Magnetic rapid heating device for a vortex tube

By using a vortex tube magnetic rapid heating device, the eddy current generated by the rotating magnetic shaft heats the water in the heat-conducting tube, solving the problems of low fuel efficiency and pollution in centralized water heating systems and achieving a highly efficient and clean heating method.

CN115127141BActive Publication Date: 2026-06-23李朝军

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Patents(China)
Current Assignee / Owner
李朝军
Filing Date
2022-07-19
Publication Date
2026-06-23

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Abstract

The application discloses a vortex tube magnetic rapid heating device, and relates to the technical field of heating equipment. The vortex tube magnetic rapid heating device is mainly used for heating water through magnetic force. The main technical scheme of the vortex tube magnetic rapid heating device is as follows: a vortex tube magnetic rapid heating device comprises an inner shell, a heating component, a magnetic shaft, a heat conduction component and a driving component. The magnetic shaft penetrates through the inner shell. The heat conduction component comprises a water supply component and a first heat conduction pipe. The water supply component is connected to the first heat conduction pipe. The first heat conduction pipe is arranged around the outer circumferential side of the magnetic shaft. The driving component is connected to one end of the magnetic shaft. The vortex tube magnetic rapid heating device is mainly used for heating.
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Description

Technical Field

[0001] This invention relates to the field of heating equipment technology, and in particular to an eddy current tube magnetic rapid heating device. Background Technology

[0002] In northern regions, most heating systems use centralized hydronic heating to supply heat to residential areas. This involves burning fuel in a boiler to heat water, which is then piped to the residential areas to maintain indoor temperatures. However, the boiler combustion process generates significant fuel pollution, and the low efficiency of fuel combustion results in some of the heat being wasted. Summary of the Invention

[0003] In view of this, the present invention provides a vortex tube magnetic rapid heating device, the main purpose of which is to provide a vortex tube magnetic rapid heating device that heats water by magnetic force.

[0004] To achieve the above objectives, the present invention mainly provides the following technical solutions:

[0005] This invention provides an eddy current tube magnetic rapid heating device, which includes:

[0006] Inner shell;

[0007] The heating element includes a magnetic shaft, a heat-conducting component, and a driving component. The magnetic shaft passes through the inner housing. The heat-conducting component includes a water supply component and a first heat-conducting pipe. The water supply component is connected to the first heat-conducting pipe, which is arranged around the outer periphery of the magnetic shaft. The driving component is connected to one end of the magnetic shaft.

[0008] Furthermore, the surface of the magnetic shaft has a first groove.

[0009] Furthermore, the first groove is spirally arranged around the outer periphery of the magnetic shaft.

[0010] Furthermore, the heating element also includes a coil component, which is disposed on the inner side of both ends of the inner housing. The coil component has a first cavity through which the magnetic shaft passes.

[0011] Furthermore, the coil component includes a first coil and a second coil, the first coil being disposed on one side of the inner housing and the second coil being disposed on the other side of the inner housing.

[0012] Furthermore, the heat-conducting component also includes a water return component, with the two ends of the first heat-conducting pipe respectively connected to the water supply component and the water return component, and the water return component connected to the water supply component.

[0013] Furthermore, the two ends of the first coil and the second coil are respectively connected to the water supply component and the water return component.

[0014] Furthermore, a cooling component is provided, comprising a cooling housing, a cooling supply component, an inlet pipe, and an outlet pipe. The cooling housing is fitted onto the side of the inner housing. One end of the inlet pipe and the outlet pipe is connected to the cooling supply component, and the other end of the inlet pipe and the outlet pipe is connected to the cooling housing.

[0015] Furthermore, the driving component includes a drive motor and a frequency converter, the frequency converter being disposed on the upper part of the drive motor, and the output end of the drive motor being connected to the magnetic shaft.

[0016] Furthermore, a temperature detector is connected to both the inner housing and the cooling housing.

[0017] Compared with the prior art, the present invention has the following technical effects:

[0018] In the technical solution provided by this invention, the inner shell serves to support and enclose the heating element; the heating element heats water. The heating element includes a magnetic shaft, a heat-conducting component, and a driving component. The magnetic shaft penetrates the inner shell. The heat-conducting component includes a water supply component and a first heat-conducting pipe. The water supply component is connected to the first heat-conducting pipe, which is arranged around the outer periphery of the magnetic shaft. The driving component is connected to one end of the magnetic shaft. Compared to existing technologies, this method uses centralized water heating to provide heating to residential areas. Water is heated by burning fuel in a boiler, and the hot water is then transported to the residential areas through pipes. Heating is used to ensure the temperature inside the house. However, the combustion process of the boiler causes a lot of fuel pollution, and the fuel combustion efficiency is low, resulting in the waste of some of the heat from the fuel. In this technical solution, a rotating magnetic shaft is set in the inner shell, and a first heat-conducting pipe is arranged around the outer periphery of the magnetic shaft. A driving component is connected to one end of the magnetic shaft. The driving component drives the magnetic shaft to rotate around its axis. The magnetic shaft generates eddy currents at a certain rotation speed. The first heat-conducting pipe heats up in the constantly changing magnetic field, so that the water in the first heat-conducting pipe is heated by the first heat-conducting pipe, thereby achieving the technical effect of heating the water in the first heat-conducting pipe. Attached Figure Description

[0019] Figure 1 A schematic diagram of the structure of the first eddy current tube magnetic rapid heating device provided in the embodiment of the present invention;

[0020] Figure 2 This is a schematic diagram of the structure of the second type of eddy current tube magnetic rapid heating device provided in an embodiment of the present invention;

[0021] Figure 3 A schematic diagram of the structure of a magnetic shaft provided in an embodiment of the present invention;

[0022] Figure 4 This is a schematic diagram of a coil component provided in an embodiment of the present invention. Detailed Implementation

[0023] The present invention will now be described in further detail with reference to the accompanying drawings and embodiments.

[0024] like Figure 1 As shown, an embodiment of the present invention provides an eddy current tube magnetic rapid heating device, which includes:

[0025] Inner shell 1;

[0026] The heating element includes a magnetic shaft 21, a heat-conducting component 22, and a driving component 23. The magnetic shaft 21 penetrates the inner shell 1. The heat-conducting component 22 includes a water supply component 221 and a first heat-conducting pipe 222. The water supply component 221 is connected to the first heat-conducting pipe 222. The first heat-conducting pipe 222 is arranged around the outer periphery of the magnetic shaft 21. The driving component 23 is connected to one end of the magnetic shaft 21.

[0027] In the technical solution provided by this embodiment of the invention, the inner shell 1 serves to support and enclose the heating element; the heating element heats water. The heating element includes a magnetic shaft 21, a heat-conducting component 22, and a driving component 23. The magnetic shaft 21 penetrates the inner shell 1. The heat-conducting component 22 includes a water supply component 221 and a first heat-conducting pipe 222. The water supply component 221 is connected to the first heat-conducting pipe 222, which is arranged around the outer periphery of the magnetic shaft 21. The driving component 23 is connected to one end of the magnetic shaft 21. Compared to the prior art, this method uses centralized water heating to provide heating to residential areas. The water is heated by burning fuel in a boiler, and then the hot water is transported to the residential areas through pipes for heating, thereby ensuring… The temperature inside the house is important, but during the boiler combustion process, a large amount of fuel pollution is caused, and the fuel combustion efficiency is low, resulting in the waste of some of the fuel's heat. In this technical solution, a rotating magnetic shaft 21 is set in the inner shell 1, and a first heat-conducting pipe 222 is arranged around the outer periphery of the magnetic shaft 21. A driving component 23 is connected to one end of the magnetic shaft 21. The driving component 23 drives the magnetic shaft 21 to rotate around its axis. The magnetic shaft 21 generates eddy currents at a certain rotation speed. The first heat-conducting pipe 222 heats up in the constantly changing magnetic field, so that the water in the first heat-conducting pipe 222 is heated by the first heat-conducting pipe 222, thereby achieving the technical effect of heating the water in the first heat-conducting pipe 222.

[0028] The inner shell 1 serves to support and enclose the heating element. The shell is made of stainless steel or aluminum alloy, has a cavity in the middle, and two through holes at both ends. Bearings are installed inside the through holes. The heating element heats water and includes a magnetic shaft 21, a heat-conducting component 22, and a driving component 23. The magnetic shaft 21 penetrates the inner shell 1. The heat-conducting component 22 includes a water supply component 221 and a first heat-conducting pipe 222. The water supply component 221 is connected to the first heat-conducting pipe 222, which surrounds the outer periphery of the magnetic shaft 21. The driving component 23 is connected to one end of the magnetic shaft 21. The magnetic shaft 21 has a cylindrical structure. The magnetic shaft 21 has N poles and S poles on its sides. Specifically, the magnetic shaft 21 has N poles at the top and S poles at the bottom, with the axis as the dividing line. The magnetic shaft 21 is a permanent magnet and can be disassembled and remagnetized using existing magnetization equipment, allowing for reuse. The heat-conducting component 22 includes a water supply component 221 and a first heat-conducting pipe 222. The water supply component 221 is connected to the first heat-conducting pipe 222, which surrounds the outer periphery of the magnetic shaft 21. The water supply component 221 can use existing water supply equipment. Specifically, the water supply component 221 includes a water tank and a water pump, with the water pump mounted on the water tank. A heat pipe 222 is connected to a water pump, which delivers water from the water tank to the heat pipe 222. The heat pipe 222 is spirally wound around the outer circumference of the magnetic shaft 21, and its rotation direction is the same as that of the magnetic shaft 21. The heat pipe 222 is made of copper to improve its thermal conductivity. Water flows through the heat pipe 222, which does not directly contact the magnetic shaft 21. A drive component 23 is located on the outer side of one end of the inner shell 1 and is connected to one end of the magnetic shaft 21, enabling the magnetic shaft 21 to rotate around its axis. Since the magnetic shaft 21 requires a certain rotation speed... Only when the temperature is high enough can the first heat pipe 222 heat up. Therefore, the minimum rotation speed of the magnetic shaft 21 is 2800 revolutions per minute. In this technical solution, a rotating magnetic shaft 21 is set in the inner shell 1, and the first heat pipe 222 is arranged around the outer periphery of the magnetic shaft 21. The driving component 23 is connected to one end of the magnetic shaft 21. The driving component 23 drives the magnetic shaft 21 to rotate around its axis. The magnetic shaft 21 generates eddy currents at a certain rotation speed. The first heat pipe 222 heats up in the constantly changing magnetic field, so that the water in the first heat pipe 222 is heated by the first heat pipe 222, thereby achieving the technical effect of heating the water in the first heat pipe 222.

[0029] Furthermore, such as Figure 2 and Figure 3As shown, the surface of the magnetic shaft 21 has a first groove 213. In this embodiment, the magnetic shaft 21 is further defined, and the first groove 213 is provided on the surface of the magnetic shaft 21. Specifically, the magnetic shaft 21 includes a shaft body 211 and a rotor 212. The shaft body 211 and the rotor 212 are integrally formed. Both ends of the shaft body 211 extend out of the inner housing 1. One end of the shaft body 211 is connected to the drive component 23. The rotor 212 is disposed inside the inner housing 1. The surface of the rotor 212 has a first groove 213. The function of the first groove 213 is to improve the heating efficiency of the first heat pipe 222. Specifically, the first groove 213 is spirally arranged around the outer periphery of the magnetic shaft 21. The spiral direction is the same as the rotation direction of the rotor 212. This not only improves the heating efficiency of the first heat pipe 222, but also drives the water in the first heat pipe 222 to flow along the spiral direction, thereby increasing the water flow speed.

[0030] Furthermore, such as Figure 4 As shown, the heating element also includes a coil component 24, which is disposed on the inner sides of both ends of the inner shell 1. The coil component 24 has a first cavity 243 through which the magnetic shaft 21 passes. In this embodiment, a coil component 24 is added, which adopts an annular coil structure. Specifically, the coil component 24 is formed by winding copper tubing. The coil component 24 has a first cavity 243 in the middle, through which the magnetic shaft 21 passes. Furthermore, the axis of the coil component 24 coincides with the axis of the magnetic shaft 21. Specifically, the coil component 24 includes a first coil 241 and a second coil 242. The first coil 241 is disposed on one side of the inner shell 1, and the second coil 242 is disposed on the other side of the inner shell 1. Water is introduced into the first coil 241 and the second coil 242. During the rotation of the magnetic shaft 21, the coil component 24 is heated, thereby achieving the technical effect of heating the water in the coil component 24.

[0031] Furthermore, the heat-conducting component 22 also includes a water return component. The two ends of the first heat-conducting pipe 222 are respectively connected to the water supply component 221 and the water return component, with the water return component connected to the water supply component 221. In summary, this embodiment adds a water return component. The function of the water return component is to transport cooled water to the water supply component 221. After the water is heated in the first heat-conducting pipe 222, the hot water is transported to the residential area through pipes. After the hot water cools down, it enters the water supply component 221. Specifically, the water return component includes a water return pump 31, a return pipe 32, and a heating pipe 33. One end of the heating pipe 33 is connected to the first heat-conducting pipe 222, and the other end is connected to the water return pump 31. Both ends of the return pipe 32 are connected to... The return water pump 31 and the water supply component 221 allow hot water to enter the heating pipe 33 from the first heat conduction pipe 222. The heating pipe 33 provides heating for houses or residential areas. After the hot water cools down, it enters the return pipe 32 from the heating pipe 33. The return water pump 31 delivers water to the water supply component 221, which continues to supply water to the first heat conduction pipe 222 to form a circulation, thereby achieving the technical effect of circulating water supply. Specifically, the two ends of the first coil 241 and the second coil 242 are respectively connected to the water supply component 221 and the return water component. The first coil 241 and the second coil 242 have the same function as the first heat-conducting pipe 222, but are positioned differently. This improves the working efficiency of the heat-conducting component 22. Specifically, the coil component 24 also includes a connecting pipe 244, which connects to the first coil 241 and the second coil 242. The second coil 242 is connected to the heating pipe 33. Water enters the first coil 241 from the water supply component 221, and then enters the second coil 242 and the heating pipe 33 in sequence through the connecting pipe 244, thereby achieving the technical effect of improving the working efficiency of the heat-conducting component 22.

[0032] Furthermore, the cooling component includes a cooling housing 41, a cooling supply component, an inlet pipe 43, and an outlet pipe 44. The cooling housing 41 is fitted onto the side of the inner housing 1. One end of the inlet pipe 43 and the outlet pipe 44 are connected to the cooling supply component, and the other end of the inlet pipe 43 and the outlet pipe 44 are connected to the cooling housing 41. In this embodiment, a cooling component is added. The function of the cooling component is to reduce the temperature of the inner shell 1. Since the magnetic shaft 21 continuously generates heat during rotation, excessively high temperatures can cause the magnetic shaft 21 to lose its magnetism. When the temperature inside the inner shell 1 is high, the cooling component is needed to cool it down. The cooling component includes a cooling shell 41, a cooling supply component, an inlet pipe 43, and an outlet pipe 44. The cooling shell 41 is fitted onto the side of the inner shell 1, that is, the cooling shell 41 wraps around the side of the inner shell 1. One end of the inlet pipe 43 and the outlet pipe 44 are connected to the cooling supply component, and the other end of the inlet pipe 43 and the outlet pipe 44 are connected to the cooling shell 41. The cooling supply component supplies cooling water to the inlet pipe 43. The cooling water enters the cavity between the inner shell 1 and the cooling shell 41 to cool the inner shell 1, and then exits from the outlet pipe 44. Water pipe 44 returns to the cooling supply component. Specifically, the cooling supply component includes a cooling tank 421 and a cooling pump 422. The cooling pump 422 is installed on the cooling tank 421, and the inlet pipe 43 is connected to the cooling pump 422. The cooling pump 422 delivers cooling water through the inlet pipe 43 to the cavity between the inner shell 1 and the cooling shell 41 to cool the inner shell 1. Then, the water returns to the cooling tank 421 through the outlet pipe 44, thereby achieving the technical effect of cooling the inner shell 1. Optionally, a cooling fan 422 can be installed on the upper part of the cooling tank 421 to cool the water in the cooling tank 421, thereby achieving the technical effect of quickly reducing the temperature of the cooling water in the cooling tank 421. A base 6 is installed at the lower part of the cooling shell to support the cooling shell 41 and the drive component 23.

[0033] Furthermore, the drive component 23 includes a drive motor 231 and a frequency converter 232. The frequency converter 232 is disposed on the upper part of the drive motor 231, and the output end of the drive motor 231 is connected to the magnetic shaft 21. In this embodiment, the drive component 23 is further defined. The drive motor 231 can drive the magnetic shaft 21 to rotate around its axis when energized. The frequency converter 232 is a frequency converter, which can change the rotation speed and rotation frequency of the magnetic shaft 21, thereby achieving the technical effect of adjusting the rotation speed of the magnetic shaft 21.

[0034] Furthermore, temperature detectors are connected to the inner housing 1 and the cooling housing 41 respectively. In this embodiment, temperature detectors are added to monitor the temperature inside the inner housing 1 and the cooling housing 41 in real time. That is, there are two temperature detectors: a first detector 51 and a second detector 52. The first detector 51 is installed on the inner housing 1, and one end of the first detector 51 passes through the cooling housing 41 and extends into the inner housing 1, thereby facilitating real-time monitoring of the temperature inside the inner housing 1. The second detector is installed on the cooling housing 41 and can monitor the temperature inside the cooling housing 41 in real time.

[0035] The above description is merely a specific embodiment of the present invention, but the scope of protection of the present invention is not limited thereto. Any variations or substitutions that can be easily conceived by those skilled in the art within the technical scope disclosed in the present invention should be included within the scope of protection of the present invention. Therefore, the scope of protection of the present invention should be determined by the scope of the claims.

Claims

1. A eddy current tube magnetic rapid heating device, characterized in that, include: Inner shell; The heating element includes a magnetic shaft, a heat-conducting component, and a driving component. The magnetic shaft penetrates the inner shell. The heat-conducting component includes a water supply component and a first heat-conducting pipe. The water supply component is connected to the first heat-conducting pipe, which is arranged around the outer periphery of the magnetic shaft. The driving component is connected to one end of the magnetic shaft. The heating element also includes a coil component, which is disposed on the inner sides of both ends of the inner shell. The coil component has a first cavity through which the magnetic shaft passes. The coil component is an annular coil structure, including a first coil and a second coil. The first coil is disposed on one side of the inner shell, and the second coil is disposed on the other side of the inner shell. A cooling component, comprising a cooling housing, a cooling supply component, an inlet pipe, and an outlet pipe, wherein the cooling housing is fitted onto the side of the inner housing, one end of the inlet pipe and the outlet pipe is connected to the cooling supply component, and the other end of the inlet pipe and the outlet pipe is connected to the cooling housing.

2. The eddy current tube magnetic rapid heating device according to claim 1, characterized in that, The surface of the magnetic shaft has a first groove.

3. The eddy current tube magnetic rapid heating device according to claim 2, characterized in that, The first groove is spirally arranged around the outer periphery of the magnetic shaft.

4. The eddy current tube magnetic rapid heating device according to claim 1, characterized in that, The heat-conducting component also includes a water return component, with the two ends of the first heat-conducting pipe connected to the water supply component and the water return component respectively, and the water return component connected to the water supply component.

5. The eddy current tube magnetic rapid heating device according to claim 4, characterized in that, The first coil and the second coil are respectively connected at both ends to the water supply component and the water return component.

6. The eddy current tube magnetic rapid heating device according to any one of claims 1 to 5, characterized in that, The driving component includes a drive motor and a frequency converter. The frequency converter is disposed on the upper part of the drive motor, and the output end of the drive motor is connected to the magnetic shaft.

7. The eddy current tube magnetic rapid heating device according to claim 1, characterized in that, Also includes: A temperature detector is connected to both the inner housing and the cooling housing.