KR102164025B1 - Magnetic injury device that increases efficiency by increasing liquid nitrogen immersion time of superconductor - Google Patents

Abstract

The present invention relates to a magnetic levitation device in which efficiency is increased by increasing the immersion time of liquid nitrogen of a superconductor. In more detail, the inside of the carrier is composed of a lattice structure, and liquid nitrogen flow holes are provided on one side of the lattice structure for each layer, so that the liquid nitrogen filled so that the superconductor is submerged at the bottom of the carrier is twisted and inclined. Even in movement, only the liquid nitrogen flow hole of the layer formed inside the carrier flows, and the layer formed inside the carrier is a multi-layered lattice structure, increasing the time for the superconductor to immerse in the liquid nitrogen to increase efficiency, and by providing an air gap, the external A superconductor that performs a thermal insulation function that prevents the heat from being transferred to the liquid nitrogen inside the carrier to further suppress the evaporation of liquid nitrogen, thereby increasing the time for the superconductor to immerse in the liquid nitrogen to enable a longer operation. It relates to a magnetic levitation device that increases the efficiency by increasing the immersion time of liquid nitrogen.
To this end, the present invention includes a track including a portion twisted into a curved surface; A plurality of magnets alternately and continuously arranged so that different polarities are expressed on the upper and lower surfaces of the track; Located on the top of the magnet installed on the track, the inside is separated into a plurality of layers, each layer is formed in a lattice structure, and liquid nitrogen is filled inside, and an air gap is formed between the outer surface and the inner surface formed in a lattice structure. Carrier; And a carrier cover that covers the upper surface of the carrier to seal the inside of the carrier filled with liquid nitrogen, and has a pressure drop hole formed in the center of the carrier to reduce the pressure inside the carrier. Provide the device.

Description

Magnetic injury device that increases efficiency by increasing liquid nitrogen immersion time of superconductor}

The present invention relates to a magnetic levitation device in which efficiency is increased by increasing the immersion time of liquid nitrogen of a superconductor. In more detail, the inside of the carrier is composed of a lattice structure, and liquid nitrogen flow holes are provided on one side of the lattice structure for each layer, so that the liquid nitrogen filled so that the superconductor is submerged at the bottom of the carrier is twisted and inclined. Even in movement, only the liquid nitrogen flow hole of the layer formed inside the carrier flows, and the layer formed inside the carrier is a multi-layered lattice structure, increasing the time for the superconductor to immerse in the liquid nitrogen to increase efficiency, and by providing an air gap, the external A superconductor that performs a thermal insulation function that prevents the heat from being transferred to the liquid nitrogen inside the carrier to further suppress the evaporation of liquid nitrogen, thereby increasing the time for the superconductor to immerse in the liquid nitrogen to enable a longer operation. It relates to a magnetic levitation device that increases the efficiency by increasing the immersion time of liquid nitrogen.

The technology for magnetic levitation using superconductors is briefly summarized. It is a technology that allows magnetic levitation by introducing a superconductor and liquid nitrogen on a rail made of magnets. High-speed driving is possible through the non-resistance property of the superconductor. Research is ongoing.

However, unlike people's increasing interest in magnetic levitation, as the structure is complex, the development of educational systems and practical technologies to make the principle easier for children, students, and the general public to understand is in fact insufficient.

In particular, for high-efficiency operation in which magnetic levitation objects move stably for a longer period of time in the construction of a magnetic levitation system, liquid nitrogen is used to induce a superconducting magnetic levitation effect, as well as by submerging the superconductor in the liquid nitrogen. A storage container is essential, and the need to develop a technology for a structure that suppresses the rapid evaporation of liquid nitrogen as much as possible even when the container (carrier) is operated in an inclined manner or vertically reversed.

Prior art literature: KR Patent Publication No. 0629277 (2006.9.29 announcement)

The present invention has been conceived to solve the above problems, and provides a magnetic levitation device that increases efficiency by increasing the immersion time of liquefied nitrogen of a superconductor, which suppresses rapid evaporation of liquefied nitrogen as much as possible even during inclined operation of a carrier and vertically inverted operation. It has its purpose to provide.

In order to achieve the above object, the magnetic levitation device in which the efficiency is increased by increasing the immersion time of liquid nitrogen of the superconductor according to the present invention comprises: a track including a curved portion; A plurality of magnets alternately and continuously arranged so that different polarities are expressed on the upper and lower surfaces of the track; Located on the top of the magnet installed on the track, the inside is separated into a plurality of layers, each layer is formed in a lattice structure, and liquid nitrogen is filled inside, and an air gap is formed between the outer surface and the inner surface formed in a lattice structure. Carrier; And a carrier cover having a pressure drop hole formed in the center of the carrier to seal the inside of the carrier filled with liquid nitrogen by covering the upper surface of the carrier.

In addition, the carrier further includes at least one liquid nitrogen flow hole formed in each space separated by a lattice structure in the layer formed inside the carrier, and the liquid nitrogen flow hole formed in the lattice structure when liquid nitrogen is injected into the carrier. The superconductor is submerged in the liquid nitrogen by flowing to the lower layer through the liquid nitrogen, and when the carrier is tilted due to the twisted curved track, the liquid nitrogen flows to the upper layer through the liquid nitrogen flow hole. It may include letting go.

In addition, the lower portion of the carrier facing the magnet may further include a superconductor slot including a superconductor space through which one or more superconductors can be introduced or drawn out.

According to the present invention, the inside of the carrier is composed of a lattice structure, and liquid nitrogen flow holes are provided on one side of the lattice structure for each layer, so that the liquid nitrogen filled so that the superconductor is immersed in the bottom of the carrier is twisted and inclined. Even in movement, only the liquid nitrogen flow hole of the layer formed inside the carrier flows, and the layer formed inside the carrier is a multi-layered lattice structure, so it is effective to increase the efficiency by increasing the time for the superconductor to immerse in the liquid nitrogen.

In addition, according to the present invention, by providing an air gap, the superconductor is submerged in the liquid nitrogen by performing an adiabatic function that first prevents the transfer of external heat to the liquid nitrogen inside the carrier to further suppress the evaporation of liquid nitrogen. It is effective in increasing the time required to allow longer hours of operation.

1 is a photograph of a magnetic levitation device in which efficiency is increased by increasing the immersion time of liquid nitrogen in a superconductor according to a preferred embodiment of the present invention.
2 is a perspective view of a track according to a preferred embodiment of the present invention,
3 is a view showing a carrier and a carrier cover according to a preferred embodiment of the present invention, and
4 is an interior view of a carrier according to a preferred embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. First of all, in adding reference numerals to elements of each drawing, it should be noted that the same elements have the same numerals as possible, even if they are indicated on different drawings. In addition, in describing the present invention, if it is determined that a detailed description of a related known configuration or function may obscure the subject matter of the present invention, a detailed description thereof will be omitted. In addition, a preferred embodiment of the present invention will be described below, but the technical idea of the present invention is not limited thereto or is not limited thereto, and may be modified and variously implemented by a person skilled in the art.

The present invention relates to a magnetic levitation device 100 that increases efficiency by increasing the immersion time of liquid nitrogen of a superconductor. More specifically, the inside of the carrier 50 is composed of a lattice structure 51, and each layer is provided with a liquid nitrogen flow hole 52 on one side of the lattice structure 51, so that the carrier 50 The liquid nitrogen filled so that the superconductor is submerged flows only through the liquid nitrogen flow hole 52 of the layer formed inside the carrier 50 even when the carrier 50 is twisted and inclined, and the layer formed inside the carrier 50 is The multi-layered lattice structure 51 increases efficiency by increasing the time the superconductor is immersed in liquid nitrogen, and the air gap 53 prevents external heat from being transferred to the liquid nitrogen inside the carrier 50. Magnetic levitation that increases efficiency by increasing the immersion time of liquefied nitrogen of a superconductor so that the superconductor can be operated for a longer time by increasing the time for the superconductor to be immersed in liquid nitrogen by performing an insulation function to prevent tea It relates to the device 100.

1 is a photograph of a magnetic levitation apparatus 100 that increases efficiency by increasing the immersion time of liquid nitrogen of a superconductor according to a preferred embodiment of the present invention, and FIG. 2 is a perspective view of a track 10 according to a preferred embodiment of the present invention. 3 is a view showing the carrier 50 and the carrier cover 60 according to a preferred embodiment of the present invention, Figure 4 is an interior view of the carrier 50 according to the preferred embodiment of the present invention.

1 to 3, the magnetic levitation device 100, which increases efficiency by increasing the immersion time of liquid nitrogen in a superconductor according to a preferred embodiment of the present invention, is a technology related to magnetic levitation, and is a rail made of a magnet 20. The superconductor immersed in liquid nitrogen on the phase was focused on allowing magnetic levitation, and the container (carrier 50) containing the liquid nitrogen and the superconductor was focused on allowing sufficient injury and strong repulsion. (10), a magnet 20, a track connection part 30, a support part 40, a carrier 50, a carrier cover 60, and a superconductor slot 70, and will be described in detail from the track 10 To

Referring to FIG. 2, the track 10 includes a portion twisted into a curved surface in the shape of a Mobius strip, and magnets 20 are alternately arranged in a row so that different polarities are expressed on the other side opposite to one side. It is manufactured separately for each section so that they can be assembled together.

2, the locking jaw 15 is fixed to the locking jaw 20 so as to extend in each longitudinal direction to one side and the other side of the track 10 on which the magnet 20 is located to cover the magnet 20, and When attaching, it is preferable to connect the tracks 10 with the track connection part 30 by inserting the magnet 20 below the locking jaw 15 in the separately manufactured track 10.

The magnets 20 are arranged alternately and continuously so that different polarities are expressed on the upper and lower surfaces of the track 10.

In particular, the magnet 20 of the present invention includes a portion where the track 10 is twisted, so that the carrier 50 is close to a specific surface (upper surface or lower surface) of the track. ) It is preferable to place it on the upper and lower surfaces.

Referring to FIG. 2, the track connection part 30 is formed in a vertical direction at one end and the other end where the magnet 20 is not installed in the track 10, and a through hole is formed in the center of the track 10 and the track 10. ), and fastening the fastening member with a through hole so that the tracks 10 can be fixed.

Referring to FIG. 2, when the through hole formed on one side of the support part 40 is formed at a position corresponding to the through hole of the track connecting part 30, the fastening member may be fastened with the through hole to be fixed to the track 10, The other side is in contact with the ground to support the track 10.

3 to 4, the carrier 50 includes a lattice structure 51 therein, and includes a liquid nitrogen flow hole 52 and an air gap 53, hereinafter, the carrier 50 And the configuration of the carrier 50 will be described in detail.

The carrier 50 is located on the top of the magnet 20 installed on the track 10 in a hexahedral shape, the inside is separated into a plurality of layers, each layer is formed in a lattice structure 51, therein liquid nitrogen Is filled, and an air gap 53 is formed between the outer surface and the inner surface formed of the lattice structure 51.

In addition, the layer formed inside the carrier 50 is characterized in that at least one liquid nitrogen flow hole 52 is formed for each space separated by a lattice structure 51 to communicate with other layers.

In addition, when the liquid nitrogen is injected into the carrier 50, the liquid nitrogen flows to the lower layer through the liquid nitrogen flow holes 52 formed in the lattice structure 51 to submerge the superconductor.

In particular, the superconductor inside the carrier 50 generates magnetic force with liquid nitrogen filled in the carrier 50 within a specific temperature range, so that the carrier 50 in which the superconductor is embedded moves along the track 10, but the carrier 50 ) Is inclined to a curved surface of a twisted shape formed on the track 10, the liquid nitrogen filled inside flows to the upper layer only through the liquid nitrogen flow hole 52 of the layer formed inside the carrier 50, and the carrier ( 50) The internal layer is composed of multiple layers, and as the time for the superconductor to be immersed in liquid nitrogen increases, the operation time increases and the efficiency increases.

In addition, as the air gap 53 formed inside the carrier 50 performs an insulating function that prevents the transfer of external heat to the liquid nitrogen inside the carrier 50, it is necessary to maintain a cryogenic temperature. It has the advantage of preventing the evaporation of liquid nitrogen by blocking direct heat transfer, and increasing the efficiency by increasing the time the superconductor is immersed in the liquid nitrogen.

Referring to FIG. 4, the carrier cover 60 covers the upper surface of the carrier 50 to seal the inside of the carrier 50 filled with liquid nitrogen, and decreases the pressure inside the carrier 50 at the center, thereby reducing pressure inside the carrier. A pressure drop hole 61 is formed to prevent it from being charged.

Referring to FIG. 4, the superconductor slot 70 includes a superconductor space <not shown> in which a superconductor can be inserted or extracted under the carrier 50 facing the magnet 20.

In addition, the superconductor slot 70 includes the superconductor slot cover 71, and allows the superconductor space to be introduced into the superconductor to be opened or closed, thereby enabling the superconductor to be easily replaced.

The above description is merely illustrative of the technical idea of the present invention, and those of ordinary skill in the technical field to which the present invention belongs can make various modifications, changes, and substitutions within the scope not departing from the essential characteristics of the present invention. will be. Accordingly, the embodiments disclosed in the present invention and the accompanying drawings are not intended to limit the technical idea of the present invention, but to explain, and the scope of the technical idea of the present invention is not limited by these embodiments and the accompanying drawings. . The scope of protection of the present invention should be interpreted by the following claims, and all technical ideas within the scope equivalent thereto should be interpreted as being included in the scope of the present invention.

10-track
15-jammed jaw
20-magnet
30-track connection
40-support
50-carrier
51-lattice structure
52-Liquid nitrogen flow hole
53-Air Gap
60-carrier cover
61-Pressure drop hole
70-Superconductor slot
71-Superconductor slot cover
100-Magnetic levitation device that increases efficiency by increasing the immersion time of liquid nitrogen in superconductors

Claims (3)

A track including a portion twisted into a curved surface;
A plurality of magnets alternately and continuously arranged so that different polarities are expressed on the upper and lower surfaces of the track;
Located on the top of the magnet installed on the track, the inside is separated into a plurality of layers, each layer is formed in a lattice structure, and liquid nitrogen is filled inside, and an air gap is formed between the outer surface and the inner surface formed in a lattice structure. Carrier; And
Carrier cover with a pressure drop hole formed in the center of the carrier to seal the inside of the carrier filled with liquid nitrogen by covering the upper surface of the carrier.
Magnetic levitation device with increased efficiency by increasing the immersion time of liquid nitrogen of the superconductor comprising a. According to claim 1
Carrier
At least one liquid nitrogen flow hole is formed for each space separated by a lattice structure.
Including more,
When liquid nitrogen is injected into the carrier, liquid nitrogen flows to the lower layer through the liquid nitrogen flow hole formed in the lattice structure to infiltrate the superconductor, and if the carrier is inclined due to the twisted curved track, the liquid nitrogen flows. Increasing the time the superconductor is immersed in liquid nitrogen because it flows through the hole to the upper layer
Magnetic levitation device with increased efficiency by increasing the immersion time of liquid nitrogen of the superconductor comprising a. The method according to claim 1 or 2
A superconductor slot including a superconductor space in which one or more superconductors can be inserted or extracted at the bottom of the carrier facing the magnet
Magnetic levitation device that increases the efficiency by increasing the immersion time of liquid nitrogen of the superconductor further comprising a.

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