KR101898278B1 - Hybrid power generating apparatus having boiling function - Google Patents

Abstract

The present invention relates to a hybrid power generating device having a boiler function which can reduce energy consumption by providing a weight of a fluid to a rotor to generate an inertial force and compression-heats and provides the fluid, thereby heating a heating target fluid. The hybrid power generating device having a boiler function comprises: a rotation motor providing a rotation force; the rotor connected to the rotation motor, and rotated by the rotation motor since a magnet is provided on an outer circumferential surface; a stator which is fixed to the outside of the rotor, and in which a coil facing the magnet of the rotor is located; an inertial force generating part generating the inertial force to the rotor through accumulation of the weight by the fluid while supplying the fluid to the rotor; and a boiler compressing the fluid discharged from the rotor, and generating high heat.

Description

HYBRID POWER GENERATING APPARATUS HAVING BOILING FUNCTION WITH BOILER FUNCTION

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a power generating apparatus, and more particularly, to a power generating apparatus capable of reducing energy consumption by providing an inertial force by providing a load of a fluid to a rotor, To a hybrid electric power generating apparatus.

Generally, a generator refers to that kinetic energy between coils is converted into electric energy as the coils rotate in a magnetic field formed of a magnet body.

A conventional generator is composed of a rotor as a rotating body and a stator as a non-rotating body. Since the magnets and the coils are arranged in correspondence with each other in the rotor and the stator, the electric energy due to the charge induced in the coils from the kinetic energy due to the rotation of the rotor is recovered and stored and used

Such a power generation apparatus is generally made to be able to produce electricity using wind, thermal or hydraulic power in nature. Such wind power, thermal power, or hydroelectric power generation apparatus may be constructed by using a windmill or a water turbine And the electric energy can be produced through the induction of the current between the rotor receiving the rotational force and the stator provided corresponding to the rotor.

Such a conventional power generation apparatus is a device and a facility which can produce electric energy from kinetic energy in nature, which can generate power or tidal power in addition to hydraulic power, thermal power or wind power.

Meanwhile, the above-described power generation apparatus may generate electric energy by using an output of a rotary motor that generates a separate rotational force in addition to a hydraulic power, a thermal power, or a wind power.

That is, the power generation device is applied not only to a device for power generation only, but also to a separate power generation device having an additional function by using rotational force to produce electric energy.

In the case where the power generation apparatus generates electric energy by the rotational force of the rotary motor, consumption of the electric energy consumed in the rotary motor must be minimized in order to obtain optimal power generation efficiency.

SUMMARY OF THE INVENTION The present invention has been made in order to solve the problems of the prior art as described above, and it is an object of the present invention to provide an inertial force due to a load of a fluid on a rotor rotating by a rotational force of a rotary motor, To provide a hybrid power generation device having a boiler function capable of compressing a fluid to provide high heat.

Specifically, it is an object of the present invention to provide a hybrid power generation apparatus having a boiler function capable of providing an inertial force to a rotor while loading and discharging fluid in a conical receiving space provided inside the rotor.

In addition, the present invention reduces the energy consumption of the motor by spirally rotating the fluid discharged from the rotor while compressing and heating the fluid through the centrifugal force at a high pressure and providing a thrust for rotation through the discharge pressure of the fluid compressed at a high pressure And to provide a hybrid power generation device having a boiler function.

According to an aspect of the present invention, there is provided a hybrid electric power generating apparatus having a boiler function, the hybrid electric power generating apparatus including: A rotor connected to the rotation motor, the rotor being disposed on an outer circumferential surface of the magnet and rotated by the rotation motor; A stator fixed to the outside of the rotor and having a coil facing the magnet of the rotor; An inertial force generating unit for generating an inertial force on the rotor through the accumulation of a load by the fluid while supplying the fluid to the rotor; And a boiler for generating high heat by compressing the fluid discharged from the rotor, wherein the inertial force generating unit comprises: a fluid pump for pumping and supplying the fluid; A hollow shaft having an interior formed in a hollow tube shape to connect the fluid pump and the rotor, and to supply fluid of the fluid pump into the rotor while rotating with the rotor by the rotating motor; A rotary joint rotatably connecting the hollow shaft to the fluid pump; And a conical receiving space provided at the center of the rotor for supplying the fluid of the hollow shaft through the inlet and having an inlet and an outlet through which the fluid is introduced and discharged and which connects the inlet and the outlet, And a conical loading part which fills the inflowing fluid into the conical receiving space and provides a load by the fluid while loading the conical loading space.

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In addition, the conical mounting portion may be formed so that the width of the receiving space gradually decreases from the inlet to the outlet.

The conical loading unit may further include a weight pocket formed in a shape of a groove in a part of an inner circumferential surface of the accommodating space and formed in a plurality of along the circumferential direction of the accommodating space to load the fluid while increasing the load by the fluid .

The weight pockets may be formed in a plurality of rows at a predetermined distance from the inlet to the outlet, and may be formed to be gradually smaller toward the outlet from the inlet.

In addition, the boiler may include a helical friction member that heats the fluid discharged from the rotor to spirally flow while compressing the fluid to heat the fluid through frictional heat by flow, and discharges the fluid; And a heat exchange tank for heat-exchanging the high-temperature fluid with the fluid to be heated while circulating the high-temperature fluid discharged from the helical friction member, and circulating the stored fluid to the rotor.

The helical friction member is formed in a cylindrical shape having a fluid flow space therein, and is connected to the rotor and rotates together with the rotor. The fluid space is divided by a spiral partition wall to divide the fluid discharged from the rotor A spiral disc for guiding the fluid to the outer periphery of the flow space along the spiral partition and compressing and heating the fluid while friction is applied; And a jet nozzle provided at an outer periphery of the spiral disk to generate a high-pressure thrust for rotating the spiral disk while discharging the compressed fluid from the spiral disk.

The heat exchange tank may include an upper tank for receiving the helical friction member therein and guiding the high-temperature fluid discharged from the helical friction member to the lower portion; A lower tank connected to the lower portion of the upper tank to provide a fluid storage space and connected to the rotor via the inertial force generating portion; A heat exchange pipe coupled to the inside of the lower tank to heat exchange the fluid to be heated and the fluid in the lower tank while flowing the fluid to be heated; And a plurality of radiating fins coupled to an outer circumferential surface of the heat exchange pipe in a state of being embedded in the lower tank to expand a heat exchange area.

According to the hybrid electric power generating apparatus having the boiler function according to the embodiment of the present invention, the inertial force due to the load of the fluid is supplied to the rotor because the fluid is discharged while being loaded on the conical stacking unit constituting the inertial force generating unit, And power generation efficiency can be improved.

Further, since the spiral disk constituting the boiler spirally rotates the fluid and compresses the fluid at a high pressure through the centrifugal force, the fluid can be smoothly heated to a high temperature and a high pressure. Especially, when the fluid having high pressure is discharged through the jet nozzle, So that the energy consumption of the rotary motor can be further reduced.

The effects of the present invention are not limited to the effects mentioned above, and other effects not mentioned can be clearly understood by those skilled in the art from the description of the claims.

1 is a perspective view showing a hybrid power generation apparatus having a boiler function according to an embodiment of the present invention.
Fig. 2 is a perspective view showing the rotor shown in Fig. 1, the helical friction member of the boiler, and the inside of the heat exchange tank.
3 is a vertical sectional view showing the interior of a rotor and the interior of a boiler according to an embodiment of the present invention.
4 is a longitudinal sectional view showing another embodiment of the conical loading portion shown in Fig.
5 is a front view of a boiler according to one embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings, wherein like reference numerals are used to designate identical or similar elements, and redundant description thereof will be omitted. The suffix "module" and " part "for the components used in the following description are given or mixed in consideration of ease of specification, and do not have their own meaning or role.

In the following description of the embodiments of the present invention, a detailed description of related arts will be omitted when it is determined that the gist of the embodiments disclosed herein may be blurred. It is to be understood that both the foregoing general description and the following detailed description are exemplary and explanatory and are intended to provide further explanation of the invention as claimed. , ≪ / RTI > equivalents, and alternatives.

Also, terms including ordinal numbers such as first, second, etc. may be used to describe various elements, but the elements are not limited to these terms. The terms are used only for the purpose of distinguishing one component from another.

It is to be understood that when an element is referred to as being "connected" or "connected" to another element, it may be directly connected or connected to the other element, . On the other hand, when an element is referred to as being "directly connected" or "directly connected" to another element, it should be understood that there are no other elements in between.

In the following description, the singular forms "a", "an", and "the" include plural referents unless the context clearly dictates otherwise, and the terms "comprise" Or combinations thereof, are intended to designate the presence of, or a combination of, one or more other features, integers, steps, operations, elements, components, or combinations thereof

FIG. 1 is a perspective view showing a hybrid power generation apparatus having a boiler function according to an embodiment of the present invention, FIG. 2 is a perspective view showing the interior of a helical friction member and a heat exchange tank of the boiler shown in FIG. 1, 1 is a longitudinal sectional view showing an interior of a rotor and an interior of a boiler according to an embodiment of the present invention. Fig. 4 is a longitudinal sectional view showing another embodiment of the conical loading portion shown in Fig. 3, and Fig. 5 is a front view showing a boiler according to an embodiment of the present invention.

1 and 2, the hybrid electric power generating apparatus according to an embodiment of the present invention includes a rotary motor 10, a rotor 20, a stator 30, an inertial force generating unit 40, And a boiler (50).

The rotary motor 10 is a component that rotates the helical friction member 100 of the rotor 20 and the boiler 50 described below.

3, the rotary motor 10 may be coupled to the outer circumferential surface of a hollow shaft 41 to be described later, and rotate the hollow shaft 41 together with the rotor 20 while being operated by a power supply.

The rotor 20 and the stator 30 constitute a power generation module that converts kinetic energy generated by the rotary motor 10 into electric energy.

Specifically, the rotor 20 constitutes a rotor of the power generation module. The rotor 20 is connected to the rotation motor 10 through a hollow shaft 41 to be described later, is rotated by the rotation motor 10, 21 are provided to form a magnetic field.

Here, the rotor 20 may be, for example, a permanent neodymium magnet as a magnet provided on the outer circumferential surface, or alternatively, a conventional permanent magnet or electromagnet may be installed.

The stator 30 is fixed to the outside of the rotor 20 as a stator of the power generation module and the coils 31 corresponding to the magnets 21 of the rotor 20 are disposed, It is possible to recover and store electric energy due to electric charges induced in the coil 31 from kinetic energy due to rotation of the coil 31. [

Specifically, when the magnet 21 is closest to the coil 31, the voltage reaches its maximum. At this point, when the coil 31 is disconnected from the circuit using the special transistor, all the energy accumulated in the form of current It can immediately induce magnetic induction to change the flow direction and generate counter electromotive force.

Here, the coil 31 may be composed of, for example, a copper double coil.

At this time, depending on the size of the coil 31, the self-induced energy may be 10 times or 20 times higher than the current direction. In this case, the opposite energy (or counter electromotive force) is the parasitic current that must be treated against the direction of the flow.

This is why copper double coils are used in the power generation apparatus according to the present invention. In a copper double coil, the opposite energy can be transferred to the next coil away from the current flow through the second wire, Lt; / RTI > Once the voltage reaches its peak, it can be disconnected from the circuit and magnetic induction can be obtained. Its counter-electromotive force can be redirected and the process can be repeated.

In addition to the above configuration, the rotor 20 and the stator 30 may be applied to any configuration known in the art to which the present invention belongs.

The inertial force generating unit 40 is a component for reducing the power consumption of the rotary motor 10 by generating an inertial force by the load on the rotor 20 described above.

Specifically, the inertial force generating unit 40 may supply fluid to the interior of the rotor 20 to provide an inertial force to the rotor 20 through accumulation of the load of the fluid.

The inertial force generating portion 40 may include a fluid pump 41, a hollow shaft 42, a rotary joint 43, and a conical loading portion 44 as shown in FIG.

The fluid pump 41 may pump the fluid stored in the heat exchange tank 200 to be described later and supply the fluid to the hollow shaft 42, which will be described later.

Specifically, the fluid pump 41 is connected to the lower tank 220 and the rotary joint 43 through a connection pipe, and supplies the fluid in the lower tank 220 to the rotary joint 43 while being operated by a power source To the hollow shaft 42 and the rotor 20.

That is, the fluid pump 41 can load the fluid in the rotor 20 by supplying the fluid in the lower tank 220 constituting the heat exchange tank 200 for storing the fluid to the rotor 20.

Here, the fluid to be used in the present invention may be applied in various forms such as heat medium oil, water, brine, water vapor, etc., and may be used in a liquid or gaseous state.

The operation of the fluid pump 41 can be controlled by the control of a temperature sensor (not shown) installed in the lower tank 220. The operation of the fluid pump 41 can be controlled according to the number of revolutions of the rotor 20 May be controlled.

The temperature sensor senses the fluid temperature of the lower tank 220 to control the operation of the fluid pump 41. For example, when the fluid temperature of the lower tank 220 reaches a predetermined temperature, Can be stopped.

That is, when the fluid temperature of the lower tank 220 reaches a high temperature, the fluid pump 41 can stop the circulation of the fluid. When the temperature of the lower tank 220 drops below the set temperature, To the rotor (20).

Also, the fluid pump 41 can be stopped before the number of revolutions of the rotor 20 reaches the predetermined number of revolutions, and can be circulated to the rotor 20 while operating only when the number of revolutions is reached have.

The hollow shaft 42 is a component that supplies the fluid stored in the heat exchange tank 200, which will be described later, to the inside of the rotor 20.

Specifically, the hollow shaft 42 is formed in a hollow tube shape. One end of the hollow shaft 42 in the longitudinal direction is connected to a fluid pump 41, which will be described later, to supply the fluid in the heat exchange tank 200, And the fluid can be supplied into the rotor 20.

The hollow shaft 42 is rotatably installed by the rotary motor 10 described above and can supply the fluid to the rotor 20 while rotating together with the rotor 20 by the operation of the rotary motor 10 .

The rotary joint 43 is a component that permits rotation of the hollow shaft 42 by rotatably connecting the hollow shaft 42 to the fluid pump 41.

That is, the rotary joint 43 connects one end of the hollow shaft 42 constituting the rotating body by the rotary motor 10 to the connection pipe of the fluid pump 41 constituting the fixing body, and the hollow shaft 42, The fluid of the fluid pump 41 can be supplied to the hollow shaft 42 while allowing the rotation of the hollow shaft 42.

Any structure can be satisfied as long as the rotary joint 43 can rotate the hollow shaft 42 while supplying the fluid.

The conical mounting portion 44 is a component that causes inertia to be generated in the rotor 20 by distributing the fluid supplied from the hollow shaft 42 to the inside of the rotor 20 and providing a load by the fluid.

3, the conical mounting portion 44 is provided at the center of the rotor 20 and has an inlet and an outlet for the fluid. By forming the conical receiving space while connecting the inlet and the outlet, It can be loaded in the receiving space.

That is, the fluid flows from the hollow shaft 42 and is scattered and loaded on the conical loading section 44 by the rotation of the rotor 20, thereby providing the inertial force through the load. ). ≪ / RTI >

3, the conical mounting portion 44 is formed so that its width becomes gradually narrower toward the discharge port from the inlet, as shown in FIG. 3, so that the load can be concentrated on a portion of the rotor 20 adjacent to the rotary motor 10. [

On the other hand, the conical mounting portion 44 may be formed with a plurality of weight pockets 45 as shown in Fig.

The weight pockets 45 are formed in the shape of a groove in a part of the inner circumferential surface of the receiving space forming the conical mounting portion 44 and are formed in plural along the circumferential direction of the receiving space to receive the fluid .

That is, the weight pocket 45 can receive the fluid through the centrifugal force generated by the rotation of the rotor 20, thereby increasing the load on the conical mounting portion 44 by the fluid.

4, the weight pockets 45 may be formed in a plurality of rows at a predetermined distance from the inlet to the outlet as shown in FIG. 4. At this time, the weight pockets 45 may be formed to be gradually smaller in size from the inlet to the outlet.

That is, the weight pocket 45 can be configured to bias the weight of the load caused by the fluid toward the rotary motor 10.

The boiler 50 is a component for heating the fluid to be heated through heat exchange while compressing the fluid discharged from the rotor 20 to generate high temperature.

The boiler 50 may include a helical friction member 100 and a heat exchange tank 200.

The helical friction member 100 is a component that heats and supplies the fluid to a high temperature through the frictional heat generated by the fluid while rotating the fluid.

Specifically, the helical friction member 100 heats the fluid with frictional heat by rotating the fluid and spirally flows through the centrifugal force, and by moving the fluid from the rotation center of the spiral flow path to the outer periphery, the fluid can be compressed and discharged at a high pressure .

That is, the helical friction member 100 can perform a function of providing the fluid with a high-temperature and high-pressure phase change through a spiral flow path.

The helical friction member 100 may include a helical disk 140 and a jet nozzle 150 as shown in FIGS.

The spiral disc 140 is a component for rotating the fluid supplied from the rotor 20 and compressing the fluid at a high temperature and a high pressure.

Specifically, the spiral disc 140 is formed in a cylindrical shape and is connected to an outlet of a conical mounting portion 44 formed in the rotor 20 with a fluid flow space therein, so that the fluid is supplied to the center portion of the flow space, The fluid can be rotated while being rotated together with the rotor 20 by the motor 10 so as to be compressed to high temperature and high pressure.

5, the spiral disc 140 is divided by the spiral partition 141 to form a spiral fluid passage, and the fluid supplied from the rotor 20 to the center of the fluid space is spirally wound, The fluid can be frictionally heated while being guided along the partition wall 141 of the partition wall 141 to be compressed at a high pressure.

That is, the fluid is heated to a high temperature by the frictional heat while moving along the spiral partition wall 141 by the rotation of the spiral disk 140, and is compressed to a high pressure state as the fluid moves to the outer periphery of the fluid space by centrifugal force have.

Referring to FIG. 2, the spiral disc 140 is shown with its tip open. However, as shown in FIG. 3, the spiral disc 140 is shielded by the disc cover 140a. .

The jet nozzle 150 is a component that generates a propelling force at a high pressure while discharging the fluid compressed at a high pressure from the spiral disc 140 to generate a high-pressure thrust for rotating the spiral disc 140.

In other words, the jet nozzle 150 is formed in the form of a plurality of holes along the circumferential direction on the outer periphery of the spiral disk 140 to generate a jet propulsion force due to the discharge of the fluid while discharging the high pressure fluid from the spiral disk 140 And serves as a rotational force of the spiral disc 140.

That is, the fluid is compressed to a high pressure while moving to the outer circumference of the fluid space through the centrifugal force due to the rotation of the spiral disk 140, and is discharged to the outside of the spiral disk 140 through the jet nozzle 150 at a high pressure, To generate a jet propulsion force for rotation of the rotor 140.

Accordingly, the helical disk 140 can reduce the load on the rotary motor 10 by providing the thrust by the jet nozzle 150, and ultimately can reduce the power consumption of the rotary motor 10 .

Here, the jet nozzle 150 is formed as a slope opposed to the rotational direction of the spiral disc 140 so as to eject the fluid in the direction opposite to the rotation of the spiral disc 140, And can be rotated.

In addition, the jet nozzle 150 may be formed so that the width of the flow path gradually decreases toward the outer side of the spiral disc 140. This is to increase the speed of the fluid by reducing the volume of the flow path so that a smooth propulsion force is generated.

On the other hand, the above-described spiral partition wall 141 may protrude vortex projections not shown along the surface.

The vortex projection is a component that generates a vortex in the fluid while expanding the friction area with the fluid, thereby achieving smooth flow.

The vortex protrusions may protrude at equal intervals on the surface of the spiral partition wall 141 to contact the fluid to interfere with the flow and generate a vortex in the fluid.

For example, the vortex protrusion may be configured to interfere with the flow of the fluid while being fixed to the spiral partition wall 141 in the form of a plate having an arc-shaped curvature and opposed to the flow direction of the fluid.

In addition, the spiral disc 140 may be formed so that the width of the fluid channel formed by the spiral partition wall 141 gradually increases from the central portion of the fluid space to the outer periphery thereof.

In other words, the spiral partition wall 141 can be formed so that the width of the flow path due to the width of the partition wall gradually widens toward the outer periphery. As a result, the fluid moves to the outside due to the centrifugal force due to the rotation of the spiral disk 140, As pressure increases, it can be compressed.

Alternatively, the spiral disc 140 may be formed such that the width of the fluid passage formed by the spiral partition wall 141 gradually increases from the central portion of the fluid space to the outer periphery thereof.

In other words, the spiral partition wall 141 can be formed so that the width of the flow path due to the width of the partition walls becomes gradually narrower toward the outer periphery. Accordingly, the fluid moves to the outside due to the centrifugal force due to the rotation of the spiral disk 140, Becomes narrower, so that it can be compressed with increasing speed.

The heat exchange tank 200 is a component for heating a fluid to be heated by exchanging heat with a fluid to be heated while storing a high temperature fluid discharged from the jet nozzle 150 constituting the helical friction member 100 described above.

That is, the heat exchange tank 200 is a component for providing hot water by heat-exchanging the high temperature fluid discharged from the jet nozzle 150 with a heating target fluid such as cold water.

Specifically, the heat exchange tank 200 may include an upper tank 210, a lower tank 220, and a heat exchange pipe 230, as shown in FIGS.

The upper tank 210 is formed in a hollow shape having an open bottom so that the spiral disc 140 and the jet nozzle 150 constituting the helical friction member 100 are received therein and discharged from the jet nozzle 150 The high-temperature high-pressure fluid can be guided to the lower portion.

The lower tank 220 may have a substantially hollow shape and may be connected to a lower portion of the upper tank 210 to store a high temperature fluid guided downward from the upper tank 210.

The lower tank 220 is connected to the fluid pump 41 described above while providing a storage space for the fluid to supply the fluid back into the rotor 20 through the fluid pump 41 and the hollow shaft 42.

The heat exchange pipe 230 is a component for heating by heat-exchanging a fluid to be heated such as cold water with a high temperature fluid stored in the lower tank 220.

The heat exchange pipe 230 may be coupled to cross the inside of the lower tank 220 and may be heated by heat exchange with the fluid of the lower tank 220 while flowing the fluid to be heated.

3, a plurality of heat dissipation fins 240 may be installed on the outer circumferential surface of the heat exchange pipe 230 so as to expand the heat exchange area with the fluid of the lower tank 220. [

The operation and operation of the hybrid power generation apparatus having the boiler function according to the embodiment of the present invention including the above-described components will be described.

The fluid pump 41 senses the rotation speed of the rotary motor 10 through the rotation sensor and when the rotary motor 10 reaches the predetermined rotation speed, the fluid pump 41 pumps the fluid in the lower tank 220 to rotate the hollow shaft 42 To the conical stacking unit 44. [0041]

The fluid is scattered into the receiving space of the conical mounting portion 44 by rotation of the rotor 20 and is increased while increasing the load while generating an inertial force in the rotor 20. [

The rotor 20 rotates through the rotating force of the rotating motor 10 and the inertial force caused by the fluid, thereby obtaining magnetic induction together with the stator 30 to generate electric energy.

The fluid is discharged from the conical loading section 44 of the rotor 20 and supplied to the spiral disc 140 and then moved along the spiral partition wall 141 by the rotation of the spiral disc 140, Heated, and compressed through centrifugal force to the outer periphery of the spiral disc 140.

The fluid is compressed to a higher pressure as the number of rotations of the spiral disc 140 increases and is discharged to the outside of the spiral disc 140 through the jet nozzle 150 to provide a driving force to the rotation of the spiral disc 140.

At this time, when the spiral disc 140 reaches the set rotational speed, the rotary motor 10 operates while reducing the output load since propulsion by the jet nozzle 150 is generated.

The high-temperature and high-pressure fluid discharged from the jet nozzle 150 is supplied to the upper tank 210 and is supplied to the lower tank 220 while moving to the lower portion. The heat exchange pipe 230 traversing the lower tank 220, The heating fluid of the heat exchange pipe 230 is heated.

As described above, the hybrid power generation apparatus having the boiler function according to the embodiment of the present invention is configured such that the fluid by the fluid pump 41 is loaded on the conical loading section 44 constituting the inertial force generating section 40, The inertial force due to the load of the fluid is provided to the rotor 20 so that the power consumption of the rotary motor 10 can be minimized and the power generation efficiency can be improved and the spiral disc 140 constituting the boiler 50 The fluid can be smoothly heated to a high temperature and a high pressure, and in particular, since a high-pressure fluid is discharged through the jet nozzle 150, the jet propulsion force for rotating the spiral disk 140 The energy consumption of the rotating motor can be further reduced.

It will be apparent to those skilled in the art that the above-described embodiments are for illustrative purposes only and that those skilled in the art will readily understand that various changes and modifications can be made without departing from the spirit or scope of the present invention. You will understand. It is therefore to be understood that the above-described embodiments are to be considered in all respects only as illustrative and not restrictive. For example, each component described as a single entity may be distributed and implemented, and components described as being distributed may also be implemented in a combined form.

It is to be understood that the scope of the present invention is defined by the appended claims rather than the foregoing description and should be construed as including all changes and modifications that come within the meaning and range of equivalency of the claims, .

10: Rotary motor
20: Rotor
30:
40: inertia force generating unit
41: Fluid pump
42: hollow shaft
43: Rotary joint
44: conical loading part
45: Weight pocket
50: Boiler
100: helical friction member
140: Spiral disk
141: Spiral partition
150: jet nozzle
200: Heat exchange tank
210: upper tank
220: Lower tank
230: Heat exchange pipe
240: heat sink fin

Claims (8)

A rotation motor for providing a rotational force;
A rotor connected to the rotation motor, the rotor being disposed on an outer circumferential surface of the magnet and rotated by the rotation motor;
A stator fixed to the outside of the rotor and having a coil facing the magnet of the rotor;
An inertial force generating unit for generating an inertial force on the rotor through the accumulation of a load by the fluid while supplying the fluid to the rotor; And
And a boiler for compressing the fluid discharged from the rotor to generate high heat,
Wherein the inertia-
A fluid pump for pumping and supplying the fluid;
A hollow shaft having an interior formed in a hollow tube shape to connect the fluid pump and the rotor, and to supply fluid of the fluid pump into the rotor while rotating together with the rotor by the rotating motor;
A rotary joint rotatably connecting the hollow shaft to the fluid pump; And
Wherein a fluid is supplied to the hollow shaft through the inlet while having an inlet and an outlet through which the fluid flows in and out of the rotor, and a conical receiving space for connecting the inlet and the outlet is formed, And a conical stacking portion for distributing the fluid to the conical accommodation space and providing a load by the fluid while being stacked.
delete The method according to claim 1,
The cone-
And a boiler function is formed such that the width of the accommodation space gradually decreases from the inlet to the outlet.
The method according to claim 1,
The cone-
Further comprising a weight pocket formed in a part of an inner circumferential surface of the accommodating space in a groove shape to form a plurality of along the circumferential direction of the accommodating space and weighting the load by the fluid while receiving the fluid.
5. The method of claim 4,
The weight pocket
And a boiler function having a plurality of rows at a predetermined interval from the inlet to the outlet and having a size gradually decreasing from the inlet toward the outlet.
The method according to claim 1,
In the boiler,
A helical friction member for rotating the fluid discharged from the rotor to spirally flow while compressing the fluid to heat and discharge the fluid through frictional heat due to flow; And
And a heat exchange tank for heat-exchanging the high-temperature fluid with the fluid to be heated while circulating the high-temperature fluid discharged from the helical friction member, and circulating the stored fluid to the rotor.
The method according to claim 6,
Wherein the helical friction member comprises:
Wherein the rotor is connected to the rotor and rotates together with the rotor, and the fluid space is defined by a spiral partition wall so that fluid discharged from the rotor flows along the spiral partition wall, A spiral disk guiding to the outside of the space to compress and heat the fluid while rubbing; And
And a jet nozzle provided at an outer periphery of the spiral disk and generating a high-pressure thrust for rotating the spiral disk while discharging the compressed fluid from the spiral disk.
The method according to claim 6,
The heat exchange tank
An upper tank for receiving the helical friction member therein and guiding the high-temperature fluid discharged from the helical friction member to the lower portion;
A lower tank connected to the lower portion of the upper tank to provide a fluid storage space and connected to the rotor via the inertial force generating portion; And
A heat exchange pipe coupled to the inside of the lower tank to heat exchange the fluid to be heated and the fluid in the lower tank while flowing the fluid to be heated; And
And a plurality of radiating fins coupled to an outer circumferential surface of the heat exchange pipe in a state of being embedded in the lower tank to expand a heat exchange area.

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