KR101772017B1 - No-axis pipe type generator - Google Patents

Abstract

The present invention relates to a non-axis pipe-type generator and, more specifically, to a non-axis pipe-type generator, which is installed between the cut pipes in a manner that cuts a pipe buried underground or a pipe formed to allow a fluid to flow on the ground or inside the building, so as to produce electricity by a flow of the fluid, and which is configured to, when the pipe-type generator is replaced due to being worn out or damaged, or the like, separate and replace only the pipe-type generator by connecting the pipe and the pipe-type generator with flanges, thereby providing ease of replacement.

Description

[0001] The present invention relates to a No-axis pipe type generator,

More particularly, the present invention relates to a non-condensed piped-type generator, and more particularly, to a non-condensed piped-type generator, in which a large-sized piping buried in an underground or a pipeline formed by flowing a fluid inside the building or inside the building, And the piping generator is connected to the flange to replace the piping generator when the piping generator is replaced due to aging or breakage of the piping generator. Thus, an unshaped pipeline generator Lt; / RTI >

Generally, a power generation device is a device that converts various energy sources into electric energy. Power generators use hydro, thermal and nuclear power depending on the energy source.

Among the energy sources, hydroelectric power generation is a method of obtaining electricity by utilizing the electromagnetic induction phenomenon in the generator by converting the position energy of water located at a high place into kinetic energy of the generator turbine.

Generally, for hydroelectric power generation, a dam is formed by blocking the river, water is confined upstream of the dam, and the water gate is opened to turn the turbine by dropping water to the downstream of the dam. In this process, the energy of the water is converted into the kinetic energy of the turbine, and the rotor coil inside the turbine rotates along the turbine, generating current through electromagnetic induction. At this time, the kinetic energy of the turbine is converted into electric energy.

In the case of hydroelectric power generation, in order to increase the power generation capacity, the water has to have a larger potential energy, so a large amount of water must be secured in the dam in order to secure a large free fall.

However, hydropower generation requires large-scale facilities, and the power generation efficiency is lowered when the rain does not come to the upstream of the dam for a long period of time.

In recent years, interest in energy has become more and more eco-friendly, and power generation methods capable of increasing utilization of resources have been studied. In this respect, new power generation methods using fluid such as hydroelectric power and wind power have been attracting attention.

There are limitations in the method currently used for general hydroelectric power generation, wind power generation, and tidal power generation.

The technology disclosed in the prior art document is a device for generating electricity by rotating a rotating body using fluid through a pipe and returning a motor shaft connected to the rotating body.

However, since the prior art requires a power generating motor in addition to the piping construction, it causes a considerable cost and requires a space for installation.

Korean Patent No. 10-0955083 A generator using fluid piping

According to an aspect of the present invention, there is provided a piping system including a large-sized piping buried in a basement or a piping formed on a ground or inside a building to allow fluid to flow therein, To produce electricity by the flow rate of the gas.

The present invention aims at providing ease of replacement by connecting only the piping type generator to the piping type generator by connecting the piping and the piping type generator to the flange and replacing the piping type generator when the piping type generator is replaced due to aging or breakage.

In order to accomplish the above object, an unshaped pipe-type generator (10) that generates rotational power from a fluid flowing through a pipe (100)

A permanent magnet (220) is formed on the outer surface, a helical screw (230) is formed on the inner surface, and a rotor (300) is formed by rotating the stator (300) Means (200);

The stator unit 500 includes a flange 500 fixedly connected to the pipe 100 and a coil 330 formed on the inner surface of the flange 500. The stator unit 500 generates electricity when the rotor unit 200 rotates, (300);

Bearing means (400) serving as a rotation guide for rotating the rotor means (200) relative to the fixed stator means (300);

And a flange 500 welded to the pipe 100 for connection between the pipe 100 and the stator 300 and bolted to the stator 300.

The present invention relates to a large-sized pipe embedded in an underground or a pipe formed to flow fluid on the ground or inside a building, and a pipe-type generator is installed between pipes cut by cutting the pipe to produce electricity So that the power supply is smooth and the cost of electricity supply can be reduced.

In addition, when the piping type generator is connected to the flange, the piping type generator is separated and replaced when the piping type generator is replaced due to aging or breakage, thereby providing an easy replacement effect.

1 is a perspective view of an unshaped pipe-type generator according to the present invention.
2 is a partial cross-sectional perspective view of the unshrunk pipe type generator of the present invention.
3 is an exploded perspective view of the unshaped pipe-type generator of the present invention.
4 is a perspective view of a spiral screw for a non-condensing tubular generator of the present invention.
5 is a cross-sectional view of the unshaped pipe-type generator of the present invention.
6 is a state diagram of the unshaped tubular generator of the present invention.
7 is a state diagram of a spiral groove for the unshaped tubular generator of the present invention.

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

A non-axial piping generator (10) of the present invention includes a piped generator (10) provided between piping (100) cut by cutting a piping (100) through which a fluid flows, And the means 200 is rotated to produce electricity.

The non-axial piping generator (10) of the present invention is characterized in that the stator means (300) is fixed to the piping (100), the bearing means (400) is formed in the stator means (300) (200) is connected to the stator means (300) so that the rotor means (200) is rotated via the bearing means.

≪ Example 1 >

1 to 5, the present invention relates to a non-condensed pipe-type power generator 10 that is generated by receiving rotational power from a fluid flowing through a pipe 100,

A permanent magnet (220) is formed on the outer surface, a helical screw (230) is formed on the inner surface, and a rotor (300) is formed by rotating the stator (300) Means (200);

The stator unit 500 includes a flange 500 fixedly connected to the pipe 100 and a coil 330 formed on the inner surface of the flange 500. The stator unit 500 generates electricity when the rotor unit 200 rotates, (300);

Bearing means (400) serving as a rotation guide for rotating the rotor means (200) relative to the fixed stator means (300);

And a flange 500 welded to the pipe 100 for connection between the pipe 100 and the stator 300 and bolted to the stator 300.

The rotor means 200 is constituent means for rotating the stator means 300 via the bearing means 400 to form a rotating system.

The rotor means 200 is formed inside the stator means 300 and is arranged between the rotor means 200 and the stator means 300 so that the rotor means 200 is rotated at the inner side of the stator means 300 The bearing means 400 is formed so that the rotor means 200 can be smoothly rotated with respect to the stator means 300 via the bearing means 400. [

The rotational force of the rotor means 200 is obtained by moving the fluid along the wing surface of the helical screw 230 fixed to the inside of the rotor means 200.

The rotor unit 200 includes a rotating tube 210 rotated by a fluid flow, a helical screw 230 for obtaining a rotational power for rotating the rotating tube 210 from the fluid, And a permanent magnet (220) for generating a rotating magnetic field during rotation.

Specifically, the rotor means (200)

A rotary tube 210 having a hollow inside which a fluid can flow and being configured to rotate with respect to the stator means 300 via the bearing means 400;

A plurality of permanent magnets 220 formed on an outer surface of the rotary pipe 210 to form a rotating system when the rotary pipe 210 rotates;

And a helical screw 230 fixed to the inner surface of the rotary tube 210 to obtain rotational power for rotating the rotary tube 210 from the fluid flowing through the hollow of the rotary tube 210 .

The rotary pipe 210 has a cylindrical shape that is formed to pass through the fluid pipe so that the fluid can flow therethrough, and is formed to have the same diameter as the pipe 100.

The rotary pipe 210 is formed between the pipe 100 and the pipe 100 and forms a gap with the pipe 100 so that the rotary pipe 210 is rotated with one side of the pipe 100, So that friction is not generated at one side of the pipe (210).

The rotary tube 210 is fixed to the bearing means 400 formed on the inner side of the stator means 300 and the rotary tube 210 is fixed to the bearing means 400 in a fitting manner, 400 and the rotary pipe 210 so that the rotary pipe 210 is not easily detached from the bearing means 400. [

As shown in FIG. 3, the N permanent magnet 220, the S pole permanent magnet 220, and the N pole permanent magnet 220 are formed on the outer circumferential surface of the rotary pipe 210. ) - > S-pole permanent magnet 220 in this order.

The permanent magnet 220 is attached and coupled to the rotary pipe 210 through one of an adhesive means and a coupling means so as not to be easily detached when the rotary pipe 210 rotates.

3 and 4, the helical screw 230 is twisted from one side to the other side. The helical screw 230 is fixedly coupled along the inner surface of the rotary tube 210, The fluid flowing inside the tube collides with the spiral screw 230 so that a power for rotating the rotary tube 210 is generated.

The rotating tube 210, which is fixedly coupled with the spiral screw 230 by the rotation of the rotating tube 210, rotates along the wing by hitting the wing of the spiral screw 230, And is rotated by the fluid moving along the axis.

The stator unit 300 is connected between the pipe 100 and the pipe 100, and the connection is connected by a flange.

The coil 330 formed on the inner side of the stator means 300 is provided with permanent magnets 220 when rotating the rotor means 200, ) Is generated, the electric power is generated by the electric power generation principle (the principle is a general electricity generation principle and the explanation is omitted).

The connection between the stator unit 300 and the pipe 100 is connected through a flange 500.

The stator means 300 includes a housing 310 formed to house the rotor means 200 therein, a housing cover 320 for fixing the bearing means 400 inserted into both ends of the housing 310, And a coil 330 wound on the inner surface of the housing 310 a plurality of times.

The stator unit 300 further includes a sealing member groove 340 formed at one side of the inner circumferential surface of the housing 310 and the housing cover 320.

 3, the stator means 300 according to the present invention includes a coil 330 formed on an inner surface thereof and a rotor 330 wound around the rotor means 200 to protect the rotor means 200 from the outside A cylindrical housing 310 formed with a first seating end 311 for receiving the bearing means 400;

A second seating end 321 for preventing the bearing means 400 from being detached to the piping 100 side is formed and one side is fixedly coupled to the housing 310 and the other side is connected to the flange 500 and the bolt- A housing cover 320 formed on both sides of the housing 310;

And a coil (330) formed on an inner surface of the housing (310) so as to be able to flow electricity by being generated by a rotating system generated when the rotor means (200) rotates.

The housing 310 is formed between the pipe 100 and the pipe 100 and has a cylindrical shape. A coil 330 is wound on the inner side of the pipe 310 several times and the bearing 310 The first seating end 311 is formed so that the first seating end 311 can be seated.

The first seating end 311 formed on both sides of the housing 310 is formed on the inner side of the housing 310 to prevent friction with the outer circumferential surface of the rotary tube 210 when coupled with the rotor unit 200 And the gap between the rotary pipe 210 and the housing 310 can be formed at a predetermined interval.

That is, the housing 310, the bearing means 400, and the rotary pipe 210 are coupled to each other so that the inner diameter of the housing 310, the inner diameter of the bearing unit 400, and the diameter of the rotary pipe 210 are equal to each other. do.

The housing 310 is coupled to the housing cover 320 coupled to both sides of the housing 310 through bolts or welding.

The housing cover 320 is coupled to both sides of the housing 310 and includes a second seating end 321 for receiving the bearing means 400 coupled to the housing cover 320 at one side of the housing cover 320 Is formed.

The second seating end 321 formed on the housing cover 320 is formed at the same height as the first seating end 311 formed on the housing 310.

That is, the bearing means 400 is accommodated in the space formed by the second seating end 321 formed on the housing cover 320 and the first seating end 311 formed on the housing 310.

The housing cover 320 prevents the bearing means 400 that is seated on the first seating end 311 of the housing 310 from coming off and connects the housing 310 to the flange 500.

The coil 330 is formed on the inner side of the housing 310 and a current is generated by a plurality of permanent magnets 220 formed on the outer surface of the rotary tube 210 by the power generation principle when the rotating magnetic field is generated .

The stator unit 300 includes a housing 310 and a housing cover 320 so as to insert a sealant for preventing water flowing into the rotary pipe 210 from flowing into the housing 310 through the bearing unit 400. [ And a sealing material groove (340) formed on at least one of the inner circumferential surfaces on one side.

The sealing member groove 340 is formed at a predetermined depth on the inner circumferential surface of the first seating end 311 formed on both sides of the housing 310 or the inner circumferential surface of the second seating end 321.

A sealing member (not shown) is inserted into the sealing member groove 340 in order to prevent the fluid from flowing into a gap that may be generated between the bearing means 400 and the rotary pipe 210 due to aging due to the use of the generator. .

Since the sealing material may cause some friction before rotation of the rotary pipe 210 during rotation, it is preferable that the sealing material is formed of a material having a high water-proofing rate and a reduced friction rate.

The bearing means 400 is formed so that the rotor means 200 can be smoothly rotated with respect to the stator means 300. The bearing means 400 is fixed to the stator means 300, And the outer peripheral surface of the rotor means 200 is fitted and fitted to the inner peripheral surface of the means 400.

The bearing means 400 is positioned between the stator means 300 and the rotor means 200 so that the spiral screw 230 formed in the rotor means 200 obtains a rotating clock from the fluid flowing through the pipe , The rotor means (200) rotates with respect to the stator means (200) fixed to the pipe.

The bearing means 400 is fitted to the rotor means 200 so that there is no gap between the rotor means 200 and the bearing means 400 and the fluid is prevented from flowing between the rotor means 200 and the bearing means 400.

The flange 500 is for connecting the pipe 100 and the housing lid 320 and is characterized in that one side of the housing lid 320 and one side of the flange 500 are tightly coupled to each other and then coupled through bolts .

Further, the other side of the flange 500 is welded to the pipe 100.

Therefore, the unshrouded tubular generator 10 of the present invention, which is formed of the rotor unit 200 and the stator unit 300, connects the flange 500 and the stator unit 300 when replacing according to an internal damage or replacement period The entire piping-type generator 10 is replaced except for the flange 500 welded to the piping 100 through the disassembly of the bolts.

≪ Example 2 >

As shown in FIGS. 1 and 7, an unshrouded piping-type generator 10, which is generated by receiving rotational power from a fluid flowing in the piping 100 of the present invention,

A permanent magnet (220) is formed on the outer surface and a helical groove (240) is formed on the inner surface. The rotor (300) rotates relative to the stator means (300) Means (200);

The stator unit 500 includes a flange 500 fixedly connected to the pipe 100 and a coil 330 formed on the inner surface of the flange 500. The stator unit 500 generates electricity when the rotor unit 200 rotates, (300);

Bearing means (400) serving as a rotation guide for rotating the rotor means (200) relative to the fixed stator means (300);

And a flange 500 welded to the pipe 100 for connection between the pipe 100 and the stator 300 and bolted to the stator 300.

The second embodiment of the present invention differs from the spiral screw of the first embodiment only in the portion constituting the helical groove in the rotary tube 210. [

Therefore, description of the same structural features as those of the first embodiment will be omitted, and only the rotor unit 200 which is a difference part will be described.

7, the rotor unit 200 has a cylindrical shape having a hollow inside to allow a fluid to flow therethrough, a rotary pipe 210 formed to rotate with respect to the stator unit 300, and;

A plurality of permanent magnets 220 formed on an outer surface of the rotary pipe 210 to form a rotating system when the rotary pipe 210 rotates;

And a helical groove 240 formed on an inner surface of the rotary tube 210 to obtain rotational power for rotating the rotary tube 210 from the fluid flowing through the hollow of the rotary tube 210 do.

The rotary pipe 210 has a cylindrical shape that is formed to pass through the fluid pipe so that the fluid can flow therethrough, and is formed to have the same diameter as the pipe 100.

The rotary pipe 210 is formed between the pipe 100 and the pipe 100 and forms a gap with the pipe 100 so that the rotary pipe 210 is rotated with one side of the pipe 100, So that friction is not generated at one side of the pipe (210).

The rotary tube 210 is fixed to the bearing means 400 formed on the inner side of the stator means 300 and the rotary tube 210 is fixed to the bearing means 400 in a fitting manner, 400 and the rotary pipe 210 so that the rotary pipe 210 is not easily detached from the bearing means 400. [

As shown in FIG. 3, the N permanent magnet 220, the S pole permanent magnet 220, and the N pole permanent magnet 220 are formed on the outer circumferential surface of the rotary pipe 210. ) - > S-pole permanent magnet 220 in this order.

The permanent magnet 220 is attached and coupled to the rotary pipe 210 through one of an adhesive means and a coupling means so as not to be easily detached when the rotary pipe 210 rotates.

7, the spiral groove 240 is formed on the inner side of the rotary pipe 210, and a groove having a certain depth in the spiral shape in the longitudinal direction of the other side end at one side of the inner side of the rotary pipe 210 Is formed.

A plurality of the helical grooves 240 may be formed. The greater the number of helical grooves, the greater the rotational power.

When the fluid flowing through the rotating tube 210 flows into the spiral groove 240 and flows, the fluid flows in a whirl-like fashion inside the rotating tube 210. As a result, the rotating power is generated, .

That is, the first and second embodiments of the present invention are different from each other in that the rotational power is obtained by a spiral screw or a spiral groove.

6 is a view for explaining the principle of generation of rotational power by the spiral screw 230 of Embodiment 1. Part of the fluid flowing through the rotating tube flows through the rotating tube 210, The rotating tube 210 in which the helical screw 230 is fixed due to frictional resistance of the fluid generated in the helical screw 230 is generated so that frictional resistance is generated by the helical screw 230 formed on the inner surface of the helical screw 230, .

At this time, the rotation of the rotary tube 210 is caused to rotate without a rotation axis due to a mechanical mechanism formed by the rotor means-bearing means-stator means.

That is, when the bearing means 400 is connected to the stator means 300 fixedly coupled to the pipe and the frictional resistance of the fluid generated in the helical screw 230 is generated in the state where the rotary pipe 210 is coupled to the bearing means, And the rotary tube is rotated without the rotary shaft by the power.

7 is a view for explaining the principle of generation of rotational power by the spiral groove 240 of Embodiment 2. Part of the fluid flowing through the rotating tube flows through the rotating tube 210, 210 along the helical groove 240 formed at a certain depth on the inner surface of the substrate 210.

When the fluid flows into the helical groove 240 and flows, the fluid flows in a whirling manner inside the rotary pipe 210, thereby generating a rotational power, and the rotary pipe 210 is rotated.

Although the preferred embodiments of the present invention have been disclosed for illustrative purposes, those skilled in the art will appreciate that various modifications, additions and substitutions are possible, without departing from the scope and spirit of the invention as disclosed in the accompanying claims. In addition, it is a matter of course that various modifications and variations are possible without departing from the scope of the technical idea of the present invention by anyone having ordinary skill in the art.

10: Piping type generator
100: Piping
200: Rotor means
210: Rotating tube
220: permanent magnet
230: Spiral screw
240: Spiral groove
300: Stator means
310: Housing
311: First seating stage
320: housing cover
321: second seating stage
330: Coil
341: sealing material groove
400: bearing means (400)
500: Flange

Claims (6)

An unshrouded piping-type generator (10) that generates power by receiving rotational power from a fluid flowing through a pipe (100)
A permanent magnet (220) is formed on the outer surface, a helical screw (230) is formed on the inner surface, and a rotor (300) is formed by rotating the stator (300) Means (200);
The stator unit 500 includes a flange 500 fixedly connected to the pipe 100 and a coil 330 formed on the inner surface of the flange 500. The stator unit 500 generates electricity when the rotor unit 200 rotates, (300);
Bearing means (400) serving as a rotation guide for rotating the rotor means (200) relative to the fixed stator means (300);
And a flange 500 welded to the pipe 100 and bolted to the stator means 300 for connecting the pipe 100 and the stator means 300,
The stator means (300)
A coil 330 is formed on the inner side surface and is formed outside the rotor means 200 to protect the rotor means 200 from the outside and has a first seating end 311 for receiving the bearing means 400, A cylindrical housing 310 in which the first and second housings 310 and 320 are formed;
A second seating end 321 for preventing the bearing means 400 from being detached to the piping 100 side is formed and one side is fixedly coupled to the housing 310 and the other side is connected to the flange 500 and the bolt- A housing cover 320 formed on both sides of the housing 310;
And a coil (330) formed on the inner surface of the housing (310) so as to be able to flow electricity by being generated by a rotating system generated when the rotor means (200) rotates,

The rotor means (200)
A rotary tube 210 having a hollow inside which a fluid can flow and having a cylindrical shape and configured to rotate with respect to the stator unit 300;
A plurality of permanent magnets 220 formed on an outer surface of the rotary pipe 210 to form a rotating system when the rotary pipe 210 rotates;
And a helical screw (230) fixed to the inner surface of the rotary tube (210) to obtain a rotational power for rotating the rotary tube (210) from the fluid flowing through the hollow of the rotary tube (210)

The rotary pipe 210 is formed between the pipe 100 and the pipe 100 and forms a gap with the pipe 100 so that the rotary pipe 210 is rotated with one side of the pipe 100, So that friction is not generated at one side of the tube 210,
The rotary tube 210 is fixed to the bearing means 400 formed on the inner side of the stator means 300 and the rotary tube 210 is fixed to the bearing means 400 in a fitting manner, 400) and the rotary pipe (210) so that no gap is generated between the rotary pipe (400) and the rotary pipe (210).
An unshrouded piping-type generator (10) that generates power by receiving rotational power from a fluid flowing through a pipe (100)
A permanent magnet (220) is formed on the outer surface and a helical groove (240) is formed on the inner surface. The rotor (300) rotates relative to the stator means (300) Means (200);
The stator unit 500 includes a flange 500 fixedly connected to the pipe 100 and a coil 330 formed on the inner surface of the flange 500. The stator unit 500 generates electricity when the rotor unit 200 rotates, (300);
Bearing means (400) serving as a rotation guide for rotating the rotor means (200) relative to the fixed stator means (300);
And a flange 500 welded to the pipe 100 and bolted to the stator means 300 for connecting the pipe 100 and the stator means 300,
The stator means (300)
A coil 330 is formed on the inner side surface and is formed outside the rotor means 200 to protect the rotor means 200 from the outside and has a first seating end 311 for receiving the bearing means 400, A cylindrical housing 310 in which the first and second housings 310 and 320 are formed;
A second seating end 321 for preventing the bearing means 400 from being detached to the piping 100 side is formed and one side is fixedly coupled to the housing 310 and the other side is connected to the flange 500 and the bolt- A housing cover 320 formed on both sides of the housing 310;
And a coil (330) formed on the inner surface of the housing (310) so as to be able to flow electricity by being generated by a rotating system generated when the rotor means (200) rotates,

The rotor means (200)
A rotary tube 210 having a hollow inside which a fluid can flow and having a cylindrical shape and configured to rotate with respect to the stator unit 300;
A plurality of permanent magnets 220 formed on an outer surface of the rotary pipe 210 to form a rotating system when the rotary pipe 210 rotates;
And a helical groove (240) formed on an inner surface of the rotary tube (210) so as to obtain rotational power for rotating the rotary tube (210) from the fluid flowing through the hollow of the rotary tube (210)

The rotary pipe 210 is formed between the pipe 100 and the pipe 100 and forms a gap with the pipe 100 so that the rotary pipe 210 is rotated with one side of the pipe 100, So that friction is not generated at one side of the tube 210,
The rotary tube 210 is fixed to the bearing means 400 formed on the inner side of the stator means 300 and the rotary tube 210 is fixed to the bearing means 400 in a fitting manner, 400) and the rotary pipe (210) so that no gap is generated between the rotary pipe (400) and the rotary pipe (210).

delete delete delete The method according to claim 1,
The stator means (300)
At least one of the housing 310 and the housing cover 320 is formed on one inner circumferential surface of the housing 310 so that the sealing material for preventing the water flowing into the rotary pipe 210 from flowing into the housing 310 through the bearing means 400 is inserted And a sealing material groove.

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