CN218972755U - Magnetic quick heating device of vortex tube - Google Patents

Magnetic quick heating device of vortex tube Download PDF

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Publication number
CN218972755U
CN218972755U CN202221859363.7U CN202221859363U CN218972755U CN 218972755 U CN218972755 U CN 218972755U CN 202221859363 U CN202221859363 U CN 202221859363U CN 218972755 U CN218972755 U CN 218972755U
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component
magnetic
water
coil
vortex tube
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CN202221859363.7U
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李朝军
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    • YGENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y02TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
    • Y02BCLIMATE CHANGE MITIGATION TECHNOLOGIES RELATED TO BUILDINGS, e.g. HOUSING, HOUSE APPLIANCES OR RELATED END-USER APPLICATIONS
    • Y02B30/00Energy efficient heating, ventilation or air conditioning [HVAC]

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Abstract

The utility model discloses a magnetic rapid heating device of a vortex tube, relates to the technical field of heating equipment, and mainly aims to provide the magnetic rapid heating device of the vortex tube for heating water through magnetic force. The main technical scheme of the utility model is as follows: a vortex tube magnetic force rapid heating device, comprising: an inner housing; the heating component comprises a magnetic shaft, a heat conduction component and a driving component, wherein 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 with the first heat conduction pipe, the first heat conduction pipe is arranged on the outer peripheral side of the magnetic shaft in a surrounding mode, and the driving component is connected with one end of the magnetic shaft. The utility model is mainly used for heating.

Description

Magnetic quick heating device of vortex tube
Technical Field
The utility model relates to the technical field of heating equipment, in particular to a magnetic rapid heating device of a vortex tube.
Background
In the heating equipment in north, most adopt the mode of centralized water heating to the residential area, thereby burn the fuel through the boiler and heat water, with hot water through the pipeline transportation to the residential area heating to guarantee the temperature in the house, current public grant patent CN201010621624.7 magnetic induction heating method and isolated plant mainly comprises cylindrical staving, and staving both ends are provided with the bung, are provided with water inlet and delivery port on the staving, its characterized in that: a rotating shaft is arranged between the two barrel covers through a rolling bearing, and the rotating shaft is driven by an external motor; a metal turbine with a spiral groove is arranged on the rotating shaft, the front surface of the metal turbine is covered with a metal clamping plate A, and the back surface of the metal turbine is covered with a metal clamping plate B; a water hole communicated with the spiral groove is formed in the metal clamping plate A, and a water seal is arranged between the outer end part of the metal clamping plate A and the barrel body; the water inlet is positioned at one side of the metal clamping plate A, and the water outlet is positioned at one side of the metal clamping plate B; permanent magnets are correspondingly arranged on the two barrel covers at the periphery of the rotating shaft, and an eddy current effect is generated in the metal body through magnetic induction, so that the metal body heats; the fluid medium such as water passes through the metal body which generates heat, high-temperature hot water or hot vapor is generated through heat exchange, and heat energy is output, but because the motor needs to drive the metal plate with larger mass and the rotating shaft to rotate around the axis of the metal plate, the energy consumption of the motor is larger, and the contact area of the metal plate and the water is smaller, so that the heat exchange efficiency of the metal plate and the water is reduced.
Disclosure of Invention
Therefore, the embodiment of the utility model provides a magnetic rapid heating device for a vortex tube, and mainly aims to provide the magnetic rapid heating device for the vortex tube, which is used for heating water through magnetic force.
In order to achieve the above purpose, the present utility model mainly provides the following technical solutions:
the embodiment of the utility model provides a magnetic rapid heating device of a vortex tube, which comprises the following components:
an inner housing;
the heating component comprises a magnetic shaft, a heat conduction component and a driving component, wherein 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 with the first heat conduction pipe, the first heat conduction pipe is arranged on the outer peripheral side of the magnetic shaft in a surrounding mode, and the driving component is connected with one end of the magnetic shaft.
Further, the surface of the magnetic shaft is provided with a first groove.
Further, the first groove is spirally provided around an outer peripheral side of the magnetic shaft.
Further, the heating component further comprises coil components, the coil components are arranged on the inner sides of two ends of the inner shell, the coil components are provided with first cavities, and the magnetic shafts penetrate through the first cavities.
Further, the coil component includes a first coil provided on one end side surface of the inner case and a second coil provided on the other end side surface of the inner case.
Further, the heat conduction component further comprises a water return component, two ends of the first heat conduction pipe are respectively connected with the water supply component and the water return component, and the water return component is connected with the water supply component.
Further, two ends of the first coil pipe and the second coil pipe are respectively connected with the water supply component and the water return component.
Further, the cooling part comprises a cooling shell, a cooling supply part, a water inlet pipe and a water outlet pipe, wherein the cooling shell is sleeved on the side face of the inner shell, one ends of the water inlet pipe and the water outlet pipe are connected with the cooling supply part, and the other ends of the water inlet pipe and the water outlet pipe are connected with the cooling shell.
Further, the driving part comprises a driving motor and a frequency conversion part, the frequency conversion part is arranged on the upper part of the driving motor, and the output end of the driving motor is connected with the magnetic shaft.
Further, temperature detectors are connected to the inner case and the cooling case, respectively.
Compared with the prior art, the utility model has the following technical effects:
in the technical scheme provided by the embodiment of the utility model, the inner shell is used for supporting and wrapping the heating component; the heating component is used for heating water, the heating component comprises 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 on the outer periphery side of the magnetic shaft in a surrounding mode, the driving component is connected to one end of the magnetic shaft, compared with the prior art, the heat is supplied to a residential area in a centralized water heating mode, fuel is combusted through a boiler to heat water, then the hot water is conveyed to the residential area through a pipeline to heat the water, so that the temperature in the house is guaranteed, however, the combustion process of the boiler can cause a large amount of fuel to pollute, and meanwhile, the combustion efficiency of the fuel is lower, so that part of heat of the fuel is wasted.
Drawings
FIG. 1 is a schematic diagram of a first vortex tube magnetic rapid heating device according to an embodiment of the present utility model;
FIG. 2 is a schematic diagram of a second vortex tube magnetic rapid heating device according to an embodiment of the present utility model;
FIG. 3 is a schematic structural diagram of a magnetic shaft according to an embodiment of the present utility model;
fig. 4 is a schematic structural diagram of a coil component according to an embodiment of the present utility model.
Detailed Description
The utility model is described in further detail below with reference to the drawings and examples.
As shown in fig. 1, an embodiment of the present utility model provides a vortex tube magnetic rapid heating device, which includes:
an inner case 1;
the heating part, the heating part includes magnetic shaft 21, heat conduction part 22 and drive part 23, and magnetic shaft 21 runs through inner housing 1, and heat conduction part 22 includes water supply part 221 and first heat pipe 222, and water supply part 221 connects in first heat pipe 222, and first heat pipe 222 encircles the periphery side that sets up at magnetic shaft 21, and drive part 23 connects in one end of magnetic shaft 21.
In the technical scheme provided by the embodiment of the utility model, the inner shell 1 is used for supporting and wrapping the heating component; the heating element is used for heating water, the heating element comprises a magnetic shaft 21, a heat conducting element 22 and a driving element 23, the magnetic shaft 21 penetrates through an inner shell 1, the heat conducting element 22 comprises a water supply element 221 and a first heat conducting tube 222, the water supply element 221 is connected to the first heat conducting tube 222, the first heat conducting tube 222 is arranged on the outer peripheral side of the magnetic shaft 21 in a surrounding mode, the driving element 23 is connected to one end of the magnetic shaft 21, compared with the prior art, the heating element is used for heating residential areas in a concentrated water heating mode, fuel is combusted through a boiler to heat water, then the hot water is conveyed to the residential areas through a pipeline to heat the residential areas, and therefore the temperature in the house is guaranteed, but in the combustion process of the boiler, a large amount of fuel is polluted, meanwhile, the combustion efficiency of the fuel is low, and therefore part of heat of the fuel is wasted.
The inner shell 1 has the functions of supporting and wrapping the heating component, the shell is made of stainless steel materials or aluminum alloy materials, a cavity is formed in the middle of the shell, two through holes are formed in two ends of the shell, and bearings are arranged on the inner sides of the through holes; the heating part is used for heating water, the heating part comprises a magnetic shaft 21, a heat conducting part 22 and a driving part 23, the magnetic shaft 21 penetrates through the inner shell 1, the heat conducting part 22 comprises a water supply part 221 and a first heat conducting pipe 222, the water supply part 221 is connected with the first heat conducting pipe 222, the first heat conducting pipe 222 is arranged on the outer circumference side of the magnetic shaft 21 in a surrounding mode, the driving part 23 is connected with one end of the magnetic shaft 21, the magnetic shaft 21 adopts a cylindrical structure, the side surface of the magnetic shaft 21 is of an N pole and an S pole, specifically, the magnetic shaft 21 takes an axis as a separation line, the upper part is of the N pole, the lower part is of the S pole, the magnetic shaft 21 is of a permanent magnet, the magnetic shaft can be detached, then the magnetic shaft can be magnetized through the existing magnetizing equipment, the magnetic shaft can be repeatedly used, the heat conducting part 22 comprises the water supply part 221 and the first heat conducting pipe 222, the water supply part 221 is connected with the first heat conducting pipe 222, the first heat-conducting pipe 222 is circumferentially arranged on the outer circumferential side of the magnetic shaft 21, the water supply part 221 can adopt the existing water supply equipment, in particular, the water supply part 221 comprises a water supply tank and a water supply pump, the water supply pump is arranged on the water supply tank, the first heat-conducting pipe 222 is connected with the water supply pump, the water supply pump can convey water in the water supply tank into the first heat-conducting pipe 222, the first heat-conducting pipe 222 is spirally circumferentially arranged on the outer circumferential side surface of the magnetic shaft 21, the rotation direction of the first heat-conducting pipe 222 is the same as the rotation direction of the magnetic shaft 21, the first heat-conducting pipe 222 adopts copper materials, the heat conduction performance can be improved, water is introduced into the first heat-conducting pipe 222, the first heat-conducting pipe 222 is not directly contacted with the magnetic shaft 21, the driving part 23 is arranged on the outer side of one end of the inner shell 1, the driving part 23 is connected with one end of the magnetic shaft 21, the magnetic shaft 21 can be driven to rotate around the axis of the magnetic shaft 21, because the magnetic shaft 21 needs a certain rotation speed to enable the first heat conduction pipe 222 to generate heat, the minimum rotation speed of the magnetic shaft 21 is 2800 revolutions per minute.
Further, as shown in fig. 2 and 3, the surface of the magnetic shaft 21 has a first groove 213. In this embodiment, the magnetic shaft 21 is further defined, the first groove 213 is disposed 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 in an integrated structure, two ends of the shaft body 211 extend out of the inner housing 1, one end of the shaft body 211 is connected to the driving component 23, the rotor 212 is disposed inside the inner housing 1, the surface of the rotor 212 has the first groove 213, the first groove 213 is used for improving the heat generating efficiency of the first heat conducting tube 222, specifically, the first groove 213 is spirally disposed on the outer peripheral side of the magnetic shaft 21, and the spiral winding direction is the same as the rotation direction of the rotor 212, which not only can improve the heat generating efficiency of the first heat conducting tube 222, but also can drive the water in the first heat conducting tube 222 to flow along the spiral direction, thereby increasing the flow speed of the water.
Further, as shown in fig. 4, the heat generating component further includes a coil component 24, the coil component 24 being disposed inside both ends of the inner case 1, the coil component 24 having a first cavity 243, the magnetic shaft 21 passing through the first cavity 243. In this embodiment, a coil component 24 is added, the coil component 24 adopts an annular coil structure, specifically, the coil component 24 is formed by coiling copper tubes, a first cavity 243 is formed in the middle of the coil component 24, the magnetic shaft 21 passes through the first cavity 243, and 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 at one end side of the inner housing 1, the second coil 242 is disposed at the other end side of the inner housing 1, water is introduced into the first coil 241 and the second coil 242, and the coil component 24 is heated in the process of rotating the magnetic shaft 21, thereby achieving the technical effect of heating the water in the coil component 24.
Further, the heat conducting member 22 further includes a water return member, two ends of the first heat conducting pipe 222 are respectively connected to the water supply member 221 and the water return member, and the water return member is connected to the water supply member 221. In summary of this embodiment, a water return component is added, the water return component is used to convey cooled water to the water supply component 221 through the water return component, after the water is heated in the first heat conducting pipe 222, hot water is conveyed to the residential area through a pipeline, after the hot water is cooled by heat dissipation, the cooled water enters the water supply component 221, specifically, the water return component includes a water return pump 31, a return pipeline 32 and a heat supply pipeline 33, one end of the heat supply pipeline 33 is connected to the first heat conducting pipe 222, the other end is connected to the water return pump 31, two ends of the return pipeline 32 are connected to the water return pump 31 and the water supply component 221, hot water enters the heat supply pipeline 33 from the heat supply pipeline 33 after the hot water is cooled, the water return pump 31 conveys the water into the water supply component 221, the water supply component 221 continues to supply water to the first heat conducting pipe 222 to form a circulation, and thus the technical effects of circulating water are achieved, specifically, two ends of the first coil 241 and the second coil 242 are respectively connected to the water supply component 221 and the water return component 221. The first coil 241, the second coil 242 and the first heat pipe 222 have the same functions and different positions, so that the working efficiency of the heat conducting component 22 can be improved, specifically, the coil component 24 further comprises a connecting pipeline 243, the connecting pipeline 243 is connected to the first coil 241 and the second coil 242, the second coil 242 is connected to the heat supply pipeline 33, water enters the first coil 241 from the water supply component 221, and then sequentially enters the second coil 242 and the heat supply pipeline 33 through the connecting pipeline 243, thereby achieving the technical effect of improving the working efficiency of the heat conducting component 22.
Further, the cooling part comprises a cooling shell 41, a cooling supply part, a water inlet pipe 43 and a water outlet pipe 44, wherein the cooling shell 41 is sleeved on the side surface of the inner shell 1, one ends of the water inlet pipe 43 and the water outlet pipe 44 are connected with the cooling supply part, and the other ends of the water inlet pipe 43 and the water outlet pipe 44 are connected with the cooling shell 41. In this embodiment, cooling components are added, the cooling components are used for reducing the temperature of the inner housing 1, as the magnetic shaft 21 continuously generates heat in the process of rotation, the magnetic shaft 21 loses magnetism due to the fact that the temperature is too high, when the temperature in the inner housing 1 is high, the cooling components are required to cool the inner housing 1, the cooling components comprise a cooling housing 41, a cooling supply component, a water inlet pipe 43 and a water outlet pipe 44, the cooling housing 41 is sleeved on the side surface of the inner housing 1, that is, the cooling housing 41 is wrapped on the side surface of the inner housing 1, one ends of the water inlet pipe 43 and the water outlet pipe 44 are connected to the cooling supply component, the other ends of the water inlet pipe 43 and the water outlet pipe 44 are connected to the cooling housing 41, the cooling supply component supplies cooling water to the water inlet pipe 43, the cooling water enters a cavity between the inner housing 1 and the cooling housing 41, the inner housing 1 is cooled down, and then returns to the cooling supply component from the water outlet pipe 44, and concretely, the cooling supply component comprises a cooling tank 421 and a cooling pump 422, the cooling pump 422 is arranged on the cooling tank 421, the water inlet pipe 43 is connected to the cooling pump 422, the cooling housing 41 is conveyed in the cavity between the inner housing 1 and the cooling housing 41 through the cooling tank 41, one end of the cooling housing 41 is connected to the cooling pump 422, and then the cooling water is cooled down from the cooling tank 421 to the cooling tank 421, and the cooling supply component is cooled down in the cooling tank 1, and the cooling tank is further cooled down through the cooling tank 421, and the cooling pump is cooled down in the cooling tank is cooled down, and the cooling tank is cooled down part is cooled down by the cooling tank and cooled down, and the cooling pump is further cooled down in the cooling tank 1, and the cooling tank is cooled down temperature is cooled down by the cooling tank 1 and the cooling tank is cooled down in the cooling tank 1 and the cooling temperature is cooled down.
Further, the driving part 23 includes a driving motor 231 and a frequency conversion part 232, the frequency conversion part 232 is disposed at the upper part of the driving motor 231, and the output end of the driving motor 231 is connected to the magnetic shaft 21. In this embodiment, the driving component 23 is further defined, the driving motor 231 can drive the magnetic shaft 21 to rotate around its axis in the energized state, the frequency conversion component 232 adopts a frequency converter, and the frequency converter can change the rotation speed and rotation frequency of the magnetic shaft 21, so as to achieve the technical effect of adjusting the rotation speed of the magnetic shaft 21.
Further, temperature detectors are connected to the inner case 1 and the cooling case 41, respectively. In this embodiment, temperature detectors are added, and the temperature detectors are used for monitoring the temperatures inside the inner housing 1 and the cooling housing 41 in real time, that is, two temperature detectors are respectively a first detector 51 and a second detector 52, the first detector 51 is arranged on the inner housing 1, one end of the first detector 51 passes through the cooling housing 41 and stretches into the inner housing 1, so that the effect of conveniently monitoring the temperature inside the inner housing 1 in real time is achieved, and the second detector is arranged on the cooling housing 41 and can monitor the temperature inside the cooling housing 41 in real time.
The foregoing is merely illustrative of the present utility model, and the present utility model is not limited thereto, and any person skilled in the art will readily recognize that variations or substitutions are within the scope of the present utility model. Therefore, the protection scope of the present utility model shall be subject to the protection scope of the claims.

Claims (10)

1. A vortex tube magnetic force rapid heating device, which is characterized by comprising:
an inner housing;
the heating component comprises a magnetic shaft, a heat conduction component and a driving component, wherein 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 with the first heat conduction pipe, the first heat conduction pipe is arranged on the outer peripheral side of the magnetic shaft in a surrounding mode, and the driving component is connected with one end of the magnetic shaft.
2. The vortex tube magnetic rapid heating device according to claim 1, wherein,
the surface of the magnetic shaft is provided with a first groove.
3. The vortex tube magnetic rapid heating device according to claim 2, wherein,
the first groove is spirally disposed around an outer peripheral side of the magnetic shaft.
4. The vortex tube magnetic rapid heating device according to claim 1, wherein,
the heating component further comprises coil components, the coil components are arranged on the inner sides of two ends of the inner shell, the coil components are provided with first cavities, and the magnetic shafts penetrate through the first cavities.
5. The vortex tube magnetic rapid heating device according to claim 4, wherein,
the coil component comprises a first coil and a second coil, wherein the first coil is arranged on one end side surface of the inner shell, and the second coil is arranged on the other end side surface of the inner shell.
6. The vortex tube magnetic rapid heating device according to claim 5, wherein,
the heat conduction component further comprises a water return component, two ends of the first heat conduction pipe are respectively connected with the water supply component and the water return component, and the water return component is connected with the water supply component.
7. The vortex tube magnetic rapid heating device according to claim 6, wherein,
and two ends of the first coil pipe and the second coil pipe are respectively connected with the water supply component and the water return component.
8. The vortex tube magnetic boost heating apparatus of any one of claims 1 to 7, further comprising:
the cooling component comprises a cooling shell, a cooling supply component, a water inlet pipe and a water outlet pipe, wherein the cooling shell is sleeved on the side face of the inner shell, one ends of the water inlet pipe and the water outlet pipe are connected with the cooling supply component, and the other ends of the water inlet pipe and the water outlet pipe are connected with the cooling shell.
9. The vortex tube magnetic rapid heating apparatus according to any one of claims 1 to 7, wherein,
the driving part comprises a driving motor and a frequency conversion part, the frequency conversion part is arranged on the upper part of the driving motor, and the output end of the driving motor is connected with the magnetic shaft.
10. The vortex tube magnetic boost heating apparatus of claim 8, further comprising:
and the temperature detectors are respectively connected with the inner shell and the cooling shell.
CN202221859363.7U 2022-07-19 2022-07-19 Magnetic quick heating device of vortex tube Active CN218972755U (en)

Priority Applications (1)

Application Number Priority Date Filing Date Title
CN202221859363.7U CN218972755U (en) 2022-07-19 2022-07-19 Magnetic quick heating device of vortex tube

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
CN202221859363.7U CN218972755U (en) 2022-07-19 2022-07-19 Magnetic quick heating device of vortex tube

Publications (1)

Publication Number Publication Date
CN218972755U true CN218972755U (en) 2023-05-05

Family

ID=86147510

Family Applications (1)

Application Number Title Priority Date Filing Date
CN202221859363.7U Active CN218972755U (en) 2022-07-19 2022-07-19 Magnetic quick heating device of vortex tube

Country Status (1)

Country Link
CN (1) CN218972755U (en)

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