KR101549332B1 - fluid pressure turbine - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a fluid pressure turbine, and more particularly, to a fluid pressure turbine that allows a fluid to convert rotational energy of an impeller into kinetic energy flowing by a drop (position energy) and a pressure difference for commercial use .
A fluid pressure turbine of the present invention comprises: a housing which is a conduit through which fluid flows; A first rotation shaft mounted to the front end of the inside of the housing in the longitudinal direction; A second rotation shaft mounted in the longitudinal direction at a rear end of the inside of the housing; A first impeller spirally formed on the circumference of the first rotation shaft; A second impeller spirally formed on the circumference of the second rotation shaft; A rotor mounted between the first rotary shaft and the second rotary shaft in the longitudinal direction and rotated by the first rotary shaft and the second rotary shaft; Wherein the housing comprises: a first rectilinear tube formed in a straight line and having the first impeller disposed on the first rotating shaft; A second rectilinear tube formed in a straight shape and having the second impeller disposed on the second rotary shaft; A bending tube in which a first bending groove in which the rotor is mounted is formed at one side and the first rotation axis and the second rotation axis are rotatably mounted while communicating the first rectilinear tube and the second rectilinear tube; And a control unit.

Description

[0001] The present invention relates to a fluid pressure turbine,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a fluid pressure turbine, and more particularly, to a fluid pressure turbine that allows a fluid to convert rotational energy of an impeller into kinetic energy flowing by a drop (position energy) and a pressure difference for commercial use .

Recently, due to the rapid demand of energy, the shortage of fossil fuels such as coal, oil and natural gas has deepened, and environmental pollution is gradually becoming a social problem. To solve these problems, various eco- There is growing interest in energy sources.

There are various methods such as hydroelectric power generation using water level difference, wind power generation using wind, solar power generation using solar energy, and tidal power generation using tidal force generated from the sea as a method of obtaining energy using natural environment .

These power generation facilities generate electric energy by rotating or rotating the turbine or windmill into rotational energy using kinetic energy that flows naturally or forcibly as the fluid flows by falling and pressure difference.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a view showing a configuration of a fluid pressure turbine that converts kinetic energy generated by a conventional fluid flowing through a drop or pressure difference into rotational energy. FIG.

As shown in FIG. 1, a conventional fluid pressure turbine includes an outer casing 10; An aberration 30 that is disposed inside the outer casing 10 and includes a rotary blade 32 having a spiral structure and an auger shaft 31 for fixing the rotary blade 32; An aberration fixing table (20) for fixing the aberration axis (31) to the outer casing (10); And a power transmission shaft 60 connected to the aberration 30 and rotated.

However, in the conventional fluid pressure turbine, the power transmission shaft 60 mounted in a direction orthogonal to the airstream axis 31 and the aberration fixing table 20 for fixing the airstream axis 31 to the inside of the outer casing 10 Is disposed in a direction orthogonal to the direction in which the fluid flows in the outer casing 10, thereby obstructing the flow of the fluid, thereby failing to efficiently convert the energy.

A conventional fluid pressure turbine is disclosed in Japanese Patent Application Laid-Open No. 10-2007-0021292.

SUMMARY OF THE INVENTION The present invention has been made in order to solve the above-mentioned problems, and it is an object of the present invention to provide a bending tube in which a rotating shaft, on which an impeller is formed, The present invention relates to a fluid pressure turbine capable of efficiently converting kinetic energy flowing through a rotor into rotational energy of an impeller.

According to an aspect of the present invention, there is provided a fluid pressure turbine including: a housing which is a conduit through which fluid flows; A first rotation shaft mounted to the front end of the inside of the housing in the longitudinal direction; A second rotation shaft mounted in the longitudinal direction at a rear end of the inside of the housing; A first impeller spirally formed on the circumference of the first rotation shaft; A second impeller spirally formed on the circumference of the second rotation shaft; A rotor mounted between the first rotary shaft and the second rotary shaft in the longitudinal direction and rotated by the first rotary shaft and the second rotary shaft; Wherein the housing comprises: a first rectilinear tube formed in a straight line and having the first impeller disposed on the first rotating shaft; A second rectilinear tube formed in a straight shape and having the second impeller disposed on the second rotary shaft; A bending tube in which a first bending groove in which the rotor is mounted is formed at one side and the first rotation axis and the second rotation axis are rotatably mounted while communicating the first rectilinear tube and the second rectilinear tube; And a control unit.

According to the fluid pressure turbine of the present invention as described above, the following effects can be obtained.

A bent groove is formed on the outside of the housing to form a bent groove in which a rotating shaft having the impeller is mounted as it is in the longitudinal direction so that the direction of the flow of the fluid with the rotating shaft is not large and the rotor or the like is disposed outside the housing So that it is possible to efficiently convert the kinetic energy flowing through the fluid into the rotational energy of the impeller by minimizing the disturbance of the flow of the fluid.

In addition, since the disturbance of the fluid flow is minimized, even when the fluid passes through the housing, there is almost no change in the flow velocity of the fluid, so that the fluid pressure turbine is continuously installed, It is possible to convert the image data into the image data.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a view showing a configuration of a fluid pressure turbine which converts kinetic energy generated by a conventional fluid flowing through a drop and pressure difference into rotational energy. FIG.
2 is a cross-sectional view showing the overall structure of a fluid energy changing device according to an embodiment of the present invention;
3 is a cross-sectional view illustrating the structure of a housing in a fluid pressure turbine according to an embodiment of the present invention.
FIGS. 4 to 6 are diagrams illustrating an example of a use state of a fluid pressure turbine according to an embodiment of the present invention; FIG.

FIG. 2 is a cross-sectional view showing the overall structure of a fluid energy varying device according to an embodiment of the present invention, and FIG. 3 is a sectional view showing the structure of a housing in a fluid pressure turbine according to an embodiment of the present invention.

2 and 3, a fluid pressure turbine according to an embodiment of the present invention includes: a housing 100 as a conduit through which fluid flows; A first rotating shaft 200 mounted to the front end of the inside of the housing 100 in the longitudinal direction; A second rotation shaft 300 mounted to the rear end of the interior of the housing 100 in the longitudinal direction; A first impeller 400 spirally formed on the circumference of the first rotary shaft 200; A second impeller 500 spirally formed on the circumference of the second rotation shaft 300; A rotor (600) mounted between the first rotation axis (200) and the second rotation axis (300) in the longitudinal direction and rotated by the first rotation axis (200) and the second rotation axis (300); A sealing member 700 mounted on an outer peripheral edge of the first impeller 400 and the second impeller 500 and contacting the inner circumference of the housing 100; A gear box 900 connected to the rotor 600 to change rotational speed; And a control unit.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

In the present invention, the flow of a fluid means that air or water flows by a camel, that is, a potential energy or a pressure difference.

In the present invention, the fluid includes air and water. Double water is more than 800 times denser than air and it is preferable to use water rather than air.

The housing 100 is formed in the shape of a pipe through which the fluid flows.

2, the first rotating shaft 200, the second rotating shaft 300, the first impeller 400, the second impeller 500, and the sealing member 700 are installed inside the housing 100 Respectively.

The rotor 100 is connected to the first rotary shaft 200 and the second rotary shaft 300 through the rotator 600 and the gear box 600 connected to the rotor 600. [ 900 and the like.

The housing 100 includes a first rectilinear tube 110, a second rectilinear tube 120, and a bending tube 130.

2, the first rectilinear tube 110 is formed in a straight shape and the first impeller 400 formed on the first rotary shaft 200 is disposed.

The second rectilinear tube 120 is formed in a straight shape as shown in FIG. 2, and the second impeller 500 formed on the second rotary shaft 300 is disposed.

The bending pipe 130 is formed at one side with a bending groove 131 in which the rotor 600 is mounted and communicates with the first rectilinear tube 110 and the second rectilinear tube, (200) and the second rotation shaft (300) are rotatably mounted.

That is, the first straight pipe 110 and the second straight pipe 120 are communicated with each other between the first straight pipe 110 and the second straight pipe 120 in the bending pipe 130, The first rotation axis 200 and the second rotation axis 300 are rotatably mounted while the first rotation axis 200 and the rotation center line of the second rotation axis 300 are arranged on a straight line.

Therefore, the rotor 600 is mounted in the bending groove 131 formed in the bending pipe 130.

The bending pipe 130 connects the first rectilinear pipe 110 and the second rectilinear pipe 120 between the first rectilinear pipe 110 and the second rectilinear pipe 120, The first rotation axis 200 and the second rotation axis 300 are rotatably mounted while the first rotation axis 200 and the rotation center line of the second rotation axis 300 are arranged on a straight line, (600) is mounted to the outside of the housing (100), the interference of the flow of the fluid flowing inside the housing (100) can be minimized and the energy can be efficiently converted.

The bending pipe 130 is formed in a "V" shape or a "U" shape. Is shown in the "V" shape in the embodiment of the present invention.

Unlike the present embodiment, the bending pipe 130 is mounted such that the first rotation axis 200 and the second rotation axis 300 are disposed so as to be aligned with the rotation center line, It may be formed in any shape as long as it is connected to the first rotation shaft 200 and the second rotation shaft 300 from the outside of the housing 100 and can rotate.

The first rotating shaft 200 is mounted to the front end of the housing 100 in the longitudinal direction.

2, the first rotary shaft 200 is installed in the longitudinal direction of the first rectilinear tube 110, and the rear end of the first rotary shaft 200 is connected to the bent groove 130 of the bending pipe 130 131 of the bending tube 130. The bending tube 130 is rotatably mounted on the bending tube 130 so as to be exposed.

The first impeller 400 is mounted on the first rotary shaft 200 and rotated by the fluid flowing through the first linear pipe 110.

The second rotary shaft 300 is mounted longitudinally at the rear end of the interior of the housing 100.

2, the second rotary shaft 300 is installed in the longitudinal direction of the second rectilinear tube 120, and the front end of the second rotary shaft 300 is connected to the bent groove 130 of the bending pipe 130 131 of the bending tube 130. The bending tube 130 is rotatably mounted on the bending tube 130 so as to be exposed.

The second impeller 500 is mounted on the second rotary shaft 300 and rotated by the fluid flowing through the second rectilinear tube 120.

The rotation axis line of the first rotation axis 200 and the rotation axis of the second rotation axis 300 are arranged in a straight line.

The front end of the first rotation shaft 200 and the rear end of the second rotation shaft 300 are mounted on the bending pipe 130 while being exposed to the bending groove 131 so that the rotation shaft 200, It is possible to minimize disturbance of the flow of the fluid even if the fluid contacts the first rotation axis 200 and the second rotation axis 300 because the angle between the direction of flow of the fluid and the direction of flow of the fluid is large.

The first impeller 400 is spirally formed on the circumference of the first rotating shaft 200 as shown in FIG.

The first impeller 400 is pushed as the fluid flowing through the first rectilinear pipe 110 flows, thereby rotating the first rotary shaft 200.

The second impeller 500 is formed in a spiral shape on the circumference of the second rotation shaft 300.

The second impeller 500 is pushed as the fluid flowing through the second rectilinear pipe 120 flows, thereby rotating the second rotary shaft 300.

As described above, the first impeller 400 and the second impeller 500 are formed in a spiral shape and rotate by the flow of the fluid, so that the first rotary shaft 200 and the second rotary shaft 500 can be minimized, The first impeller 400 and the second impeller 500 can be rotated even in a weak fluid flow to obtain rotational energy.

The first and second impellers 400 and 500 may be separated from each other at the first and second rotary shafts 200 and 300 to facilitate replacement and repair of the first and second impellers 400 and 500.

The first and second impellers 400 and 500 may be integrally formed on the first and second rotating shafts 200 and 300, as in the case of this embodiment.

The rotor 600 is mounted between the first rotating shaft 200 and the second rotating shaft 300 in the longitudinal direction and rotated by the first rotating shaft 200 and the second rotating shaft 300.

More specifically, the rotor 600 is rotatably mounted on the bending pipe 130 as shown in FIG. 2, and the rotation center line is positioned on the straight line, and the rotor 600, which is exposed to the bending groove 131, Is mounted on the rear end of the first rotary shaft 200 and the front end of the second rotary shaft 300 and is rotated by the first rotary shaft 200 and the second rotary shaft 300.

As the rotor 600 is mounted to the bent groove 131 outside the housing 100, the flow of the fluid flowing through the housing 100 is not disturbed.

The rotation center line of the rotor 600 is disposed on a straight line with the rotation center line of the first rotary shaft 200, the second rotary shaft 300, the first rectilinear tube 110 and the third rectilinear tube. do.

The rotation center line of the rotor 600, the first rotation axis 200, the second rotation axis 300, the first rectilinear tube 110, and the third rectilinear tube are arranged in a straight line, The first impeller 400 and the second impeller 500 are arranged in a straight line so that the rotational center line of the first impeller 400 and the second impeller 500 are also aligned with each other, Since the second impeller 500 is rotated again by the fluid that rotates the first impeller 400, a greater rotational force can be obtained.

The gear box 900 is connected to the rotor 600 to change rotational speed.

More specifically, the gear box 900 receives the rotational force of the rotor 600 so as to apply a force and a rotational speed required for other mechanical devices, such as a cone presser, a generator, and the like, and transmits the rotational force to another mechanical device.

It is possible to connect another mechanical device to the rotor 600 directly without the gear box 900, unlike the present embodiment.

The sealing member 700 is mounted on the outer circumferential end of the first impeller 400 and the second impeller 500 and contacts the inner circumference of the housing 100.

More specifically, the sealing member 700 may fill a space between the first and second impellers and the interior of the housing 100 as shown in FIG. 2 to prevent fluid from passing therethrough, Thereby allowing the first and second impellers 400 and 500 to rotate more smoothly.

Such a sealing member 700 can be bent smoothly when it comes into contact with the projection 101 described later and can be bent naturally by the fluid flow without affecting the rotation of the first and second impellers 400 and 500 Soft fur or soft cloth material.

On the other hand, a spiral protrusion 101 is formed on the inner circumference of the housing 100 as shown in FIG. 2 and FIG.

The protrusion 101 is formed in the same direction as the rotation direction of the first impeller 400 and the second impeller 500 to rotate the fluid flowing in the housing 100, ) To reduce the friction with the inner periphery.

As shown in FIG. 2, a filter 800 for filtering foreign substances is mounted on the front end of the housing 100 through which the fluid flows.

The filter 800 is formed in a conical shape having a better width toward the end.

As the filter 800 is formed in a conical shape, the filter 800 can be prevented from interfering with the flow of the fluid flowing into the housing 100 even if foreign substances are caught by the filter 800 because the area of the filter 800 is wide .

In this embodiment, the filter 800 is formed in a conical shape having a smaller width in the direction opposite to the flow direction of the fluid so that foreign matter does not enter the inside of the housing 100 by the filter 800, 100, but it may be formed in a conical shape having a smaller width in the flow direction of the fluid, unlike the present embodiment.

However, if the filter 800 is formed to have a smaller width in the direction of flow of the fluid, the foreign material is collected at the end of the filter 800 and interferes with the flow of the fluid. Therefore, It is preferable to make the width narrower in the opposite direction so as to prevent foreign matter from collecting in the filter 800.

2, the front end of the housing 100 is widened in a direction opposite to the direction in which the fluid flows into the housing 100, so that the fluid flows into the housing 100 more easily .

A valve (103) is mounted on the front end of the housing (100) to adjust the amount of fluid flowing into the housing (100).

The valve 103 may be mounted on the rear end of the housing 100 to control the amount of fluid flowing out of the housing 100, as in the present embodiment.

In addition, it is preferable to cover the bending groove 131 with a lid 102 to protect the rotor 600 and the gear box.

The operation of the fluid pressure turbine of the present invention having such a structure and the operating state thereof will be described.

2, the fluid flows from the first impeller 400 disposed in the first rectilinear tube 110 through the filter 800 to the first impeller 400, Thereby rotating the first rotating shaft 200.

The fluid then moves to the second rectilinear tube 120 through the bending tube 130 and the fluid moved to the second rectilinear tube 120 pushes the second impeller 500, 2 rotation shaft 300 is rotated, and then is discharged to the outside from the housing 100.

When the fluid passes through the housing 100, rotation is generated by the protrusion 101 formed in the housing 100, and the fluid passes through the inside of the housing 100 while rotating, The friction with the inside of the housing 100 is reduced.

The first rotary shaft 200 and the second rotary shaft 300 that are rotated by the fluid pushing the first and second impellers 400 and 500 rotate the rotor 600 mounted on the bending groove 131 And the rotational force of the rotor 600 is changed by the gear box 900 so that the force and the rotational speed are transmitted to the other mechanical device.

FIGS. 4 to 6 are views illustrating a use state of a fluid pressure turbine according to an embodiment of the present invention.

4, when the housing 100 is fixed to the float A, fluid is supplied to the housing 100 in a state where the flow of the natural fluid such as a bird or a river is converted into rotational energy. To change the fluid energy.

In case of using in a dam, it is installed in a part discharged from the dam as shown in FIG. 5, and kinetic energy of the fluid can be converted into rotational energy.

Since the fluid pressure turbine of the present invention minimizes the interference of the fluid flow as described above, it is possible to connect several fluid energy change devices to the sockets S and convert the fluid energy into a plurality of rotational energies with a single kinetic energy And can generate more rotational energy.

In addition, as shown in FIG. 6, a plurality of the present invention may be connected to the discharge port through which the air is discharged from the pneumatic energy storage device using the water pressure developed by the present inventor, thereby converting the pneumatic energy into rotational energy.

The fluid pressure turbine of the present invention is not limited to the above-described embodiments, and can be variously modified and practiced within the scope of the technical idea of the present invention.

100: housing 101: projection 102: cover
103: valve 110: first rectilinear tube 120: second rectilinear tube
130: Bending pipe 131: Bending groove 200: First rotary shaft
300: second rotating shaft 400: first impeller 500: second impeller
600: rotor 700: sealing member 800: filter
900: gear box A: float S: socket

Claims (12)

A housing as a conduit through which the fluid moves;
A first rotation shaft mounted to the front end of the inside of the housing in the longitudinal direction;
A second rotation shaft mounted in the longitudinal direction at a rear end of the inside of the housing;
A first impeller spirally formed on the circumference of the first rotation shaft;
A second impeller spirally formed on the circumference of the second rotation shaft;
A rotor mounted between the first rotary shaft and the second rotary shaft in the longitudinal direction and rotated by the first rotary shaft and the second rotary shaft; , ≪ / RTI &
The housing includes:
A first rectilinear tube formed in a straight shape and having the first impeller disposed on the first rotary shaft;
A second rectilinear tube formed in a straight shape and having the second impeller disposed on the second rotary shaft;
A bending tube in which a first bending groove in which the rotor is mounted is formed at one side and the first rotation axis and the second rotation axis are rotatably mounted while communicating the first rectilinear tube and the second rectilinear tube;
And a sealing member mounted on an outer circumferential end of the first impeller and the second impeller and contacting the inner circumference of the housing.
The method according to claim 1,
The bending pipe
"V" or "U " shape.
The method according to claim 1,
Wherein the first rotation axis, the second rotation axis, the first rectilinear tube, the second rectilinear tube, and the rotational center line of the rotor are disposed on a straight line.
delete The method according to claim 1,
The sealing member
Characterized in that it is a soft bristle or a soft cloth material.
The method according to claim 1,
And a spiral protrusion is formed on an inner circumference of the housing.
The method of claim 6,
Wherein the rotation direction of the projection is the same as the rotation direction of the impeller.
The method according to claim 1,
Wherein a filter for filtering foreign matter is mounted on a front end of the housing through which the fluid flows.
The method of claim 8,
Wherein the filter is formed in a conical shape having a narrower width toward an end.
The method according to claim 1,
A gear box connected to the rotor to change the rotation speed; ≪ / RTI >
The method according to claim 1,
Wherein the housing is equipped with a valve for controlling an inflow amount of fluid flowing into the housing.
The method according to claim 1,
Wherein the housing is connected to each other by a socket, and a plurality of the housing are arranged in series.

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