KR100955083B1 - A power generator using a fluid pipe - Google Patents

Abstract

PURPOSE: A generator using a fluid pipeline is provided to generate power without interrupting the flow of the fluid by using the fluid flowing in the edge part of a fluid pipeline. CONSTITUTION: A generator using a fluid pipeline includes a rotator(10) and a generator(50). The rotator is installed in the inner periphery region of a fluid pipeline(P) which has empty inside. The rotator is rotated by the fluid moving to the inside edge region of the fluid pipeline. The generator generates the electricity by the rotation of the rotator. The power generation is conducted without obstructing the flow of the fluid flowing along the fluid pipeline.

Description

A power generator using a fluid pipe

The present invention relates to a power generation apparatus. More specifically, the present invention relates to a power generation apparatus using a fluid pipe which is installed inside a pipe through which fluid such as cold water, cooling water, oil, and air flows to obtain electricity.

In general, a generator is a device that converts certain energy into electrical energy. Generators are divided into hydropower, thermal power, nuclear power, etc., according to their energy sources, and convert natural energy into electrical energy so that it can be used properly when needed.

Among them, the hydroelectric generator is a method of converting the potential energy of water located at a high place into the kinetic energy of a generator turbine and obtaining electricity by using electromagnetic induction inside the generator.

In general, for hydroelectric power generation, dams are constructed by blocking rivers, confining water upstream of the dam, opening the gate, and dropping it downstream of the dam to turn the turbine. In this process, the potential energy of water is converted into the kinetic energy of the turbine. The rotor coil inside the turbine then rotates along the turbine to generate current through electromagnetic induction. This process converts the kinetic energy of the turbine into electrical 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, and thus, a large amount of water must be secured in the dam in order to secure a larger drop.

However, the hydroelectric power generation requires a large-scale facility for power generation, and the power generation efficiency is lowered when there is no rain for a long time upstream of the dam.

As another example, thermal power generation, also known as thermal power generation, refers to a power generation method that uses a heat generated by burning fuel such as wood and coal to turn a turbine and obtains electricity using the power of the turbine.

Thermal power generation is a widely used power generation method at home, but it has limited fuel resources and causes environmental problems such as air pollution.

In recent years, a growing interest in energy has been researched in the academic field for the development of more environmentally friendly and resource utilization.

In this respect, new power generation methods using fluids such as hydraulic power and wind power are attracting attention. In conventional hydro and wind generators, a generator is integrally installed with a wing at the center of a fluid flow. In other words, the generator or the central axis of the generator rotates with power induced in the outer blades to generate power. And this is the current method used in general hydro, wind power, tidal power, etc. was limited.

In other words, various types of fluids such as cold water, cooling water, oil, gas, and air are transported through various types of pumps in various buildings and industrial plants, and these fluids have energy due to their pressure and flow rate. Nevertheless, it could not be recycled to gain rotational power or to be used for direct generation.

Therefore, the present applicant has proposed the present invention at the request of the times as described above, and an object thereof is to provide a power generation apparatus using a fluid pipe that can generate power by recycling resources that are more environmentally friendly and unnecessary.

The present invention is characterized in that the power generation by using a fluid flowing detachably coupled to the fluid pipe to the edge of the fluid pipe,

It includes a rotating body detachably coupled to the inner circumferential region of the fluid pipe to rotate by the fluid moving to the fluid pipe inner edge region; And a generator for generating electricity by receiving the rotation of the rotating body.

According to the generator using the fluid pipe of the present invention has the following effects.

First, since the generator is mounted at the edge region inside the pipe with various fluids having almost constant flow rates such as cold water, cooling water, air, and oil, power generation can be performed without disturbing the flow of the fluid.

Second, since the device that generates power can be easily removed and detached, it can be installed and used in an existing fluid pipe or a new fluid pipe, and can generate energy by utilizing existing waste resources. To provide.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. First of all, in adding reference numerals to the components of each drawing, it should be noted that the same reference numerals are used as much as possible even if displayed on different drawings. In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear.

1 is a schematic side cross-sectional view of a rotating body installed in a fluid pipe according to an embodiment of the present invention, Figure 2 is a plan view showing the arrangement of the fluid pipe and the impeller of Figure 1, Figure 3 is a fluid 4 is a view illustrating the flow and rotation of the impeller, and FIG. 4 is a conceptual view illustrating the power generator of FIG. 1 in a plan view.

In the power generating apparatus of the present invention, the rotating body 10 is installed at the edge region of the pipe P through which fluid such as cold water, cooling water, oil, air, etc. flows to generate power by using a fluid flowing in the edge region inside the pipe P. And, to the central region of the pipe (P) to allow the fluid to move smoothly without disturbing the flow.

More specifically, as shown in FIG. 1, in the power generation apparatus of the present invention, when there is any fluid pipe P installed vertically, the fluid pipe P is divided into an upper pipe P1 and a lower pipe P2. It is provided with a rotary induction device (1) which is installed in the space therebetween after cutting as much as possible.

The rotary induction apparatus 1 mounted to the fluid pipe P is provided between the insertion pipe 5 and the insertion pipe 5 and the fluid pipe P that largely partition the inner region of the fluid pipe P. It may include a rotating body 10 for converting the flow of the fluid into rotational kinetic energy, and guides 20 and 30 disposed on at least one side of the rotating body 10 to guide the flow of the fluid.

The insertion pipe 5 has a diameter smaller than the upper pipe (P1) and is fixed to the upper pipe (P1) to have a space spaced inside the upper pipe (P1). The insertion pipe (5) is made of a cylinder like the shape of the fluid pipe (P) as shown in FIG.

The insertion pipe (5) is fixed to the upper pipe (P1) and the lower pipe (P2) is installed for convenience in assembling the inlet guide 20, which will be described later for the purpose of assembly, and the outlet guide 30 is formed so that the part is divided 2 It is preferred to consist of dogs.

The inner wall of the insertion pipe (5) may be unpatterned, and may be processed so that the fluid flow in the vertical downwards through the uneven structure slightly more firmly.

When the insertion pipe 5 is installed inside the fluid pipe P, as shown in FIG. 3, the inside of the insertion pipe 5 becomes hollow (H), so that the inflowing fluid can flow smoothly without interrupting the course. Since the inlet guide 20 and the outflow guide 30 are formed on the outside of the insertion pipe 5, the rotor 10 is mounted in the space formed by the insertion pipe 5 and the fluid pipe P. It is possible to generate electricity using the incoming fluid.

In detail, the inflow guide 20 installed in the upper region of the insertion pipe 5 is introduced between the upper pipe P1 and the insertion pipe 5, that is, from the upper edge region of the fluid pipe P. It serves to guide the flow of the fluid to the rotating body (10).

The inflow guide 20 is fixed to the insertion pipe (5), which is formed integrally with the insertion pipe (5) having a plurality of guide wings (20a) arranged downward at a predetermined angle along the outside of the insertion pipe (5). Can be. As shown in FIG. 3, the inflow guide 20 guides the flow of the fluid flowing from the upper side in the direction in which the induction blade 20a guides using the induction blade 20a. In addition, the fluid flowing from the upper portion passes vertically downwardly into the inside H of the insertion pipe 5 in which the guide vane 20a is not formed.

The size, length, quantity, and shape of the guide vane 20a may be variously designed, and the thickness of the insertion pipe 5 may be variously designed along with the structure of the material and the guide vane 20a.

The fluid flowing from the upper portion of the fluid pipe (P) is inclined direction of the left or right right or right in the existing straight down through the inlet guide (5) inserted into the inside and the inlet guide (20) formed outside the insertion pipe (5) To be induced.

When the fluid guided in the inclined direction of the left and right sides passes through the inflow guide 20, the mechanical seal 40 is coupled between the upper pipe P1 and the lower pipe P2. Guided to the lower rotating body (10). Here, the mechanical connects the upper and lower parts of the rotating body 10 to maintain the airtight so that the fluid does not leak to the outside, and serves to minimize the friction loss due to the rotation of the rotating body (10). Of course, the mechanical yarn may be replaced by another type of yarn serving the above-mentioned role.

The rotating body 10 is rotated by receiving the flow rate and pressure of the fluid introduced by the inlet guide 20 described above, and converts the flow of the fluid into rotational kinetic energy. To this end, the rotary body 10 is equipped with a rotary blade 10a to rotate under the force of the fluid guided through the guide blade 20a of the inlet guide 20 from the top.

Rotating blade 10a of the rotating body 10 has an approximately symmetrical structure with respect to the induction blade 20a of the upper inlet guide 20 on the horizontal plane, but can be devised in various shapes, quantities, heights, and lengths. have.

The rotary body 10 is the upper pipe (P1) and the lower pipe (P2) as shown in Figure 3 to reduce the friction through the fluid between the insertion pipe 5 and the rotation during its rotation, its resistance, etc. The outer diameter can be made larger than). To this end, an area in which the rotating body 10 is installed may be provided as a separate housing to be coupled to the upper pipe P1 and the lower pipe P2.

When the diameter of the rotating body 10 is designed to be larger than the actual pipe P, the pressure of the fluid required for the rotation of the rotating body 10 is temporarily lowered, thereby reducing the rotational resistance of the rotating body 10.

Therefore, it is possible to use the flow rate and pressure of the fluid pipe (P) which is operated for a predetermined time or 24 hours depending on the purpose by the pump in existing and new buildings or industrial sites, etc. without receiving a large resistance in the middle. By using the rotational force induced through the generator can be used as electricity storage, lighting, or general electricity.

The rotor 10 may vary in the number and direction of installation of the rotor blades 10a so as to maintain a constant rotational force for a long time, and the material, thickness, weight, etc. of the rotor 10 may be selectively designed.

The outflow guide 30 for guiding the flow of the fluid passing through the rotating body 10 is provided at the lower portion of the rotating body 10, that is, the lower pipe (P). The outflow guide 30 has a configuration similar to the inflow guide 20 described above, and a plurality of guide vanes 30a may be integrally formed in the insertion pipe 5. Therefore, the outflow guide 30 may efficiently adjust the direction of the fluid so that the fluid passing through the rotating body 10 smoothly moves downward.

The fluid generating the rotational force while passing through the rotating body 10 is guided so as to be in a vertical downward direction through the guide vanes 30a of the outflow guide 30 located directly below, and the inside of the inserted internal insertion pipe 5. It merges again with the fluid flowing down vertically along (H).

On the other hand, the generator 50 for generating electricity by receiving the rotational force of the rotating body 10 is disposed outside the fluid pipe (P). The generator 50 receives the rotational kinetic energy of the rotating body 10 to generate electricity. To this end, a pulley 55 and a belt 53 are installed to connect the rotor 10 and the generator 50 to transmit power.

Here, the generator 50 fixed to the outside of the rotor 10 may be a direct current or alternator and is not specified as either. The generator 50 together with the above-described rotating body 10 constitutes a power generator.

And as shown in Figure 4 the outside of the above-described rotating body 10 may be a saw tooth, irregularities, gear shape processing in the circumferential direction, it can be processed into a V-shaped groove or the like without such processing. This may be a method of reducing energy loss when transmitting the rotational force of the rotor 10 to the generator 50.

For example, the body of the fixed generator 50 at a close distance from the rotor 10 through the tooth, request, gear-shaped pulley 55 directly contacting the rotor 10 to obtain a rotational force to generate power. Can be. And through the V belt, uneven belt, flat belt and the like to obtain a rotational force through the pulley 55 connected to the generator shaft 50 in close proximity to the rotor 10, the generator 50 body rotates to generate power can do.

Since the shape, number, and number of rows, such as teeth, irregularities, and gears that can be processed in the rotating body 10 are not specified, it may be selected from one to many according to the minimum requirements of the force and internal resistance of the rotating body 10. .

In addition, by varying the size of the pulley 55 fixed to the outer circumference of the rotor 10 and the shaft connected to the generator 50 body, the pulley 55 and the belt 53 described above according to various fluids and flow rates. Can be changed.

As described above, the power generation apparatus of the present invention is installed in the pipe P through which fluids such as cold water, cooling water, oil, and air flow, and generates power by receiving the flow rate of the fluid flowing in the edge region of the pipe P. The region allows the fluid to flow smoothly so that power generation can be performed without disturbing the flow of the fluid.

In addition, it is easy to remove and detach, so that it can be easily installed and used in the existing fluid pipes or newly installed fluid pipes can not only generate energy by utilizing existing resources, but also serve as a new type of power generation model.

The foregoing description is merely illustrative of the technical idea of the present invention, and various changes and modifications may be made by those skilled in the art without departing from the essential characteristics of the present invention.

The power generation apparatus of the present invention can be applied to various vertical and horizontal pipes on existing and new facilities, and it is understood that the type of fluid and the flow direction in vertical or horizontal pipes are not related in any direction. In addition, the fluid flowing along the pipe maintains a constant speed and may be applied to the present invention in a condition where there is no variation or a slight variation.

In the above-described embodiment, both the inflow guide 20 disposed on the side where the fluid is introduced and the outflow guide 30 disposed on the side where the fluid flows out are provided, but only the rotating body 10 for power generation may be provided. The guide may be provided only at one of the upper and lower parts of the rotating body 10. And the rotating body 10 may be provided by using a plurality of rotational power by providing a plurality to be further developed.

 Therefore, the embodiments disclosed in the present invention are not intended to limit the technical idea of the present invention but to describe the present invention, and the scope of the technical idea of the present invention is not limited by these embodiments. The protection scope of the present invention should be interpreted by the following claims, and all technical ideas within the equivalent scope should be interpreted as being included in the scope of the present invention.

1 is a schematic side cross-sectional view of a rotating body installed in a fluid pipe according to an embodiment of the present invention.

Figure 2 is a plan view showing the arrangement of the fluid pipe and the impeller of Figure 1;

3 shows the flow of fluid and the rotation of the impeller.

4 is a conceptual view illustrating the rotating body of FIG. 1 in a plan view;

  1: generator 10: rotor

10a: Wing 20: Inflow guide

20a: Induction wing 30: Outflow guide

30a: Induction wing 40: Seal

50: generator 53: belt

55: pulley P: piping

Claims (7)

A rotating body having a ring shape, the rotating body being installed in an inner circumferential region of an empty fluid pipe and rotating by a fluid moving to an inner edge area of the fluid pipe; And And a generator configured to generate electricity by receiving rotation of the rotating body, thereby generating power without disturbing the flow of the fluid flowing along the fluid pipe as much as possible. The method of claim 1, And a guide configured to guide the flow of the fluid, the guide being disposed on at least one of the side into which the fluid flows into the rotating body and the side from which the fluid flows. The method of claim 2, The guide, An apparatus for generating power using a fluid pipe, comprising: an inflow guide disposed on a side into which a fluid flows in; and an outflow guide disposed on a side from which the fluid flows out. The method of claim 3, And an insertion pipe inserted into the fluid pipe so as to form a space in which the rotor and the guide are installed. The method of claim 4, wherein The insertion pipe and the fluid pipe is a power generation device using a fluid pipe, characterized in that the sealing by a mechanical seal (mechanical seal). The method of claim 1, Generating apparatus using a fluid pipe further comprises a pulley and a belt connecting the rotor and the generator. The method according to any one of claims 1 to 6, The rotating body is a power generation device using a fluid pipe, characterized in that provided in plurality.

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