KR20120067467A - Oxygen magnetic separator in air - Google Patents

Abstract

PURPOSE: An oxygen ultra conductive magnetic separator in air is provided to shorten separation time by using a non-magnetic pipe which includes magnetic filter wires and an ultra conductive magnetic separator. CONSTITUTION: An oxygen ultra conductive magnetic separator comprises non-magnetic pipe(100), axial direction diaphragms(120), and magnetic filter wires(130). The non-magnetic pipe is installed in boa of an ultra conductive magnet(10) in an axial direction in order for air to exit and enter. The non-magnetic pipe is separated by an axial direction diaphragm in which through-holes is formed and forms two transfer lines which are connected to each other. In one of the transfer lines, a magnetic filter wire is included inside and discharges oxygen in the air, and the other transfer line separates and discharges nitrogen.

Description

Oxygen superconducting magnetic separator in air

The present invention relates to a superconducting magnetic separation device, and uses a superconducting magnetic separation device to separate oxygen in air, and to an oxygen superconducting magnetic separation device in air to allow simultaneous separation of oxygen and nitrogen therefrom.

In recent years, superconductivity and low temperature generation technology have advanced significantly, and superconducting magnets having excellent economical and operability have been put into practical use. Application of such a superconducting magnet to a magnetic separation device has the advantage of being able to process suspended particles in large quantities at high speed, saving energy and processing them in a small device in a small area.

In general, a superconducting magnetic separator is a device for purifying wastewater or polluted air generated in a factory or home using superconducting magnets. When the object to be treated is passed through the magnetic filter inserted in the material, the substance to be separated is adsorbed on the filter and separated.

The present invention is to separate the oxygen in the air, the air is composed of about 78% nitrogen (N ₂ ) and about 21% oxygen (O ₂ ), there are several ways to separate the air into nitrogen and oxygen have.

In particular, a method of separating using activated carbon or zeolite using a size difference between nitrogen and oxygen molecules has been commercialized. However, this increases the purity while repeating the compression and expansion to a high pressure, there is a problem that the productivity is low, such as the amount of air used compared to the amount of gas to be separated and the process takes a lot of time.

Therefore, the present invention intends to use the principle of the superconducting magnetic separation device.

Nitrogen is very weak diamagnetic (-0.43x10 ^-6 cm ³ / mol) and oxygen has a large susceptibility (108x10 ^-6 cm ³ / mol) in paramagnetic material. Therefore, under high magnetic fields, nitrogen is hardly affected, but oxygen is attracted to the strong magnetic field. Of course, oxygen is expected to be effective in the high magnetic fields generated by superconducting magnets because the magnetization rate is much smaller than that of strong magnetic materials such as Fe, Ni, and Co.

That is, the paramagnetic material has a smaller susceptibility value according to the applied magnetic field than the ferromagnetic material, but when the value of the applied magnetic field is increased by using a superconducting magnet, the paramagnetic material is magnetized to a sufficient value to be adsorbed and removed by the magnetic filter.

However, even if such a superconducting magnetic separation device is used, efficient separation of nitrogen from oxygen becomes a problem.

The present invention is to solve the above problems, to provide a superconducting magnetic separation device to separate the oxygen in the air, and to provide an oxygen superconducting magnetic separation device in the air to allow the simultaneous separation of oxygen and nitrogen therefrom. It is done.

In order to achieve the above object, the present invention, in the superconducting magnetic separation device using a superconducting magnet, a non-magnetic pipe is installed in the bore of the superconducting magnet in the axial direction is made of the inflow and outflow of air, the non-magnetic pipe is formed through the hole It is separated by an axial diaphragm to form two transfer lines communicating with each other. One of the transfer lines includes a magnetic filter wire inside to separate and adsorb oxygen in the air, and the other transfer line separates nitrogen. An oxygen superconducting magnetic separation device of air characterized in that the discharge is a technical gist.

In addition, the non-magnetic pipe is formed as a single body to the boa portion of the superconducting magnet, the transfer line is separated from the end portion of the boa of the superconducting magnet is formed extending into two bodies so that nitrogen and oxygen are transferred respectively. It is desirable to.

In addition, the diaphragm is formed up to a portion where the separation begins with the two bodies, the through-hole formed in the diaphragm is preferably formed only to the bore portion of the superconducting magnet, the magnetic filter wire is separated into two bodies extending It is preferable to be formed to a part.

In another aspect, the present invention, in the superconducting magnetic separation device using a superconducting magnet, a non-magnetic pipe is installed in the axial direction of the superconducting magnet is made to flow in and out, the non-magnetic pipe is a through hole at the front end of the superconducting magnet It is separated by the formed axial diaphragm to form two conveying lines communicating with each other, one of the conveying lines includes a magnetic filter wire therein to separate oxygen in the air, and at the beginning of the boa of the superconducting magnet The lines are separated and extended to two bodies, and the body including the magnetic filter wire is axially inserted into the bore of the superconducting magnet to adsorb and discharge the separated oxygen, and the other body is formed outside the superconducting magnet to form nitrogen. Another technology of oxygen superconducting magnetic separation device in the air, characterized in that for discharging And as a base.

Here, the diaphragm is preferably formed only until the non-magnetic pipe is separated into two bodies.

By means of the above problem solving means, using a non-conductive pipe including a superconducting magnetic separation device and a magnetic filter wire, air is converted into a gas having a higher concentration of nitrogen and a gas having a higher concentration of oxygen than a natural state at a higher speed than a conventional device. At the same time there is an effect that can be separated.

In addition, it is possible to send a gas having a high oxygen concentration to the combustion device that requires a large amount of oxygen to improve the efficiency, it is expected to be applied to various fields that require oxygen.

1-Schematic diagram of the oxygen superconducting magnetic separation device in the air according to the first embodiment of the present invention.
2-a cross sectional view of a non-magnetic pipe according to a first embodiment of the invention;
3-side perspective view of a non-magnetic pipe according to a first embodiment of the present invention;
4-Schematic diagram of the oxygen superconducting magnetic separation device in the air according to the second embodiment of the present invention.

The present invention relates to an oxygen superconducting magnetic separation device in the air that uses a superconducting magnetic separation device to separate the oxygen in the air, thereby allowing efficient separation of oxygen and nitrogen.

In particular, non-magnetic pipes and magnetic filter wires are installed in the bore of superconducting magnets to adsorb and discharge oxygen in the air. Since the oxygen can be separated and discharged at the same time as a gas having a high concentration, there is an advantage in that a gas having a high oxygen concentration can be supplied to a combustion device that requires a large amount of oxygen.

Hereinafter, with reference to the accompanying drawings will be described an embodiment of the present invention.

≪ Embodiment 1 >

1 is a schematic diagram of a first embodiment of the present invention, Figure 2 shows a cross-sectional view of a non-magnetic pipe according to the first embodiment of the present invention, Figure 3 is a non-magnetic according to the first embodiment of the present invention The side perspective view of the pipe is shown.

As shown, the first embodiment of the present invention, in the superconducting magnetic separation device using the superconducting magnet 10, the non-magnetic pipe 100 is installed in the bore of the superconducting magnet 10 in the axial direction, the flow of air This is to be made, by generating a high gradient high magnetic field by the magnetic filter wire 130 included in the non-magnetic pipe 100 to adsorb oxygen in the air and to separate and discharge it with nitrogen.

The non-magnetic pipe 100 is separated by an axial diaphragm 120 having a through hole 110 to form two transfer lines communicating with each other, and one of the transfer lines includes a magnetic filter wire 130 therein. ), And oxygen is separated and adsorbed in the air, and the other transfer line is to separate and discharge nitrogen.

The magnetic filter wire 130 included in one of the transfer lines of the non-magnetic pipe 100 is formed of a ferritic stainless material and laminated in the transfer line. When the magnetic material is placed inside the superconducting magnet 10, the magnetic flux is focused into the magnetic filter wire 130, and a rapid magnetic slope is formed on the surface of the magnetic filter wire 130. Therefore, when the magnetic filter wire 130 is formed in one of the transfer lines of the non-magnetic pipe 100, a stronger magnetic field is generated to act as a magnetic filter so that a magnetic material is generated when gas or liquid passes therebetween. Will be adsorbed. Oxygen in the air is also magnetic, so that the efficient adsorption to the magnetic filter wire 130 is made.

That is, in the transfer line including the magnetic filter wire 130 where the magnetic flux is concentrated, the oxygen concentration is increased while the paramagnetic oxygen is adsorbed, so that the transfer line with the magnetic filter wire 130 has a higher oxygen concentration than air. The other transfer line without the magnetic filter wire 130 becomes a portion that flows at a higher ratio of nitrogen than air.

In addition, the non-magnetic pipe 100 is formed as a body to the boa portion of the superconducting magnet 10, the transfer line is based on the diaphragm 120 in the end portion of the bore of the superconducting magnet 10. It is separated and extended into two bodies to allow nitrogen and oxygen to be transferred, respectively. In addition, the diaphragm 120 is formed up to a portion where the separation starts with two bodies, the through-hole 110 formed in the diaphragm 120 is formed only up to the bore portion of the superconducting magnet 10, the magnetic filter wire 130 is separated into two bodies are formed up to the extended portion.

That is, the diaphragm 120 is formed only up to the part where the superconducting magnet 10 is located (the part where the separation starts with two bodies), after which the non-magnetic pipe is completely divided into two bodies, and oxygen in the air is magnetic. The filter wire 130 is to flow only to the part. The magnetic filter wire 130 included in the elongated body is weaker than in the bore of the superconducting magnet 10 but is still under the magnetic field effect of the superconducting magnet 10 so that oxygen continues to contain the magnetic filter wire 130. To ensure stable discharge.

Second Embodiment

Figure 4 shows a schematic diagram of the second embodiment of the present invention, as shown in the second embodiment of the present invention, unlike the first embodiment from the front end of the superconducting magnet 10 from the non-magnetic pipe ( 100 is formed so that the superconducting magnet 10 starts to be divided into two bodies in a Y-shape, which will be described below.

The non-magnetic pipe 100 is formed in the axial direction of the superconducting magnet 10 as a whole, the non-magnetic pipe 100 is an axial diaphragm 120 having a through-hole 110 formed at the front end of the superconducting magnet 10. It is separated by a) to form two transfer lines in communication with each other, one of the transfer line includes a magnetic filter wire 130 therein to separate the oxygen in the air from the front end of the superconducting magnet (10).

In addition, the transfer line is separated and formed into two bodies at the boa starting portion of the superconducting magnet 10, and the body including the magnetic filter wire 130 is inserted axially into the boa of the superconducting magnet 10. It is formed to adsorb and discharge the oxygen separated from the front end of the superconducting magnet 10, the other body is formed to the outside of the superconducting magnet 10 to discharge the nitrogen. Here, the diaphragm 120 is formed only until the non-magnetic pipe 100 is separated into two bodies.

That is, since the non-magnetic pipe 100 is formed from the front end of the superconducting magnet 10 and includes a magnetic filter wire 130 in one of the transfer lines, oxygen is separated from the non-magnetic pipe 100 into two bodies. Since the magnetic field effect of the magnetic filter wire 130 by the superconducting magnet 10 before it is induced to flow into the body inserted into the bore of the superconducting magnet 10, the simultaneous separation and discharge of nitrogen and oxygen is possible.

As described above, the present invention simultaneously separates air into a gas having a higher concentration of nitrogen and a gas having a higher concentration of oxygen than a natural state using a non-magnetic pipe including a superconducting magnetic separation device and a magnetic filter wire. You can do it.

This means that in a device using a boiler that uses fuel such as coal or petroleum to raise the temperature by combustion, the efficiency of the boiler can be increased if the ratio of oxygen to the natural state can be increased when flowing air for combustion. It is possible to improve the efficiency by sending a gas with a high oxygen concentration to a combustion device that requires a large amount of oxygen such as a thermal power plant.

In addition, the heat generated during the combustion reaction is not constant due to the change in humidity in the air, the output may not be uniform, increasing the concentration of oxygen in the air, such problems can be solved, such as oxygen superconducting in the air according to the present invention It is expected that the magnetic separation device will be applied to various fields.

10: superconducting magnet 100: nonmagnetic pipe
110: through-hole 120: diaphragm
130: magnetic filter wire

Claims (6)

In a superconducting magnetic separation device using a superconducting magnet,
A non-magnetic pipe 100 is installed in the bore of the superconducting magnet 10 in the axial direction, and air flows in and out.
The nonmagnetic pipe 100 is separated by an axial diaphragm 120 having a through hole 110 to form two transfer lines communicating with each other. One of the transfer lines includes a magnetic filter wire 130 therein. Oxygen superconducting magnetic separation device in the air, characterized in that the discharge by separating and adsorbing oxygen in the air, the other transport line is separated and discharged nitrogen. According to claim 1, The non-magnetic pipe 100 is formed of a body up to the bore portion of the superconducting magnet 10, the transfer line is separated from the two ends of the bore of the superconducting magnet 10, two Oxygen superconducting magnetic separation device in the air, characterized in that extending to the body of the nitrogen and oxygen to be transported respectively. The method of claim 2, wherein the diaphragm 120 is formed to a portion where the separation starts with two bodies, the through-hole 110 formed in the diaphragm 120 is formed only to the boa portion of the superconducting magnet 10 Oxygen superconducting magnetic separation device in the air. According to claim 2, The magnetic filter wire 130 is oxygen superconducting magnetic separation device in the air, characterized in that formed to extend to the separated portion of the two body. In a superconducting magnetic separation device using a superconducting magnet,
The non-magnetic pipe 100 is installed in the axial direction of the superconducting magnet 10, the air flows in and out,
The non-magnetic pipe 100 is separated by an axial diaphragm 120 having a through-hole 110 formed at the front end of the superconducting magnet 10 to form two transfer lines communicating with each other, one of the transfer lines Including a magnetic filter wire 130 therein to separate oxygen from the air,
At the start of the boa of the superconducting magnet 10, the transfer line is separated and extended to two bodies, and the body including the magnetic filter wire 130 is axially inserted into the bore of the superconducting magnet 10. Oxygen superconducting magnetic separation device in the air, characterized in that the adsorbed and discharged separated oxygen, the other body is formed outside the superconducting magnet (10) to discharge nitrogen. The oxygen superconducting magnetic separation device of air according to claim 5, wherein the diaphragm 120 is formed only until the non-magnetic pipe 100 is separated into two bodies.

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