KR100888794B1 - Vortex heating generator - Google Patents

Abstract

A vortex heating generator is provided to heat fluid using thermal energy generating in rotating the fluid at high speed without using an additional fossil fuel. A high efficiency heating device comprises a motor(200), a housing(10) in which a penetration hole(11) in which a rotating shaft(210) of a motor is inserted is formed, in which a plurality of grooves(13) are formed like a step on the inner surface and outer surface is formed with a discharge pipe(20) connected to the inner surface; a cover(30) assembled to the housing, in which a penetration hole(31) to be assembled to a suction pipe(40) is formed inside and a plurality of grooves(33) is formed like a step on the inner surface; a fluid accelerating unit(60) of an impeller type, formed on the end of a rotating shaft of a motor; and a vortex activating unit(50), assembled to the housing and the inner surface of a cover away at regular interval from, in which a hole(51) in which a rotating shaft of a motor is formed in the center and whose outer surface has a plurality of grooves(53) shaped like a step.

Description

High efficiency heating device using vortex {VORTEX HEATING GENERATOR}

The present invention relates to a high-efficiency heating device using a vortex, and more particularly, by swirling the fluid flowing in the flow path at a high speed in the heating device to form a vortex that decomposes molecules of the fluid and generates thermal energy to heat the liquid. It relates to a high efficiency heating device using.

In general, most devices such as boilers using fluids (hereinafter referred to as "water") have heating means.

The heating means is supplied with thermal energy by burning fossil fuels such as oil, gas, and coal, or by a heater device connected to electricity.

However, as described above, a method of receiving thermal energy using a separate fossil fuel or electricity in a boiler has the following problems.

First, in recent years, the whole world is trying to secure energy due to the risk of depletion of fossil fuels (oil, gas, etc.), and it is a serious global problem that even the strength of oil is the cause of war.

 In recent years, in order to solve the above problems, some countries have made efforts to use nuclear energy, which is a highly technology-intensive industry, and these industries include the United States, Japan, and Korea, except for European countries.

Second, boilers are the most commonly used thermal energy devices in the home.

The boiler is used oil, gas or coal and these fossil fuels in Korea depend on 100% imports.

In addition, the boilers have an average efficiency of 60% compared to the fuel, and the efficiency of the waste fuel is considerably high, and the harmful gases generated while the fuel is burned are becoming a social problem as the main cause of environmental pollution.

In addition, the old boiler has a problem that the fuel efficiency is sharply lowered and the fuel is always stored at a close distance, so that there is always a risk of fire.

The present invention has been made in consideration of the above circumstances, and an object of the present invention is to use a high efficiency heating device using vortices that can maintain an environment that is environmentally friendly because no harmful gas is generated due to the use of a separate fossil fuel. In providing.

In addition, another object of the present invention is to provide a high-efficiency heating device using a vortex that can be safely used without the risk of fire because it does not need to carry and carry fuel by not using a separate fossil fuel such as oil or coal. .

In addition, another object of the present invention to provide a heating device having a significantly higher efficiency than fossil fuel.

In addition, another object of the present invention is to use a vortex that can reduce the cost of boiler management because the configuration is simple and easy to repair and manage even if the skilled person is not easy to repair and management, so that no separate manager, such as the bathroom, the boiler room of the building It is to provide a high efficiency heating device.

The present invention has a motor, a body having a through-hole through which the rotating shaft of the motor is inserted, and a plurality of grooves are formed on the inner surface and a discharge pipe communicating with the inner surface on the outer surface, and suctioned in the center to achieve the above object. The pipe has a through hole to be assembled and a plurality of grooves are formed on the inner surface and the cover assembled with the body, the body and the inner surface of the cover are assembled at a predetermined interval spaced apart and the rotating shaft of the motor is inserted into the center portion There is a fluid heating apparatus using a vortex comprising a disk-shaped vortex activator having a hole and a plurality of grooves on the outside.

In addition, as another embodiment of the fluid heating apparatus according to the present invention has a motor, a body having a through hole into which the rotating shaft of the motor is inserted and formed with a plurality of grooves in the inner surface and the discharge pipe communicating with the inner surface on the outer surface, The cover has a through hole in which the suction pipe is assembled in the center, and a plurality of grooves are formed in the inner surface, and the cover is assembled with the body, an impeller-shaped fluid acceleration part formed at the end of the rotating shaft of the motor, and the inner surface of the body and the cover. It is assembled in a state spaced apart at a predetermined interval and comprises a disk-shaped vortex active portion having a plurality of grooves to the outside and the hole into which the rotation shaft of the motor is inserted in the center portion.

On the other hand, the distance between the cover and the body and the plurality of grooves formed in the vortex active portion is characterized in that it is proportional to the diameter of the vortex active portion.

In addition, the inner surface of the cover and the body and the outer circumferential surface of the vortex active portion are formed in a stepped step so that the thermal energy generated by the groove is gradually increased.

In addition, the diameter of the suction pipe is characterized in that 1.2 ~ 1.4 times the diameter cross section of the discharge pipe.

In addition, the cross-sectional area of the suction pipe is characterized in that the same as the cross-sectional area of the gap between the vortex active portion, the body and the cover.

In addition, the suction pipe is formed coaxially with the fluid acceleration portion, characterized in that the discharge pipe is formed on the body to be connected to the outer peripheral surface of the vortex active portion.

As described above, the high efficiency heating device using the vortex according to the present invention has the following effects.

First, the fluid heating device according to the present invention has a simple configuration, less occurrence of failure and easy maintenance, there is no need for a separate management personnel can reduce labor costs.

Second, there is no need to transport fuel, such as petroleum or coal, it is possible to maintain a clean surrounding environment and to reduce the cost of purchasing and transporting fuel.

Third, by not using fossil fuels, there is an environmentally friendly effect that no pollutants are emitted.

Fourth, it can provide heating or hot water in small independent spaces, and largely can be used for large-scale saunas, swimming pools, farms, gardening facilities for special crops, schools, military units, etc. It has an effect.

Fifth, there is no need for a separate fuel storage has the effect of eliminating the risk of other fire around the fuel storage.

Next, embodiments of the present invention will be described in detail with reference to the drawings.

1 is a perspective view showing the appearance of a high efficiency heat generating device using the vortex according to the present invention.

As shown in the drawing, the heating device 100 is connected to the rotating shaft 210 of the conventional motor 200.

The heating apparatus 100 includes a body 10 having a discharge pipe 20 formed therein, and a cover 30 which is in close contact with and assembled to the body 10, and a suction pipe 40 at a central portion of the cover 30. ) Is assembled.

In addition, in the state in which the motor 200 and the heating device 100 is assembled, the cradle 300 is assembled at the lower part so as to be safely seated on the ground, and is formed to facilitate transportation and installation.

In order to describe the configuration of the heating apparatus 100 in more detail, referring to FIGS. 2 to 3 as follows.

First, the motor 200 is firmly fixed to the upper portion of the cradle 300 and may form a pad (not shown) for absorbing the vibration of the motor 200 at its connection portion.

In addition, the through hole 11 formed in the central portion of the body 10 is inserted into the rotation shaft 210 of the motor 200 is watertightly maintained.

The inner surface of the body 10 is formed with a stepped stepped step 12, the groove 12 is formed with a plurality of grooves 13, the outer circumferential surface is formed with a plurality of female threaded holes 14 are assembled do.

On the other hand, after the body 10, the disk-shaped vortex active part 50 is fitted to the rotary shaft 210 and is fixed to the rotary shaft 210 using a key (not shown).

The vortex activator 50 has an outer shape of a disk and has a hole 51 into which a rotation shaft 210 is inserted in a central portion thereof, and has a plurality of grooves 53 on both sides of a surface formed of a stepped step 52. ) Is formed.

In addition, the surface of the vortex activator 50 forms a plurality of through holes 54 in order to quickly transfer the water flowing from the front side to the rear side, and instantaneously fills the water inside the heating device.

On the other hand, the impeller-shaped fluid acceleration portion 60 is formed at the end of the rotating shaft 210.

The fluid acceleration unit 60 forms water flowing through the suction pipe 40 to the circumference of the vortex activator 50, as well as helps circulation of water.

On the other hand, the cover 30 is in close contact with the body 10 in a state in which the vortex activator 50 is assembled close to the inner surface of the body 10.

The cover 30 has a through hole 31 in which a suction pipe 40 is assembled at a central portion thereof, and a stepped step 32 and a plurality of grooves 33 in the step 32 are formed on the inner circumferential surface thereof. Is formed.

In addition, the suction pipe 40 and the cover 30 and the cover 30 and the body 10 are firmly assembled by a coupling means such as a bolt, and the watertight oil is applied to the close contact surfaces of the cover 30 and the body 10. It is desirable to form a separate seal (not shown) in order to avoid this.

Meanwhile, the grooves 33, 13, and 53 formed in the cover 30, the body 10, and the vortex generator 50 are positioned on the same line as the vortex generator 50 rotates, and the deflection is repeated. When the water is located in the same line, the water is gathered and cut off, and another water vortex (swirl) is generated inside the grooves 33, 13, and 53, and the water is molecularly decomposed by the above-described process proceeding at high speed. And heat energy is generated.

4 to 5, the water flows in through the suction pipe 40 by the rotation of the fluid accelerator 60 connected to the rotating shaft 210. The water is moved to the spaced apart space between the vortex activator 50, the cover 30, and the body 10 and is discharged through the discharge pipe 20 again.

At this time, the moving water in the space is separated from the molecules of the water at the position where the respective grooves 33, 13, 53 are formed to generate heat energy.

That is, the grooves 33, 13, 53 continue to move the grooves 33, 13, 53 are located on the same line and again deflected on the same line as the vortex activator 50 rotates. Molecular decomposition is caused by strong impacts such as tearing when agglomerates and deflects while on board. Water also swirls inside the grooves 33, 13 and 53 to release heat energy.

The above portion is obtained in the course of many experiments and research, the grooves 33 formed in the cover 30 and the grooves 53 formed in the vortex generating portion 50, and also the body 10 and the vortex generating portion 50 In the state where the formed grooves 13 and 53 are located in the same line, the gap generates the largest thermal energy when the garden is formed.

In addition, it was shown that the distance of each of the grooves 33, 13, 53 emits the greatest thermal energy when it is proportional to the diameter of the vortex activator 50.

In addition, the grooves 33, 13, and 53 formed in each of the stepped positions 32, 52, and 12 are rotated by the formed position, and it was confirmed that the molecular energy of the second stage is maximized.

In addition, the diameter of the suction pipe 40 is formed 1.2 to 1.4 times the direct end surface of the discharge pipe 20, the cross-sectional area of the suction pipe 40 is the vortex active portion 50, the body 10 and the cover 30 The highest efficiency was obtained when the cross-sectional area of the interval was equal to.

Prototype Test Results

Hereinafter, a result of manufacturing and testing a high efficiency heat generating device using the vortex according to the present invention will be described with reference to FIG. 6.

<Test method>

A high efficiency heating device (hereinafter referred to as “heating device”) using a vortex manufactured as a prototype was commissioned for 60 minutes using a 55Kw domestic Hyosung motor and connected to a water tank (2100L).

At this time, the water tank (P) and the motor 200 is connected to the suction pipe 40 and the discharge pipe 20 so that the water in the water tank (P) is circulated, and each pipe (40, 20) of the changed temperature of the water Thermometers T1, T2, T3, and T4 were installed for measurement and several ball valves (B) were installed to control the water circulated.

In addition, the suction pipe 40 has a flow meter 41 for measuring the inflow of water and a circulation motor 42 for forcibly circulating the water.

As described above, after the water was installed to circulate the tank and the heating device, the temperature of the thermometers of T1 and T2 was measured at intervals of 10 minutes to check the changed state.

<Test result>

time, minutes T1 ℃ T2 ℃ ΔT ℃ m, kg / hour Q, kcal Q, kW Wmitor, kW efficiency, factor 10 32.0 60.0 28.0 1,636 45,808 53.26 51.7 1.03 20 32.0 61.0 29.0 1,636 47,444 55.17 51.7 1.06 30 32.0 44.0 12.0 4,444 53,328 62.00 51.7 1.19 40 36.0 48.0 12.0 4,444 53,328 62.00 51.4 1.20 50 36.0 52.0 16.0 2,647 42,352 49.25 52.6 0.90 60 38.0 58.0 20.0 2,647 52,940 61.56 52.6 1.17

*. In the above test results, the average efficiency value was 1.09.

*. The effect of direction was not observed in this experiment.

1 is a perspective view of a high efficiency heating device using the vortex according to the present invention

2 is an exploded perspective view of a heating device part of the high efficiency heating device using the vortex according to the present invention;

3 is a cross-sectional view of the high efficiency heating device using the vortex according to the present invention

Figure 4 is an enlarged cross-sectional view showing the flow of the fluid of the high efficiency heating device using the vortex according to the present invention

Figure 5 is a front view showing the flow of fluid in the vortex active portion of the high efficiency heating device using the vortex according to the present invention

6 is a structural diagram according to the test method on the specification of the high efficiency heating device using the vortex according to the present invention

* Description of the symbols for the main parts of the drawings *

100 ... heater 200 ... motor

300 ... holder 10 ... body

11 ... through hole 12 ... step

13 ... Home 14 ... Female thread

20 ... discharge pipe 30 ... cover

31 ... through hole 32 ... step

33 ... home 40 ... suction pipe

50 ... vortex active part 51 ... hole

52 ... Step 53 ... Home

60 ... fluid accelerator

Claims (7)

delete Motor 200; The discharge shaft 20 having a through hole 11 into which the rotating shaft 210 of the motor 200 is inserted and formed with a plurality of grooves 13 in a stepped stepped manner on the inner surface and communicating with the inner surface on the outer surface is A body 10 formed; A cover 30 having a through hole 31 in which a suction pipe 40 is assembled in a center thereof, and a plurality of grooves 33 formed in a stepped stepped state on an inner surface thereof, and assembled with the body 10; An impeller-shaped fluid acceleration part 60 formed at an end of the rotation shaft 210 of the motor 200; The inner surface of the body 10 and the cover 30 are assembled at regular intervals, and the hole 51 into which the rotating shaft 210 of the motor 200 is inserted in the center portion and the plurality of grooves 53 to the outside. Includes; the vortex active portion 50 formed in the stepped stepped state, Here, the fluid introduced through the suction pipe 40 passes through the space formed outside the vortex activator 50 in response to the driving of the fluid accelerator 60 formed on the rotation shaft 210 of the motor 200. A plurality of grooves 33, 13, and 53 formed in the vortex activator 50, the cover 30, and the body 10 are discharged to the discharge pipe 20 and pass through the vortex activator 50. High efficiency heating device using vortex, characterized in that the thermal energy is generated by molecular decomposition. According to claim 2, wherein the distance between the plurality of grooves 33, 13, 53 formed in the cover 30 and the body 10 and the vortex active portion 50 is proportional to the diameter of the vortex active portion 50 High efficiency heating device using vortex. delete 3. The high efficiency heat generating apparatus using vortex according to claim 2, wherein the diameter of the suction pipe (40) is 1.2 to 1.4 times the diameter cross section of the discharge pipe (20). The high-efficiency heat generating device using vortex according to claim 2, wherein a cross-sectional area of the suction pipe (40) is equal to a cross-sectional area of an interval between the vortex activator (50) and the body (10) and the cover (30). The method of claim 2, wherein the suction pipe 40 is formed coaxially with the fluid acceleration portion 60 and the discharge pipe 20 is formed on the body 10 to be connected to the outer peripheral surface of the vortex active portion 50 High efficiency heating device using vortex.

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