KR20110013622A - Generator - Google Patents

Abstract

PURPOSE: A hydroelectric power generator is provided to continuously generate power using a head and to produce electricity by driving a turbine. CONSTITUTION: A hydroelectric power generator comprises first and second mounting grooves(11,12), first and second water tanks(21,22), soft first and second pipe bodies(31,32), first and second branch units(41,42), a chamber(51), a hydraulic turbine(52), a generator(53), a storage battery(54), an inverter(55), and a controller(C). The first and second mounting grooves are formed in the ground. The first and second water tanks are inserted into the first and second mounting grooves. The first and second pipe bodies connect the first and second water tanks. The first and second branch units are formed at the centers of the first and second pipe bodies. The chamber is connected to the first and second branch units. The hydraulic turbine is installed inside the chamber and is rotated by water fallen from the first and second branch units. The controller prevents the generator and the storage battery from being overcharged.

Description

Hydro power unit {GENERATOR}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a hydroelectric power generation apparatus, and more particularly, to a hydroelectric power generation apparatus capable of generating electricity by rotating a turbine using a drop generated in a plurality of reservoirs capable of varying heights.

In general, due to the development of high-tech industries, various types of generators have been developed and used, such as nuclear power, dams using hydroelectric power and thermal power generation.In addition, electricity is generated by installing power generation turbines in wide or small rivers. It was.

However, the conventional hydroelectric generator is installed in a river or a dam and generates a lot of voltage, so the scale is very large and is fixedly installed, which causes excessive initial facility cost.

The present invention has been made to solve the above-mentioned problems of the prior art, to enable self-power generation in a small facility, such as a farm or barn, two reservoirs are set to mutually opposite height, according to the height The present invention relates to a hydroelectric power generation apparatus capable of generating electricity by driving a turbine using a drop.

The above object of the present invention, the first and second seating grooves formed in the ground; First and second tanks inserted into the first and second seating grooves; Connecting the first and second tanks and the flexible first and second bodies having flexibility and elasticity; First and second distributors respectively formed in the middle of the first and second tubular bodies; A chamber configured to communicate with the first and second distributors; Aberration installed in the chamber and rotated by water falling from a branch; A generator coupled to the shaft of the aberration to convert kinetic energy due to rotation into electrical energy; A storage battery for storing electricity generated by the generator; It is achieved by a hydroelectric power generation apparatus including an inverter for boosting the electricity of the battery to a rated voltage.

It is characterized in that the elevating means for further elevating the first and second tanks, respectively.

The elevating means is a base installed in the inner lower portion of the first and second seating groove; A lift table installed on the upper part of the base to support the lower part of the first and second tanks; A power unit for generating power for elevating the platform; It characterized in that it comprises a guide rail fixed to the upper and the lower fixed to the first and second seating groove vertically.

The lifting means is mounted to the ceiling; A movable table installed on the mounting table; A wire wound on the movable table and connected to one end of the first and second tanks; A driving unit connected to the other end of the wire; A controller for elevating the first and second tanks by winding or releasing wires by forward and reverse rotation of the driving unit; It characterized in that it comprises a guide rail fixed to the upper and the lower fixed to the first and second seating groove vertically.

According to the present invention, power is generated using a drop of water falling from two tanks, and the two tanks alternately change in height so that power can be continuously generated by a drop, and the mutual height is set to be opposite, and Since it is possible to generate electricity by driving a turbine using a drop according to the height, there is an effect that can be used for self-power generation in a farm or barn which is a relatively small facility.

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

1 and 2 is a configuration diagram showing a hydroelectric generator according to the present invention.

As shown in Fig. 1 and Fig. 2, the hydroelectric generator A according to the present invention

First and second seating grooves 11 and 12 formed on the ground;

First and second tanks 21 and 22 inserted into the first and second seating grooves 11 and 12;

Soft first and second tubular bodies 31 and 32 connecting the first and second tanks 21 and 22 and having flexibility and flexibility;

 First and second distributors 41 and 42 respectively formed in the middle of the first and second pipe bodies 31 and 32;

A chamber (51) formed to communicate with the first and second distributors (41,42);

An aberration 52 installed in the chamber 51 and rotated by water falling from the first and second branch mechanisms 41 and 42;

A generator (53) coupled to the shaft of the aberration (52) to convert kinetic energy due to rotation into electrical energy;

A storage battery 54 for storing electricity generated by the generator 53;

Inverter 55 for boosting the electricity of the storage battery 54 to a rated voltage

It is made, including.

The first and second seating grooves 11 and 12 are formed by excavating the ground to a predetermined depth, and are formed to a depth enough to allow the first and second tanks 21 and 22 to be inserted.

The first and second water tanks 21 and 22 are water tanks for storing a predetermined amount of water, and a connector for connecting the first and second pipe bodies 31 and 32 to upper and lower sides thereof is formed.

The first and second pipe bodies 31 and 32 are pipes connecting the first and second water tanks 21 and 22 to be made of a soft material such as PVC having flexibility and elasticity. Therefore, even if the height of the first and second tanks 21 and 22 is changed repeatedly, the bending and elasticity may be damaged so that the first and second tanks 21 and 22 may not be damaged or interfere with the lifting operation of the first and second tanks 21 and 22.

In addition, the first and second tubular bodies 31 and 32 do not have a separate fixing means so that the first and second tanks 21 and 22 are freely stretched when the first and second tanks 21 and 22 are lifted and operated, and in particular, the up and down reversal of the chamber 51 is performed. Make it possible.

In the middle of the first and second tubular bodies 31 and 32, the first and second branch apparatuses 41 and 42 each having a “T” shape may be coupled to each other so that the flow direction of water may be converted to a right angle. The change is caused to fall to the aberration 52 in the chamber 51.

In addition, valves V are mounted on both sides of the first and second branch mechanisms 41 and 42, respectively, for opening and closing. Therefore, when the maintenance of the aberration 52, the valve (V) by locking the inflow of water can be easy to work.

The chamber 51 has a rectangular box shape with an empty inside, and has falling holes communicating with the first and second branch mechanisms 41 and 42 at upper and lower portions thereof.

The aberration 52 is a wheel shape consisting of two discs and a plate coupled therebetween, so that a shaft installed horizontally in the chamber is rotatably coupled to the center thereof, and water falling from the dripping hole of the aberration 52 It can be rotated while deflecting the diaphragm.

The generator 53 is installed outside the chamber 51 and coupled to the shaft of the aberration 52, and converts the kinetic energy due to rotation into electrical energy.

Since the generator 53 is known in the art, detailed description thereof will be omitted.

The battery 54 stores electricity generated by the generator 53.

The inverter 55 boosts the electricity of the battery 54 to a rated voltage of 220 V which is commonly used.

In addition, a controller (C) for protecting the generator (53) and controlling the driving of the lifting means (H1, H2) to be described later is further provided.

The controller C prevents excessive rotation of the generator 53 to prevent overvoltage generation, thereby preventing overcharging of the battery 54.

In addition, the controller C prevents the complete discharge of the battery 54 to protect the life.

The controller C also functions to control the operation of the lifting means H1 and H2.

Meanwhile, elevating means H1 and H2 for elevating the first and second tanks 21 and 22 in opposite directions are further provided.

That is, for example, when the first tank 21 is raised, the second tank 22 is lowered. On the contrary, when the second tank 22 is raised, the first tank 21 is lowered.

The elevating means (H1, H2) may be configured in various embodiments, but the present invention adopts two embodiments.

As shown in Figs. 1 and 2, the elevating means H1 according to the first embodiment,

A base H11 installed at an inner lower portion of the first and second seating grooves 11 and 12;

A lift table (H12) installed on the upper portion of the base (H11) to support the lower portion of the first and second tanks (21, 22);

It comprises a power unit (H13) for generating a power for raising and lowering the lifting platform (H12).

The lifting platform (H12) is a plurality of metal pieces are hinged in an "X" shape is connected in multiple stages, the lower portion is composed of a working shaft coupled through a horizontal through two metal pieces intersected, which is the same as the usual jockey Detailed description thereof will be omitted.

The power unit (H13) is to provide the power to raise and lower the height of the lifting platform (H12) by rotating the operating shaft forward, reverse, it is composed of a motor connected to the operating shaft.

The motor may further be connected to a reducer for deceleration.

On the other hand, Figure 3 is a block diagram showing a hydroelectric power generator according to another embodiment of the present invention.

As shown in Fig. 3, the lifting means H2 according to the second embodiment is

A mounting bracket (H21) installed on the ceiling;

A moving table (H22) installed on the mounting table (H21);

A wire (H23) wound on the movable table (H22) and having one end connected to an upper end of the first and second tanks (22);

A driving unit (not shown) connected to the other end of the wire (H23);

It comprises a controller (C) for lifting the wire (H23) by the forward and reverse rotation of the drive unit to lift the first and second tanks (21, 22).

That is, the lifting means H2 according to the second embodiment is similar in configuration to a conventional 'hoist'.

Therefore, the first and second tanks 21 and 22 can be selectively raised or lowered by the operation of the controller C, which is performed by the winding operation of the drive unit and the wire H23 linked thereto.

Hereinafter will be described the operating relationship of the present invention.

First, as shown in FIG. 1, the first tank 21 is lowered and the second tank 22 is raised.

Water in the second water tank 22 is moved downward through the first pipe body 31 and flows into the chamber 51 from the first distributor 41 and falls to rotate the aberration 52.

Electricity is generated by driving the generator 53 connected thereto by the rotation of the aberration 52, and the generated electricity is stored in the storage battery 54 and then output to the outside through the inverter 55.

After rotating the aberration 52, the water continues to move to the first tank 21 and is stored.

If the water is filled in the first tank 21 while the power generation is performed through the above process, the lifting means is operated to raise the first tank 21 and lower the second tank 22.

The supply of electricity for the operation of the elevating means (H) uses electricity generated by self-generation.

After that, the water of the first tank 21 is introduced into the chamber through the second tube 32 and then transferred to the second tank.

At this time, since the first and second tubular bodies 31 and 32 are soft pipes, even if the positions of the first and second tanks 21 and 22 are changed, problems such as breakage or blockage do not occur.

On the other hand, as shown in Figure 2, the first tank is raised and the second tank is lowered, the position of the first and second pipe bodies (31, 32) is reversed, this time the second branch 42 is positioned upwards The first branch mechanism 41 is positioned downward.

That is, the chamber 51 is inverted due to the self-weight of the generator 53, and since the first and second tubular bodies 31 and 32 are soft, the position can be reversed.

These opposing height variations of the first and second baths 21, 22 can be carried out continuously, thereby allowing the production of electricity continuously.

Although the present invention has been described in connection with the above-mentioned preferred embodiments, it will be apparent to those skilled in the art that various modifications and variations can be made without departing from the spirit and scope of the invention, It is obvious that the claims fall within the scope of the claims.

1 and 2 is a block diagram showing a hydroelectric generator according to the present invention.

3 is a block diagram showing a hydroelectric power generator according to another embodiment of the present invention.

<Description of Symbols for Main Parts of the Present Invention>

11: first seating groove 12: second seating groove

21: 1st tank 22: 2nd tank

31: first body 32: second body

41: first branch mechanism 42: second branch mechanism

51 chamber 52 aberration

53 generator 54 storage battery

55: inverter

Claims (6)

First and second seating grooves 11 and 12 formed on the ground; First and second tanks 21 and 22 inserted into the first and second seating grooves 11 and 12; Soft first and second tubular bodies 31 and 32 connecting the first and second tanks 21 and 22 and having flexibility and flexibility;  First and second distributors 41 and 42 respectively formed in the middle of the first and second pipe bodies 31 and 32; A chamber (51) formed to communicate with the first and second distributors (41,42); An aberration 52 installed in the chamber 51 and rotated by water falling from the first and second branch mechanisms 41 and 42; A generator (53) coupled to the shaft of the aberration (52) to convert kinetic energy due to rotation into electrical energy; A storage battery 54 for storing electricity generated by the generator 53; An inverter (55) for boosting electricity of the storage battery (54) to a rated voltage; Controller (C) to prevent the overcharge and over-discharge of the generator 53 and the storage battery 54 Hydroelectric device comprising a. The method of claim 1, The chamber (51) has a rectangular box shape with an empty inside, and the upper and lower portions of the hydroelectric generator, characterized in that the falling hole communicating with the first and second branch (41, 42). The method of claim 1, Hydroelectric power generation apparatus characterized in that it is further provided with elevating means (H1, H2) for raising and lowering the first and second tanks (21, 22), respectively. The method of claim 3, wherein The lifting means (H1) is A base H11 installed at an inner lower portion of the first and second seating grooves 11 and 12; A lift table (H12) installed on the upper portion of the base (H11) to support the lower portion of the first and second tanks (21, 22); A power unit (H13) for generating power for elevating the platform (H12); Controller C for controlling the drive of the power unit H13 Hydroelectric device comprising a. The method of claim 4, wherein The lifting platform (H12) is composed of a plurality of metal pieces are hinged to the "X" shape is connected in multiple stages, the lower portion is composed of a working shaft coupled through the two metal pieces intersected horizontally, The power plant (H13) is a hydroelectric generator, characterized in that consisting of a motor connected to the operating shaft. The method of claim 3, wherein The lifting means (H2) is A mounting bracket (H21) installed on the ceiling; A moving table (H22) installed on the mounting table (H21); A wire (H23) wound on the movable table (H22) and having one end connected to an upper end of the first and second tanks (22); A driving unit connected to the other end of the wire (H23); Controller (C) for elevating the first and second tanks (21, 22) by winding or releasing the wire (H23) by the forward and reverse rotation of the drive unit Hydroelectric device comprising a.

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