KR20210106818A - tesla carrier - Google Patents

Abstract

The present invention relates to an apparatus for generating heat energy by using magnetoresistance. Specifically, the apparatus for generating heat energy (1) by using magnetoresistance in accordance with the present invention comprises: a heat energy generation tank means (100) for making heat energy generated in an energy source to discharge the energy source having the heat energy; a heat energy generation coil means (200) wound on a central shaft of the heat energy generation tank means (100) in a cylindrical shape to take on a spiral form, wherein the energy source is introduced through one side and the introduced energy source flows to the heat energy generation tank means (100); and a frequency oscillation means (300) performing frequency oscillation toward the heat energy generation tank means (100) and the heat energy generation coil means (200), wherein oscillating frequency from the frequency oscillation means (300) induces an electric current in the heat energy generation coil means (200) and the heat energy generation tank means (100). Accordingly, interaction of magnetoresistance heats the heat energy generation coil means (200) and the heat energy generation tank means (100) and makes heat energy generated in the energy source introduced into the heat energy generation coil means (200) and discharged to the heat energy generation tank means (100). Accordingly, heat energy is rapidly generated in the energy source with a small amount of energy to ensure high efficiency of the apparatus for generating heat energy.

Description

Thermal energy generating device using magnetoresistance {tesla carrier}

The present invention relates to an apparatus for generating thermal energy using magnetoresistance, and more particularly, by using the electromagnetic induction principle of current due to frequency oscillation and the interaction of magnetic reluctance through this, thermal energy is generated in an energy source It relates to a device for generating thermal energy using magnetoresistance.

Resistance heating is

A method of heating using electrical resistance.

What is induction heating?

As a method of electric heating, it is a method of heating by converting electric energy into thermal energy by electromagnetic induction.

In addition, magnetic reluctance is,

Resistance to changes in magnetic flux in a magnetic circuit is proportional to the length of the magnetic circuit, and inversely proportional to the cross-sectional area and permeability.

The present invention provides a thermal energy generating device capable of generating thermal energy in an energy source within a short time to obtain high efficiency with little energy using such resistance heating, induction heating, and magnetic reluctance. want to

Accordingly, as a prior art related to a device for generating thermal energy using magnetoresistance,

As shown in Figure 10 (a),

"Multiple induction heating device for boiler" of Republic of Korea Patent Publication No. 10-1080108 (hereinafter referred to as 'prior art 1'),

A first body formed in a circular tube shape and a first hole arranged in a circular arrangement on an upper surface of the first body are formed, and a first coil heated by electric power supply is installed on the outer surface of the first body, so that the first body a first heating part configured to be heated, a second body having the same second hole as the first heating part in the first body, and a second coil, wherein the outer surface of the second coil is the inside of the first body It consists of a second heating part formed and installed in a size in contact with the surface, a third body having the same third hole as the first heating part inside the second body, and a third coil, wherein the outer surface of the third coil is the second heating part. 2 A second heating unit formed in a size in contact with the inner surface of the body, one end of the third coil passing through the second to third bodies, and a connection for electrically connecting each coil through the body In communication with the first to third holes at the upper and lower portions of the member and the heating unit, water introduced from the outside is dispersed in the lower portion of the first heating unit, and water passing through the first to third holes is collected and discharged in the upper portion It consists of a pipe part that

The capacity of the water to be heated is increased by the expansion of the second or third heating unit in which the second or third hole is formed through which the heated water is moved, and the first body of the first heating unit and the second heating unit are formed. As the body and the third body of the third heating unit are heated by the first coil, the second coil, and the third coil, respectively, even if the amount of water used increases, the heating time does not increase, and the inside of the already installed first heating unit After the second heating part or the third heating part is easily inserted into the furnace, the extension operation is completed only by connecting the first coil, the second coil, and the third coil to each other through the connecting member. It relates to a multiple induction heating device for a boiler, which can easily configure an induction heating device suitable for the capacity of water to be increased simply by simply expanding the second heating unit to the third heating unit in proportion to the above.

Another prior art is

As shown in Figure 10 (b),

"Induction heating boiler" of Republic of Korea Patent Publication No. 10-1484981 (hereinafter referred to as 'prior art 2'),

A working coil is formed using a copper pipe, a water tank made of a magnetic material is placed close to the working coil, and water is introduced into the working coil to circulate it, and then the leaked water is supplied to the water tank. It relates to an induction heating boiler with increased thermal efficiency, configured to supply a switching current under the control of a controller by an IGBT to the working coil.

As can be seen, the prior art 1 to the prior art 2 are similar to the present invention and the same technical field, and although similar and identical technical concepts exist in the basic components constituting the invention, the problems and effects to be solved by the invention, There is a difference in the means of solving the problem.

That is, there is a difference in technical characteristics in specific solutions (components) of the invention for solving the problem to be solved by the invention and exhibiting the effect.

Therefore, the present invention is different from the conventional induction heating-related technologies including the prior art 1 to the prior art 2, the problem to be solved (object of the invention) of the present invention only, a solution (configuration) for solving this element) and the effect exerted by solving it, we intend to seek its technical characteristics.

Republic of Korea Patent Publication No. 10-1080108 (Registered on October 31, 2011) Republic of Korea Patent Publication No. 10-1484981 (Registered on January 15, 2015)

Accordingly, the present invention has been devised to solve the above-mentioned conventional problems,

An object of the present invention is to provide a thermal energy generating device that allows thermal energy to be rapidly generated in an energy source requiring thermal energy.

Another object of the present invention is to

An object of the present invention is to provide a thermal energy generating device that allows thermal energy to be rapidly generated in an energy source using resistance heating, induced current, and magnetic reluctance without using a separate heat source catalyst. .

The present invention for achieving the above object has been devised to achieve the problem to be solved,

In the thermal energy generating device using magnetoresistance,

a thermal energy generating tank means for generating thermal energy in the energy source and discharging the thermal energy generated energy source;

a thermal energy generating coil unit wound in a cylindrical shape based on the central axis of the thermal energy generating tank unit to form a spiral, and an energy source is introduced to one side, and the introduced energy source flows to the thermal energy generating tank unit;

Frequency oscillation means for oscillating a frequency with the heat energy generating tank means and the heat energy generating coil means;

A current is induced in the thermal energy generating coil means and the thermal energy generating tank means by the frequency oscillated from the frequency oscillation means, and the thermal energy generating coil means and the thermal energy generating tank means are heated and heated by the interaction of magnetic reluctance accordingly. It is characterized in that heat energy is generated in an energy source that is introduced into the generating coil means and discharged to the heat energy generating tank means.

On the other hand, prior to this, in this specification, the terms or words used in the claims of the patent registration should not be construed as being limited to conventional or dictionary meanings, and the inventor should not use the concept of terms to explain his invention in the best way. should be interpreted as meaning and concept consistent with the technical idea of the present invention based on the principle that can be appropriately defined.

Accordingly, the embodiments described in the present specification and the configurations shown in the drawings are only the most preferred embodiment of the present invention, and do not represent all of the technical spirit of the present invention. It should be understood that there may be equivalents and variations.

According to the present invention as described above in the above configuration and operation,

1. Quickly generate thermal energy to an energy source that requires thermal energy.

That is, high efficiency is created with little energy.

2. As a compact device, there is no noise or vibration in operating the device as well as improving the efficiency of the installation space.

That is, in comparison with the area of a space where a steam pipe generating thermal energy to an energy source is installed in the related art, the present invention not only minimizes the installation area due to the significant simplification of the device, but also, in the case of a conventional steam pipe, the compressor In contrast to the active generation of noise and vibration due to use, the present invention uses frequency oscillation, so that noise and vibration are significantly reduced.

3. Without using a separate heat source catalyst, heat energy is rapidly generated in the energy source using only the interaction of resistance heating, induced current, and magnetic reluctance.

4. By using frequency oscillation, energy consumption is significantly saved.

That is, the energy saving effect is maximized.

Accordingly, the present invention can be said to be a very effective invention for rapidly generating thermal energy to an energy source requiring thermal energy.

1 is a block diagram of a thermal energy generating device using a magnetoresistance according to the present invention.
2 is a cross-sectional view showing a conceptual diagram of an apparatus for generating thermal energy using a magnetoresistance according to the present invention.
3 is a schematic cross-sectional view showing an embodiment of a device for generating thermal energy using a magnetoresistance according to the present invention.
4 is a flowchart schematically illustrating the flow of an energy source for an embodiment of an apparatus for generating thermal energy using a magnetoresistance according to the present invention.
5 is a flow diagram of an energy source for an embodiment of the apparatus for generating thermal energy using a magnetoresistance according to the present invention.
6 is a schematic cross-sectional view illustrating a conceptual diagram of resistance heating, induction heating, and magnetic reluctance generated from an apparatus for generating thermal energy using magnetoresistance according to the present invention.
7 is a conceptual diagram illustrating a state perspective view of an embodiment of an apparatus for generating thermal energy using a magnetoresistance according to the present invention.
8 shows an actual photograph of an embodiment of an apparatus for generating thermal energy using a magnetoresistance according to the present invention.
9 is a schematic diagram illustrating an embodiment of a heating system to which a device for generating thermal energy using a magnetoresistance according to the present invention is applied.
10 shows a representative diagram of the prior art for the apparatus for generating thermal energy using the magnetoresistance according to the present invention.

Hereinafter, with reference to the accompanying drawings, the function, configuration and operation of the apparatus 1 for generating thermal energy using a magnetoresistance according to the present invention will be described in detail.

1 is a block diagram of a device for generating thermal energy using a magnetoresistance of the present invention, FIG. 2 is a conceptual diagram of a device for generating thermal energy using a magnetoresistance of the present invention, and FIG. 3 is a device for generating thermal energy using a magnetoresistance of the present invention A schematic diagram of an embodiment is shown.

As shown in Figures 1 to 3, the present invention,

In the thermal energy generating device (1) using magnetoresistance,

a thermal energy generating tank means 100 for generating thermal energy in an energy source and discharging the thermal energy generated energy source;

Thermal energy generating coil means for winding in a cylindrical shape with respect to the central axis of the thermal energy generating tank means 100 to form a spiral, and allowing the energy source to flow to one side and the introduced energy source to flow to the thermal energy generating tank means 100 . (200);

Frequency oscillation means 300 for oscillating a frequency with the heat energy generating tank means 100 and the heat energy generating coil means 200;

A current is induced in the thermal energy generating coil unit 200 and the thermal energy generating tank unit 100 by the frequency oscillated from the frequency oscillating unit 300, and the thermal energy generating coil unit is the result of the interaction of magnetic reluctance. (200) and the thermal energy generating tank means 100 are heated and introduced into the thermal energy generating coil means 200, characterized in that the thermal energy is generated in the energy source discharged to the thermal energy generating tank means (100).

That is, the present invention uses an induction heating method, but the thermal energy generating tank means 100 by the frequency oscillated from the frequency oscillating means 300 and the thermal energy generating coil means surrounding the outer peripheral surface of the thermal energy generating tank means 100 By the interaction of the magnetic reluctance of 200, heat is generated, and heat energy is transferred to the energy source flowing through the heat energy generating coil means 200 and the heat energy generating tank means 100 according to a specific path. It is a technology for a thermal energy generating device.

Looking more specifically,

Thermal energy generating tank means 100,

a first tank unit 110 having an empty space therein;

a second tank unit 120 forming a concentric circle with the first tank unit 110 and inserting the first tank unit 110 into an empty space therein;

an energy source space part 130 generated between the first tank part 100 and the second tank part 120 by the combination of the first tank part 110 and the second tank part 120;

an energy source tank connection unit 140 connecting one side of the energy source oil passage space 130 and an empty space inside the first tank unit 110;

The energy source discharge unit 150 for discharging the energy source flowing into the first tank unit 110 to the outside;

By the interaction of the magnetic reluctance of the thermal energy generating coil means 200 and the thermal energy generating tank means 100 by the frequency oscillated from the frequency oscillation means 300, thermal energy is transferred to the energy source flowing along a specific path. As it is generated, it is characterized in that the energy source in which thermal energy is generated is discharged to the energy source discharge unit 150 .

In addition, the thermal energy generating coil means 200,

a first heating element coil unit 210 closely attached to and coupled to the outer peripheral surface of the second tank unit 120 and wound in a cylindrical shape with respect to the central axis of the second tank unit 120 to form a spiral;

a second heating element coil part (220) spaced apart from the first heating element coil part (210) by a predetermined interval and wound in a cylindrical shape based on the central axis of the second tank part (120) to form a spiral;

a first heating element coil connection part 230 for connecting one side of the first heating element coil part 210 and one side of the second heating element coil part 220;

a second heating element coil connecting part 240 connecting one side of the first heating element coil part 210 and one side of the second tank part 120;

Consists of; an energy source inlet pipe part 250 for allowing an energy source to flow into the second heating element coil part 220 ,

Through the interaction of the magnetic reluctance of the first heating element coil part 210 and the second heating element coil part 220 by the frequency oscillated from the frequency oscillation means 300, the energy source inlet pipe part 250 It is characterized in that the incoming energy source is moved along a specific path to generate thermal energy.

That is, due to the frequency oscillated from the frequency oscillation means 300, the first tank part 110, the second tank part 120, the first heating element coil part 210, and the second heating element coil part 220 flow. The current is actively alternating, so that thermal energy is rapidly generated, thereby allowing the thermal energy to be rapidly transferred to an energy source flowing along a specific path.

That is, as shown in FIG. 6 , heat is generated in the second heating element coil unit 220 according to the resistance heating method, and according to the induction heating method, the first heating element coil unit 210 and the second heating element coil unit 210 The first tank part 110 and the second tank part 120 wrapped in the second heating element coil part 220 are heated, and in addition, the second heating element coil part 220 and the first heating element coil part 210 are heated. ) and the interaction of the magnetic reluctance of the thermal energy generating tank means 100, the thermal energy generating coil means 200 and the thermal energy generating tank means 100 are heated together, and the energy flowing in and flowing along a specific path Thermal energy is rapidly generated in the source. (The frequency oscillation means 300 first oscillates a frequency with the second heating element coil unit 220 .)

At this time, the height of the first tank unit 110 is 'H ₁ ',

When one side of the energy source discharge unit 150 is inserted and coupled to the inside of the first tank unit 110, the protruding height is referred to as 'H ₂ ',

The inequality of H ₂ > a * H _{1 must hold.}

In this case, 'a' is a constant,

The range of 'a' is,

a = 0.001 to 1.

In addition, since the energy source expands 1600 [times] in volume when it is changed from saturated steam to superheated steam, it is preferable to maintain the _{energy source in the first tank unit 110 at less than H 2 .}

This is because, when the energy source is filled and maintained with more than H _{2 , the thermal efficiency is lowered.}

In addition to this,

The cross-sectional area of the first heating element coil 210 is 'A ₁ ',

When the cross-sectional area of the second heating element coil 220 is 'A ₂ ',

The inequality of A ₁ ≤ A ₂ must be established.

For example, if the first heating element coil part 210 is formed in a circular tube shape,

The second heating element coil part 220 is preferably formed in a tubular shape having a larger cross-sectional area than the first heating element coil part 210, or is formed in a rectangular shape, in particular, a rectangular shape.

This allows the current between the first heating element coil part 210 and the second heating element coil part 220 to be actively exchanged by the frequency oscillated from the frequency oscillation means 300, as well as the second heating element coil part 220. and the second tank unit 120 also allow currents to be actively exchanged with each other, so that the interaction of magnetic reluctance is facilitated.

That is, the first heating element coil part 210 and the second heating element coil part 220 may be formed in a circular or polygonal shape so that the inequality is satisfied.

In addition, when the separation distance between the first heating element coil part 210 and the second heating element coil part 220 is 'D ₁ , D ₂ ',

It should be formed within the range of 0 [mm] < D ₁ < 200 [mm] (see Fig. 3).

When this is 0 [mm], that is, when the first heating element coil part 210 and the second heating element coil part 220 are in contact, a short (short circuit) occurs,

If it is more than 200 [mm], the interaction effect is greatly reduced, and it is not possible to quickly generate thermal energy in the energy source.

In addition, the reason why the thermal energy generating coil means 200 is largely formed by the first heating element coil part 210 and the second heating element coil part 220 is,

This is to create a spin effect (spintronics) of great magneto resistance due to the interaction of magnetic reluctance. (This is the reason why thermal energy is rapidly generated).

On the other hand, in the present invention,

The dome housing 400 that protects the thermal energy generating tank means 100 and the thermal energy generating coil means 200 from the outside, so that the thermal energy is generated more quickly, as well as preventing the generated thermal energy from being lost to the outside; may be included or constituted.

The present invention also

a first path (R1) through which the energy source is introduced into the energy source inlet pipe unit (250);

a second path (R2) through which the energy source flows to the second heating element coil unit (220) through the first path (R);

a third path (R3) through which the energy source passes through the second path (R2) and the first heating element coil connection unit (230);

a fourth path (R4) through which the energy source flows to the second heating element coil unit (220) through the third path (R3);

a fifth path (R5) through which the energy source passes through the fourth path (R4) and the second heating element coil connection unit (240);

a sixth path (R6) through which the energy source flows to the energy source passage space (130) through the fifth path (R5);

a seventh path (R7) through which the energy source passes through the sixth path (R6) and the energy source oil passage tank connection unit (140);

an eighth path (R8) through which the energy source flows into the first tank unit (110) through the seventh path (R7);

A ninth path (R9) through which the energy source is discharged to the energy source discharge unit 150 through the eighth path (R8); is composed of,

As shown in FIG. 5, the energy source is a first path (R1), a second path (R2), a third path (R3), a fourth path (R4), a fifth path (R5), a sixth path ( R6), the seventh path R7, the eighth path R8, and the ninth path R9 are sequentially passed to generate thermal energy.

On the other hand, with reference to FIG. 4 , the flow of the energy source flowing into the apparatus 1 for generating thermal energy using magnetoresistance according to the present invention is briefly viewed as a flowchart,

an energy source inflow step (S100) in which the energy source is introduced through the first path (R1);

a second heating element coil flow step (S200) in which the energy source flows through the second path (R2) and the third path (R3);

a first heating element coil flow step (S300) in which the energy source flows through the fourth path (R4) and the fifth path (R5);

a flow step (S400) of an energy source passage space in which an energy source flows through the sixth path (R6) and the seventh path (R7);

a first tank part flow step (S500) in which the energy source flows into the first tank part 110 through the eighth path (R8);

An energy source discharging unit discharging step (S600) in which an energy source from which thermal energy is generated is discharged through the ninth path (R9);

The energy source flows in, flows out, and out, causing the energy source to generate thermal energy.

For reference, the term 'energy source' in the present invention means,

Refers to liquids and gases, and in particular, may be defined as water, oil with a low vaporization point, refrigerant, and the like.

In addition, according to the amount of the energy source introduced into the present invention, the state of thermal energy generated in the energy source may vary.

For example, assuming that the energy source is water, saturated steam or superheated steam may be discharged to the energy source discharge unit 150 according to the amount of water introduced.

In addition, the thermal energy generating tank means 100 and the thermal energy generating coil means 200 are made of metal, in particular, made of a magnetic material, by the interaction of magnetic reluctance with each other by the frequency oscillated from the frequency oscillation means 300 . Heat is generated and heated.

In addition, the first heat generating Czech may be part 210 and the second heat generating Czech forming part 220, it is spaced at a predetermined interval, a predetermined height. (D _1, but also may become a specific range defined in D ₂ .)

This is to rapidly expose the thermal energy generating tank means 100 and the thermal energy generating coil means 200 to the frequency oscillated from the frequency oscillation means 300, so that heat is generated and heated by the interaction of magnetic reluctance. This is to shorten the time and maximize the efficiency of the device.

In addition, 'interaction' in the present invention means,

It means that a current is generated by the frequency oscillated from the frequency oscillation means 300, and the generated current is actively exchanged with another object to form magnetic reluctance.

The following experimental example compares the performance with respect to the temperature-time of the conventional steam tube generating thermal energy to the energy source and the thermal energy generating device 1 using the magnetoresistance of the present invention.

Experiment example

The energy source applied to the above experimental example is water, which shows the time it takes to raise 4 [ton] of water to 90 [℃].

'①' is a conventional steam tube,

'②' is a thermal energy generating device 1 using the magnetoresistance of the present invention.

That is, as described above, in the conventional steam tube, it takes 24 [hr] to raise 4 [ton] of water to 90 [℃], whereas the present invention takes only 1 [hr].

The above experimental example is an experiment made under the same conditions of supplying electric power of 380 [V] and current of 110 [A] being applied.

At this time, in addition to the supply power and current, the conventional steam pipe used in the experiment is a steam pipe installed in a dedicated area of 65 [m ² ] to 70 [m ² ], and the present invention has a dedicated area of 15 [m ² ] to 20 [m] ² ] is prepared for the performance of the thermal energy generating device 1 using the magnetoresistance installed in the present invention. The effect can be further increased according to the number of installations of the thermal energy generating device 1 using the cross-sectional area and the formed length of the coil means 200 and magnetoresistance.)

That is, in the present invention, the frequency oscillation means 300 is connected to the second heating element coil 220 configured as a passage through which a coil and energy source capable of generating thermal energy flows in and flows, and the frequency oscillation means 300 is oscillated, and resistance heating ( resistance heating) is formed, of course, due to the second heating element coil part 210 and the first heating element coil part 210, the thermal energy generating tank means 100 generates thermal energy in an induction heating method, in addition to , magnetic reluctance in the first heating element coil part 210 , the second tank part 120 , and the first tank part 110 due to the frequency and current flowing to the second heating element coil part 220 . Formation and their interaction is to rapidly generate thermal energy in the thermal energy generating tank means 100 and the thermal energy generating coil means 200 .

At this time, the thermal energy (E) generated in the energy source is,

It can be defined as 'E = 1 + (E _RH * E _MR ) + E _{IH + f'.}

here,

E is the thermal energy generated from the present invention,

E _RH is the thermal energy generated by resistance heating,

E _MR is the thermal energy generated by the interaction of magnetoresistance,

E _IH is the thermal energy produced by induction heating,

f is the frequency oscillated by the frequency oscillation means 300 .

In the present invention, a character written through '[]' means a unit of the corresponding number.

As described above, the present invention is not limited to the described embodiments, and it is apparent to those skilled in the art that various modifications and variations can be made without departing from the spirit and scope of the present invention.

Therefore, since it can be implemented in various other forms without departing from the technical spirit or main characteristics, the embodiments of the present invention are merely illustrative in all respects and should not be construed as being limited and may be implemented with various modifications.

The present invention relates to a device for generating thermal energy using magnetoresistance, and can be used in the overall energy-related industrial field.

For example, industries that require amplification of energy and control of calorific value, agricultural and fishery related heating and cooling system industries, device and system industries that supply heat sources for residential spaces and buildings, engines of transportation means such as ships, vehicles, trains, etc. It can be applied to contributing to the promotion of various industrial fields, such as industrial facilities, household waste from pyrolysis, marine waste treatment facilities and system industries, and furthermore, solid oxide fuel cells and turbine power generation.

1: Thermal energy generating device using magnetoresistance
100: thermal energy generating tank means 110: first tank unit
120: second tank unit 130: energy oil passage space unit
140: energy source tank connection unit 150: energy source discharge unit
200: thermal energy generating coil means 210: first heating element coil part
220: second heating element coil part 230: first heating element coil connection part
240: second heating element coil connection part 250: energy source inlet pipe part
300: frequency oscillation means 400: dome housing
S100: energy source introduction step S200: second heating element coil flow step
S300: first heating element coil flow step S400: energy source flow space portion flow step
S500: first tank unit flow step S600: energy source discharge unit discharge step
R1: first path R2: second path
R3: third path R4: fourth path
R5: fifth route R6: sixth route
R7: 7th path R8: 8th path
R9: Route 9

Claims (1)

In the thermal energy generating device (1) using magnetoresistance,
a thermal energy generating tank means 100 for generating thermal energy in an energy source and discharging the thermal energy generated energy source;
Thermal energy generating coil means for winding in a cylindrical shape with respect to the central axis of the thermal energy generating tank means 100 to form a spiral, and allowing the energy source to flow to one side and the introduced energy source to flow to the thermal energy generating tank means 100 . (200);
Frequency oscillation means 300 for oscillating a frequency with the heat energy generating tank means 100 and the heat energy generating coil means 200;
A current is induced in the thermal energy generating coil unit 200 and the thermal energy generating tank unit 100 by the frequency oscillated from the frequency oscillation unit 300, and the thermal energy generating coil unit is the result of the interaction of magnetic reluctance. (200) and the thermal energy generating tank means 100 are heated, characterized in that heat energy is generated in an energy source that is introduced into the thermal energy generating coil means 200 and discharged to the thermal energy generating tank means 100,
A device for generating thermal energy using magnetoresistance.

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