connector (220) is fixed to the heat dissipation assembly (100). The second connector (220) is provided with a fourth interface (221), a fifth interface (222) and a sixth interface (223). The fourth interface (221) forms the water inlet end, and the fifth interface (222) is used to install a control valve that controls the opening and closing of the fourth interface (221) and the sixth interface (223). The third connector (230) is fixed to the first connector (210). The third connector (230) is provided with a seventh interface (231) and an eighth interface (232). The seventh interface (231) forms the water supply end, and the eighth interface (232) is connected to the sixth interface (223) through a guide pipe (240).

3. The pressure-adjustable radiator according to claim 2, characterized in that, The second interface (212) and the seventh interface (231) face away from the top of the heat dissipation assembly (100).

4. The pressure-adjustable radiator according to claim 3, characterized in that, The third interface (213) and the fifth interface (222) face away from the inlet (101) and the outlet (102).

5. The pressure-adjustable radiator according to claim 4, characterized in that, The third connector (230) is welded to the second connector (220).

6. The pressure-adjustable radiator according to claim 5, characterized in that, The first connector (210), the second connector (220) and the third connector (230) each have a spherical cavity formed inside.

7. The pressure-adjustable radiator according to claim 6, characterized in that, The heat dissipation assembly (100) includes: A pair of radiator bodies (110) are arranged in parallel and fixed by a connecting plate, and the circulation space is formed inside the radiator body (110); A heat dissipation corrugated plate (120) is disposed between a pair of radiator bodies (110) and is attached to the radiator body (110).

8. The pressure-adjustable radiator according to claim 7, characterized in that, The connecting plate includes a first connecting plate (130) and a pair of second connecting plates (140). The first connecting plate (130) is connected to the top of a pair of radiator bodies (110), and the second connecting plates (140) are detachably connected to both sides of the radiator bodies (110).