KR20190107493A - Fluid heating device through fluid frictional heat - Google Patents

Abstract

The present invention relates to a fluid heating device through fluid frictional heat, which is connected to a motor to be connected to a rotating shaft of a first case that is rotated at a high speed. A frictional rotor provided with first and second friction through holes primarily heats a liquefied fluid by heating the liquefied fluid with a centrifugal force, an eddy, and friction heat by high speed rotation in a fluid heating internal space portion. The primarily heated liquid fluid is connected to the motor to be connected to a rotating shaft of a second case that is rotated at a high speed, and the frictional rotor provided with the first and second friction through holes secondarily heats the liquefied fluid by heating the liquefied fluid with a centrifugal force, an eddy, and friction heat by high speed rotation in the fluid heating internal space portion. The liquefied liquid is primarily and secondarily heated to effectively, quickly, and smoothly produce a liquefied liquid having a high temperature to produce eco-friendly energy.

Description

Fluid heating device through fluid frictional heat

The present invention relates to a fluid heating apparatus through fluid friction heat, and more particularly, a friction rotor having first and second friction through holes connected to a rotating shaft of a first case which is connected to a motor and rotates at high speed, and has a fluid heating internal space. The liquid fluid is heated by centrifugal force, vortex, and frictional heat by high-speed rotation at the part, and the liquid fluid is heated first, and the first heated liquid fluid is connected to the rotating shaft of the second case which is connected to the motor and rotated at high speed. The friction rotor with 2 friction holes is heated secondly by centrifugal force, vortex and frictional heat by high speed rotation in the inner space of the fluid heating to produce the high temperature liquid fluid efficiently and quickly. It relates to a fluid heating device through the fluid friction heat to produce environmentally friendly energy.

In general, the boiler is commonly used as a heating or hot water supply device, the water is heated to a constant temperature to supply through the supply pipe and heated by the radiant heat of the heat and return to the circulating pump, the boiler as described above It is closely related to our lives as a heating and hot water supply device in homes and offices, and as a power generator for industrial activities in industrial sites.

The boiler as described above has been developed a lot by the necessity, the handling is easy, while the structure is complicated, requires a high level of technology in terms of construction, maintenance or repair, and the auxiliary facilities involved in the handling of the boiler, Effective thermal management of fuel consumption is also an important issue.

However, conventional boilers use oil, electricity, or gas as fuel to provide a heat source, and the basic concept of supplying heating and hot water by operating a circulating pump is not changed. Many research and development is being done.

Therefore, boilers or heat generators that have been used or developed so far have to consume excessive power or fuel despite many researches and developments, and can be burdened by consumers in terms of construction or maintenance, thus creating a new concept of boiler. There has been a continuing demand for heat generators.

Heat pumps are widely used as heat generators. During the operation of the heat pump, heat exchange and reverse circulation of heat occur inside.

That is, the principle of absorbing heat from the external environment and converting the medium into a high temperature material is applied.

A representative example of such a heat pump is a heat pump system that generates heat energy using changes in physical and mechanical parameters of the material (particularly pressure and volume).

However, such a conventional heat pump system requires a variety of devices for heat exchange, for example, a compressor, a condenser, an evaporator, and the like, and thus, the system is complicated and difficult to miniaturize.

Moreover, conventional heat pump systems have limitations in implementing a simple system for achieving the purpose of heating only in the form of cooling and heating in a single system.

In order to solve the above problems, the present invention is connected to the rotating shaft of the first case is connected to the motor is rotated at high speed in the fluid heating inner space portion of the friction rotor having a first and second friction through holes The fluid is heated by centrifugal force, vortex, and frictional heat to heat the liquid fluid firstly, and the first heated liquid fluid is connected to the rotating shaft of the second case which is connected to the motor and rotates at high speed, and has first and second friction holes. A friction rotor heats secondly by centrifugal force, vortex, and frictional heat by high-speed rotation in the inner space of the fluid heating, and heats the liquid fluid one and two times to produce high-temperature liquid fluid efficiently and quickly, producing eco-friendly energy. It is an object of the present invention to provide a fluid heating device through a new fluid friction heat.

In order to achieve the above object, the present invention is the first inlet (a) is provided on the right side and the outlet (b) is installed on the left side, the fluid heating inner space (c) formed therein that can be heated fluid first Two cases 10a and 10b; The first and second cases 10a and 10b are disposed in a longitudinal direction on the center line of the fluid heating inner space c and are installed on the left side of the first case 10a and the second case 10b. A rotating shaft 20 which is installed to be capable of rotating at a high speed integrally with the connecting shafts d respectively extended to the outside of the right side of the; It is installed between the first and second cases (10a, 10b), the first driving shaft 31a is provided on the left side to be connected to the connecting shaft (d) of the first case (10a), the second case ( A motor 30 having a second drive shaft 31b on its right side to be connected to the connection shaft d of 10b; It is fixed to the outer periphery of the rotary shaft 20 of the first and second cases (10a, 10b) a plurality or more are heated liquid by compression and friction by high-speed rotation in the fluid heating inner space (c) A friction rotor 40 installed to discharge through the outlets of the first and second cases 10a and 10b; A connecting pipe 50 connecting the outlet (b) of the first case (10a) and the inlet (a) of the second case (10b) with each other: to the inlet (a) of the first case (10a) It is provided on the left side to be connected to the outlet (b) to supply the liquid fluid, characterized in that consisting of a liquid fluid tank 60 having an inlet (a) on the right side.

In addition, the friction rotor 40 has a main body (40a) formed in the shape of a disk plate, a coupling hole 41 is formed in the center of the main body 40a to be coupled to the rotating shaft 20, the coupling hole 41 A groove portion 42 having a plurality of friction protrusions 42a is formed on the upper surface at a distance from both sides of the outer peripheral side of the), and the plurality of second friction through holes 44 formed on the outer peripheral surface of the main body 40a are The first friction through hole 43 is formed in the shape of the left light right side, or the left hole 43a and the right hole 43b have different heights, and the left hole 43a and the right hole 43b are mutually different. An inclined hole 43c is formed to be connected, and the first friction through hole 43 and the second friction through hole 44 are connected to each other.

In addition, the first driving shaft 31a of the motor 30 and the connecting shaft d of the first case 10a are connected to each other by a first connecting member 70a. The second driving shaft 31b and the connecting shaft d of the second case 10b are connected to each other by a second connecting member 70b.

The present invention is connected to the motor and the rotating shaft of the first case is rotated at high speed and the friction rotor having the first and second friction holes are heated by the high-speed rotation in the fluid heating inner space portion liquid fluid is heated by centrifugal force, vortex and friction heat Firstly heats the liquid fluid, and the first heated liquid fluid is connected to the motor again and is connected to the rotating shaft of the second case which rotates at high speed, and a friction rotor having first and second friction holes is provided in the fluid heating inner space. Secondary heating by centrifugal force, vortex and frictional heat by high-speed rotation has the effect of producing eco-friendly energy by efficiently and quickly producing high-temperature liquid fluids by heating the liquid fluids one and two times.

1 is a perspective view according to the present invention.
2 is a front schematic view according to the present invention;
3 is a perspective view showing a friction rotor according to the present invention.
Figure 4 is a schematic cross-sectional view showing a first embodiment showing the first and second friction through holes of the friction rotor according to the present invention.
Figure 5 is a schematic cross-sectional view showing a second embodiment showing the first and second friction through holes of the friction rotor according to the present invention.
Figure 6 is a schematic cross-sectional view showing a third embodiment showing the first and second friction through holes of the friction rotor according to the present invention.
7 is a schematic view showing a friction protrusion on the friction rotor according to the present invention.

In order to fully understand the present invention, preferred embodiments of the present invention will be described with reference to the accompanying drawings.

Embodiments of the invention may be modified in various forms, the scope of the invention should not be construed as limited to the embodiments described in detail below. This embodiment is provided to more safely explain the present invention to those skilled in the art.

Therefore, the shape of the elements in the drawings and the like may be exaggerated to emphasize a more clear description. It should be noted that the same members in each drawing are sometimes shown with the same reference numerals.

1 is a perspective view according to the invention, Figure 2 is a front schematic view according to the present invention, Figure 3 is a perspective view showing a friction rotor according to the present invention, Figure 4 is a first, Figure 2 is a schematic cross-sectional view showing a first embodiment showing a friction hole, Figure 5 is a schematic cross-sectional view showing a second embodiment showing a first, second friction through hole of the friction rotor according to the present invention, Figure 6 Figure 3 is a schematic cross-sectional view showing a third embodiment showing the first and second friction through holes of the friction rotor, Figure 7 is a schematic diagram showing a friction protrusion on the friction rotor according to the present invention.

Fluid heating device through the fluid friction heat according to the present invention will be described in detail with reference to those shown in Figures 1 to 7.

Fluid heating apparatus through the fluid friction heat according to the present invention is the first case (10a), the second case (10b), the rotating shaft 20, the motor 30, the friction rotor 40, the connection pipe It consists of 50 and the liquid fluid tank (60).

The first case 10a is preferably formed in a cylindrical shape, but the shape of the first case 10a is not limited, and the fluid heating inner space c is formed in the first case 10a.

The fluid heating inner space (c) is composed of a space for heating the liquid fluid.

The inlet (a) is provided on the right side of the first case (10a) and the outlet (b) is provided on the left side.

The first case 10a is preferably made of a material such as a metal that can withstand high speed rotation, and is preferably made of a structure in which a liquid fluid supplied to the fluid heating inner space part c is not leaked.

The first case 10b is preferably formed in a cylindrical shape, but the shape of the first case 10b is not limited, and the fluid heating inner space c is formed inside the first case 10b.

The fluid heating inner space (c) is composed of a space for heating the liquid fluid.

The inlet (a) is provided on the right side of the second case (10b) and the outlet (b) is provided on the left side.

The second case 10b is preferably made of a material such as a metal that can withstand high speed rotation, and preferably has a structure in which the liquid fluid supplied to the fluid heating inner space part c is not leaked.

The first and second cases 10a and 10b and the motor 30 are installed on the upper surface of the pedestal 80.

The inlet (a) and the outlet (b) of the second case (10b) for the inlet and discharge of the liquid fluid for heating the liquid fluid when the fluid heating device of the present invention is used in a heating system or a power generation system, etc. It is used for piping by installing connecting piping.

The rotation shaft 20 is installed to be separated from the first and second drive shafts 31a and 31b of the motor 30.

The rotating shaft 20 is disposed and installed in the longitudinal direction on the center line of the fluid heating inner space (c) of the first case (10a).

It is configured to be installed so as to rotate at high speed integrally with the connecting shaft (d) extending to the outside of the left side of the first case (10a).

In addition, the rotation shaft 20 is disposed in the longitudinal direction on the center line of the fluid heating inner space (c) of the second case (10b) is installed.

It is configured to be installed so as to rotate at high speed integrally with the connecting shaft (d) extending to the outside of the right side of the second case (10b).

The rotating shaft 20 is connected to the motor 30 is configured to rotate at high speed.

Portions of the first and second cases 10a and 10b through which the rotating shaft 20 penetrates are preferably sealed so that liquid fluid does not leak. Such sealing should not be prevented from rotating in the rotating shaft 20.

To this end, a bearing (not shown) is preferably provided in each of the hollows formed in the first and second cases 10a and 10b supporting the rotating shaft 20 to reduce frictional force when the rotating shaft 20 is rotated. .

In addition, in order to prevent leakage or leakage of the liquid fluid stored in the fluid heating inner space (c) of the first and second cases (10a, 10b) in the hollow oil seal (between the hollow and the rotating shaft 20) Not shown) is preferably provided. Since the configuration of the bearing and the oil seal can be easily implemented by a technique known to the public, detailed description thereof will be omitted.

The motor 30 is installed between the first and second cases 10a and 10b.

In addition, the motor 30 is configured to be provided with a first driving shaft 31a on the left side to be connected to the connecting shaft d of the first case 10a.

The motor 30 has a second driving shaft 31b on the right side thereof to be connected to the connection shaft d of the second case 10b.

The motor 30 is preferably composed of a motor that is rotated at high speed.

Meanwhile, the first driving shaft 31a of the motor 30 and the connection shaft d of the first case 10a are connected to each other by a first connecting member 70a.

In addition, the second driving shaft 31b of the motor 30 and the connecting shaft d of the second case 10b are connected to each other by a second connecting member 70b.

As described above, the first and second drive shafts 31a and 31b of the motor 30 and the connection shafts d of the first and second cases 10a and 10b are formed by the first and second connection members 70a and 70b. Connecting the to facilitate the disassembly and coupling of the first and second cases (10a, 10b) and the motor 30 to facilitate the manufacture, repair, transportability.

The friction rotor 40 is fixed to the outer periphery of the rotary shaft 20 of the first case (10a) a plurality or more fixed to the fluid by the high-speed rotation in the fluid heating inner space (c) and Heated by the friction is configured to discharge through the outlet (b) of the first case (10a).

In addition, the friction rotor 40 is fixed to the outer periphery of the rotary shaft 20 of the second case (10b) a plurality or more fixed to the liquid fluid by the high-speed rotation in the fluid heating inner space (c) It is configured to be discharged through the outlet (b) of the second case (10b) by heating by compression and friction.

On the other hand, the friction rotor 40 is composed of a main body 40a formed in the shape of a disk plate.

A coupling hole 41 is formed at the center of the main body 40a to be coupled to the rotation shaft 20.

Concave grooves 42 are formed at a distance from both sides of the outer side of the coupling hole 41 is formed.

 A plurality of first friction through holes 43 are formed at the edge of the main body 40a.

A plurality of second friction through holes 44 are formed on the outer circumferential surface of the main body 40a.

The first friction through hole 43 and the second friction through hole 44 are connected to each other.

The plurality of first and second friction through holes 43 and 44 are formed in the friction rotor 40 so that the friction rotor 40 generates centrifugal force at a high speed so as to rotate the first and second friction through holes ( 43, 44) is a liquid fluid is caught and rubbed to generate friction heat more easily and efficiently.

In addition, a plurality of friction protrusions 42a are formed on the upper surface of the recess 42.

As described above, the plurality of friction protrusions 42a are formed on the upper surface of the groove portion 42, when the friction rotor 40 rotates at high speed, the friction protrusions 42a are the first and second frictions. In order to generate friction heat more efficiently by causing friction with the liquid fluid together with the through holes 43 and 44.

In addition, the first friction through hole 43 is formed in the shape of the left light right narrow.

The first friction through hole 43 has a left hole 43a and a right hole 43b having different heights, and the inclined hole 43c such that the left hole 43a and the right hole 43b are connected to each other. It is formed and configured.

As described above, the first friction through hole 43 is formed of the left light right narrow, the left and right holes 43a and 43b, and the inclined hole 43c, when the friction rotor 40 rotates at high speed. This is to generate friction heat more efficiently by causing the liquid fluid to crush through the first friction through holes 43.

In addition, the second friction through hole 44 is inclined portion 44a is formed to be inclined is configured to be connected to the first friction through hole 43.

As described above, the second friction through hole 44 is inclined portion 44a is formed to be inclined to be configured to be connected to the first friction through hole 43 when the friction rotor 40 rotates at high speed, The liquid fluid more efficiently rubs against the inclined portion 44a connecting the first and second friction through holes 43 and the first and second friction through holes 43 and 44 to generate friction heat more efficiently. For sake.

The connecting pipe 50 is configured by connecting the outlet (b) of the first case (10a) and the inlet (a) of the second case (10b) with each other.

The connection pipe 50 is a high temperature by heating the liquid fluid in the second case (10b) and the first heated liquid fluid after heating the liquid fluid first in the first case (10a) This is to generate the liquid fluid more quickly.

The liquid fluid tank 60 is provided on the left side to be connected to the outlet (b) to supply the liquid fluid to the inlet (a) of the first case (10a), the inlet (a) is provided on the right side do.

The inlet port (a) of the first case (10a) and the outlet port (b) of the liquid fluid tank 60 is configured by a connection pipe (90).

In addition, the inlet (a) of the liquid fluid tank 60 is also configured to be connected to the pipe (90).

The present invention described above is connected to the rotating shaft 20 of the first case 10a which is connected to the motor 30 and rotates at high speed, and the friction ash having the first and second friction through holes 43 and 44. The electron 40 is heated by the high-speed rotation in the fluid heating inner space (c), the liquid fluid is heated by centrifugal force, vortex and frictional heat to heat the liquid fluid primarily and the first heated liquid fluid again the motor (30) Is connected to the rotary shaft 20 of the second case 10b which is rotated at a high speed, and the friction rotor 40 having the first and second friction through holes 43 and 44 is inside the fluid heating. In the space part (c) by the high-speed rotation by centrifugal force, vortex and frictional heat secondly to heat the liquid fluid 1,2, to produce a high-temperature liquid fluid efficiently and quickly and smoothly.

The embodiments according to the present invention described above are merely exemplary, and those skilled in the art will appreciate that various modifications and equivalent other embodiments are possible therefrom. . Therefore, it will be understood that the present invention is not limited to the forms mentioned in the detailed description.

Therefore, the true technical protection scope of the present invention will be defined by the technical spirit of the appended claims. It is also to be understood that the present invention includes all modifications, equivalents and substitutions within the spirit and scope of the invention as defined by the appended claims.

10a: first case 10b: second case
20: rotating shaft 30: motor
31a: first drive shaft 31b: second drive shaft
40: friction rotor 40a: main body
41: coupling hole 42: groove
42a: friction protrusion 43: first friction hole
43a: left hand 43b: right hand
43c: inclined hole 44: second friction through
44a: slope 50: connector
60: liquid fluid tank 70a: first connecting member
70b: second connecting member a: inlet
b: outlet c: fluid heating internal space
d: connecting shaft

Claims (3)

First and second cases (10a and 10b) having an inlet (a) on the right side and an outlet (b) on the left side and having a fluid heating inner space (c) therein for heating the fluid;
The first and second cases 10a and 10b are disposed in a longitudinal direction on the center line of the fluid heating inner space c and are installed on the left side of the first case 10a and the second case 10b. A rotating shaft 20 which is installed to be rotatable at a high speed integrally with the connecting shafts d respectively extended to the outside of the right side of the;
It is installed between the first and second cases (10a, 10b), the first driving shaft 31a is provided on the left side to be connected to the connecting shaft (d) of the first case (10a), the second case ( A motor 30 having a second drive shaft 31b on its right side to be connected to the connection shaft d of 10b;
It is fixed to the outer periphery of the rotary shaft 20 of the first and second cases (10a, 10b) a plurality or more are heated liquid by compression and friction by high-speed rotation in the fluid heating inner space (c) A friction rotor 40 installed to discharge through the outlets of the first and second cases 10a and 10b;
A connecting pipe 50 connecting the outlet (b) of the first case (10a) and the inlet (a) of the second case (10b) with each other:
It is provided on the left side to be connected to the outlet (b) to supply the liquid fluid to the inlet (a) of the first case (10a), and is composed of a liquid fluid tank 60 having the inlet (a) on the right side Fluid heating device through a fluid friction heat, characterized in that. The method of claim 1,
The friction rotor 40 has a main body 40a formed in the shape of a disc plate, and a coupling hole 41 is formed at the center of the main body 40a to be coupled to the rotation shaft 20, and the coupling hole 41 is formed. A recess 42 having a plurality of friction protrusions 42a is formed on the upper surface at a distance from both side outer edges of the plurality of second friction holes 44 formed on the outer circumferential surface of the main body 40a. The first friction through hole 43 or the left hole 43a and the right hole 43b are formed at different heights, and the left hole 43a and the right hole 43b are connected to each other. The inclined hole (43c) is formed, and the first friction through hole (43) and the second friction through hole (44) is a fluid heating device through a fluid friction heat, characterized in that connected to each other. The method of claim 1,
The first driving shaft 31a of the motor 30 and the connecting shaft d of the first case 10a are connected to each other by a first connecting member 70a, and the first driving shaft 31 of the motor 30 is connected to the first driving shaft 31a. The second drive shaft (31b) and the connecting shaft (d) of the second case (10b) is a fluid heating device through a fluid friction heat, characterized in that configured by being connected to the second connecting member (70b).

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