CN210042284U - Magnetic energy heating device - Google Patents

Abstract

The utility model relates to a magnetic energy heating device belongs to electromagnetic heating technical field, magnetic energy heating device include coil, thermal insulation material layer, terminal, magnetic energy heating pipe, the outer wall of magnetic energy heating pipe on be provided with the thermal insulation material layer, the winding has the coil on the magnetic energy heating pipe of thermal insulation material layer parcel, the both ends of coil are provided with a terminal respectively. The utility model has the advantages of simple structure, higher thermal efficiency, strong expandability, convenient connection with an intelligent control system, wide application and suitability for providing heat sources in various fields; meanwhile, the method has the advantages of high safety, emission reduction, energy conservation and emission reduction, can meet various use scenes, and can meet the sustainable development requirements of safety, high efficiency and low emission.

Description

Magnetic energy heating device

Technical Field

The utility model belongs to the technical field of electromagnetic heating, specifically speaking relates to a magnetic energy heating device.

Background

In industrial production and life processes, heat energy is mostly needed to be provided, the current heat source providing modes generally include coal, oil, natural gas, biomass, electric energy, solar energy and the like, and particularly, coal, oil and natural gas are used mostly, but all of the heat sources belong to non-renewable resources, and a large amount of emission is generated in the using process, so that the environment is greatly influenced.

With more and more clean energy sources, the application range of electric energy is more and more extensive, but at present, the electric energy heating mode is mainly an electric heating rod, and electromagnetic heating is mainly used for household or industrial high-frequency instantaneous heating. However, the method of high-power magnetic energy continuous heating in industrial use is not available, and meanwhile, in industrial use, high-temperature and high-pressure fluid is generally required to transfer heat.

Based on the above existing circumstances, there is a need for a device using magnetic energy for heating, which can provide continuous large heat through electromagnetic heating, meet various use scenarios, and realize sustainable development with safety, high efficiency and low emission.

Disclosure of Invention

In order to overcome the problems existing in the background technology, the utility model provides a magnetic energy heating device, which has the advantages of simple structure, higher thermal efficiency, strong expandability, convenient connection with an intelligent control system, wide application and suitability for providing heat sources in multiple fields; meanwhile, the method has the advantages of high safety, emission reduction, energy conservation and emission reduction, can meet various use scenes, and can meet the sustainable development requirements of safety, high efficiency and low emission.

In order to achieve the above purpose, the utility model is realized by the following technical scheme:

the magnetic energy heating device comprises a coil 1, a heat insulation material layer 2, binding posts 4 and a magnetic energy heating pipe 5, wherein the heat insulation material layer 2 is arranged on the outer wall of the magnetic energy heating pipe 5, the magnetic energy heating pipe 5 wrapped by the heat insulation material layer 2 is wound with the coil 1, and two ends of the coil 1 are respectively provided with one binding post 4.

Further, the inner wall of the magnetic energy heating pipe 5 is uniformly provided with protrusions 501, and a groove is formed between two adjacent protrusions 501.

Further, two ends of the magnetic energy heating pipe 5 are respectively welded with a flange 3, and the flange 3 is uniformly provided with connecting screw holes 301 along the circumferential direction.

Furthermore, a semicircular groove with the depth of 3mm and the width of 5mm is arranged on the end surface of the flange plate 3; a high-temperature and high-pressure resistant sealing ring 302 matched with the semicircular groove is arranged in the semicircular groove.

Further, the heat insulating material layer 2 includes a high temperature resistant material layer 201, a heat insulating material layer 202, and an insulating material layer 203, where the high temperature resistant material layer 201 is located at the innermost layer and contacts with the outer wall of the magnetic energy heating pipe 5, the heat insulating material layer 202 is located outside the high temperature resistant material layer 201, and the insulating material layer 203 is located outside the heat insulating material layer 202.

The utility model has the advantages that:

the utility model has the advantages of simple structure, higher thermal efficiency, strong expandability, convenient connection with an intelligent control system, wide application and suitability for providing heat sources in various fields; meanwhile, the method has the advantages of high safety, emission reduction, energy conservation and emission reduction, can meet various use scenes, and can meet the sustainable development requirements of safety, high efficiency and low emission.

Drawings

Fig. 1 is a schematic structural view of the present invention;

fig. 2 is a schematic end-face structure diagram of the present invention;

fig. 3 is a schematic diagram of the middle section structure of the present invention.

In the figure, 1-coil, 2-heat insulation material layer, 201-high temperature resistant material layer, 202-heat insulation material layer, 203-insulating material layer, 3-flange plate, 301-connecting screw hole, 4-binding post, 5-magnetic energy heating pipe and 501-bulge.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention clearer, the following will explain in detail a preferred embodiment of the present invention with reference to the accompanying drawings to facilitate understanding of the skilled person.

As shown in fig. 1-3, the magnetic energy heating device includes a coil 1, a thermal insulation material layer 2, a binding post 4, and a magnetic energy heating pipe 5, wherein the magnetic energy heating pipe 5 is made of cast iron, the magnetic energy heating pipe 5 has a length of 50cm, the magnetic energy heating pipe 5 has an outer diameter of 10cm, the magnetic energy heating pipe 5 has a pipe wall thickness of 3cm, protrusions 501 are uniformly distributed on the inner wall of the magnetic energy heating pipe 5, a groove is formed between two adjacent protrusions 501, the depth of the groove is 1cm, and the width of the root of the groove is 1 cm; the grooves are formed in the inner wall of the magnetic energy heating pipe 5, so that heat conducting liquid or heat conducting gas can be guided to flow in an accelerated manner, meanwhile, the contact area between the inner wall and the heat conducting liquid or the heat conducting gas is increased, and heat on the magnetic energy heating pipe 5 can be quickly transferred to the heat conducting liquid or the heat conducting gas. The magnetic energy heating pipe is characterized in that a heat insulation material layer 2 is arranged on the outer wall of the magnetic energy heating pipe 5, the heat insulation material layer 2 comprises a high temperature resistant material layer 201, a heat insulation material layer 202 and an insulation material layer 203, the high temperature resistant material layer 201 is located on the innermost layer and is in contact with the outer wall of the magnetic energy heating pipe 5, and the thickness of the high temperature resistant material layer 201 is 0.3 cm; the outer side of the high-temperature resistant material layer 201 is provided with a heat insulation material layer 202, and the thickness of the heat insulation material layer is 0.5 cm; the outer side of the insulating material layer 202 is an insulating material layer 203, and the thickness of the insulating material layer is 0.2 cm. By arranging the high-temperature-resistant material layer 201, the heat-insulating material layer 202 and the insulating material layer 203 with different thicknesses, the heat in the magnetic energy heating pipe 5 is not transmitted outside, and meanwhile, safety accidents caused by the transmission of current through the magnetic energy heating pipe 5 can be prevented. A coil 1 is wound on a magnetic energy heating pipe 5 wrapped by the heat insulation material layer 2, the heat insulation material layer 203 is in contact with the coil 1, two terminals 4 are respectively arranged at two ends of the coil 1, and the wire diameter of the coil 1 is 16 mm; the maximum heating power of the coil 1 is 20 KW; the binding posts 4 at the two ends of the coil 1 can be respectively connected into a magnetic energy control system to realize intelligent control.

The two ends of the magnetic energy heating pipe 5 are respectively welded with the flange plate 3, the diameter of the flange plate 3 is 20cm, the flange plate 3 is uniformly provided with connecting screw holes 301 with the aperture of 8mm along the circumferential direction, the connecting screw holes 301 are connected with other devices through screws, the magnetic energy heating pipe is convenient to disassemble and install, is more convenient and quicker to maintain, has stronger expansibility, and can realize the connection between the magnetic energy heating pipe 5 and the magnetic energy heating pipe 5 according to the heat supply requirement, thereby realizing the heating of the multistage magnetic energy heating pipe 5. A semicircular groove with the depth of 3mm and the width of 5mm is arranged on the end face of the flange plate 3; a high-temperature and high-pressure resistant sealing ring 302 matched with the semicircular groove is arranged in the semicircular groove. When the magnetic energy heating pipe 5 is connected with a pipeline or other devices, the sealing function can be realized through the sealing ring arranged on the flange plate 3, the heat conducting liquid or heat conducting gas in the magnetic energy heating pipe 5 is prevented from leaking, and the sealing ring is resistant to high temperature and high pressure, and is beneficial to prolonging the service life of the magnetic energy heating pipe.

The utility model discloses a working process:

after the magnetic energy heating pipe 5 is connected with a heat supply pipeline or other devices through the flange plates 3 at the two ends, and the coil 1 is connected with a power supply and electrified, the magnetic energy heating pipe 5 starts to generate heat energy under the influence of a magnetic field, so that the magnetic energy heating pipe 5 heats heat-conducting liquid or heat-conducting gas in the magnetic energy heating pipe, and the heat-conducting liquid or the heat-conducting gas enters the devices needing heat supply or other devices needing direct heating through the pipeline.

The utility model has the advantages of simple structure, higher thermal efficiency, strong expandability, convenient connection with an intelligent control system, wide application and suitability for providing heat sources in various fields; meanwhile, the method has the advantages of high safety, emission reduction, energy conservation and emission reduction, can meet various use scenes, and can meet the sustainable development requirements of safety, high efficiency and low emission.

Finally, it is noted that the above-mentioned preferred embodiments illustrate rather than limit the invention, and that, although the invention has been described in detail with reference to the above-mentioned preferred embodiments, it will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the scope of the invention as defined by the appended claims.

Claims (5)

1. A magnetic energy heating device is characterized in that: the magnetic energy heating device comprises a coil (1), a heat insulation material layer (2), binding posts (4) and a magnetic energy heating pipe (5), wherein a heat insulation material layer (2) is arranged on the outer wall of the magnetic energy heating pipe (5), the magnetic energy heating pipe (5) wrapped by the heat insulation material layer (2) is wound with the coil (1), and two ends of the coil (1) are respectively provided with one binding post (4).

2. A magnetic energy heating apparatus according to claim 1, wherein: the inner wall of the magnetic energy heating pipe (5) is uniformly provided with the bulges (501), and a groove is formed between every two adjacent bulges (501).

3. A magnetic energy heating apparatus according to claim 1, wherein: the magnetic energy heating pipe is characterized in that two ends of the magnetic energy heating pipe (5) are respectively welded with a flange plate (3), and the flange plate (3) is uniformly provided with connecting screw holes (301) along the circumferential direction.

4. A magnetic energy heating apparatus according to claim 3, wherein: a semicircular groove with the depth of 3mm and the width of 5mm is formed in the end face of the flange plate (3); a high-temperature and high-pressure resistant sealing ring (302) matched with the semicircular groove is arranged in the semicircular groove.

5. A magnetic energy heating apparatus as claimed in any one of claims 1 to 4, wherein: the heat insulation material layer (2) comprises a high temperature resistant material layer (201), a heat insulation material layer (202) and an insulation material layer (203), wherein the high temperature resistant material layer (201) is located at the innermost layer and is in contact with the outer wall of the magnetic energy heating pipe (5), the heat insulation material layer (202) is arranged on the outer side of the high temperature resistant material layer (201), and the insulation material layer (203) is arranged on the outer side of the heat insulation material layer (202).

Images