KR20110107561A - A power generator using air - Google Patents

Abstract

The present invention relates to a power generating apparatus using air, the tank containing the fluid, the air supply unit communicating with the tank and supplying air into the tank, buoyancy to lift the inside of the tank by the air supplied from the air supply unit It may be connected to the member and the buoyancy member and may include a power generator for generating power by receiving the power generated by the lifting of the buoyancy member.

Description

Power generator using air {A POWER GENERATOR USING AIR}

The present invention relates to a power generating apparatus using air, and more particularly, to an apparatus for generating power by raising and lowering a buoyancy member accommodated inside a tank using air.

In general, power generators generate power by being continuously supplied with power energy, which is mostly manufactured through nuclear power, thermal power, or hydropower, in order to generate power. Accordingly, even when power is generated, power generation efficiency is greatly reduced because power energy manufactured at a predetermined cost must be supplied elsewhere.

In addition, since power must be continuously supplied when generating power, the cost of power energy production increases exponentially.

Accordingly, an object of the present invention is to provide a power generating device for generating power more efficiently by supplying air through solar heat or waste heat to lift and lift a buoyancy member. have.

A power generating apparatus using air according to an embodiment of the present invention, the tank containing the fluid; An air supply unit communicating with the water tank and supplying air into the water tank; A buoyancy member for elevating the inside of the tank by the air supplied from the air supply unit; And a power generation unit connected to the buoyancy member and configured to generate power by receiving power generated by the lifting of the buoyancy member.

The air supply portion, one side is in communication with the lower portion of the water tank, the side is disposed in the main body connected to the supply pipe for supplying air and inside the main body and the piston to linearly reciprocate the inside of the main body and the supply pipe And a first supply valve for supplying air to the inside of the main body according to opening and closing, and a second supply valve mounted at one side of the main body and for supplying air contained in the main body to the inside of the water tank according to whether the opening and closing is performed. The first supply valve and the second supply valve may be one-way valves.

In this case, the air supply unit may further include a movable unit connected to the piston to linearly reciprocate the piston.

In addition, the movable unit is connected to the solar cell unit and the solar cell unit consisting of a plurality of solar cell modules in which a plurality of solar cells for converting solar energy into electrical energy connected in series or in parallel, by the solar cell unit It includes a storage battery for storing the generated power, the storage battery may be connected to one side of the piston to supply power to linearly reciprocate the piston.

On the other hand, the buoyancy member, one side is connected to the power generating unit, the other side is open to collect the air discharged from the air supply unit therein, the side has a discharge valve for discharging the collected air to the outside It may be installed.

In addition, the buoyancy member, one side is connected to the power generating portion, the first member and the inside is sealed in a vacuum state and one side is integrally connected with the first member and the other side is open and discharged from the air supply And a second member collecting internal air therein, wherein the second member may be equipped with a discharge valve for discharging the collected air to the outside.

The first member and the power generating unit may be connected to a pin gear.

In addition, the buoyancy member is mounted to the swing unit and the swing unit which is arranged to swing the inside of the water tank, and receives at least one buoyancy body that is lifted along the swing unit by receiving the air supplied from the air supply unit It may be to include.

Here, the turning unit may include a first gear disposed above the water tank, a second gear disposed under the water tank, and a chain member connected to the first gear and the second gear. .

In this case, a rotation member is connected to one side of the first gear, and the power generation unit connects the roller and the roller and the rotation member to be connected to the connection member and the roller which receive the rotational force generated by the turning unit. And it may be to include a generator for producing a rotational force transmitted through the connecting member to the power.

In addition, the buoyancy body may be arranged in multiple stages along the longitudinal direction of the chain member.

In addition, the buoyancy body, one side is connected to the chain member and the other side may be to collect the air discharged from the air supply therein.

In addition, the buoyancy body, one side is connected to the chain member and the inside of the first member is sealed in a vacuum state and one side is integrally connected with the first member and the other side is open to be discharged from the air supply It may be to include a second member for collecting the air therein.

According to the exemplary embodiment of the present invention, power energy supplied to generate air is supplied through solar heat or waste heat to be discarded, and thus, there is an advantage of not having to produce power energy separately at a predetermined cost. Accordingly, not only can the power generation efficiency be maximized, but also greatly reduce the cost of power energy supplied to produce air, which in turn reduces the overall maintenance cost.

1 is a cross-sectional view of a power generator using air according to an embodiment of the present invention.
2 to 3 is an operation of the air supply unit according to an embodiment of the present invention.
4 to 5 is an operation of the buoyancy member according to an embodiment of the present invention.
6 is a cross-sectional view of a buoyancy member according to another embodiment of the present invention.
7 is a cross-sectional view of a power generator using air according to another embodiment of the present invention.
8 is a cross-sectional view of a buoyancy member according to another embodiment of the present invention.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art may easily implement the present invention. The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Like parts are designated by like reference numerals throughout the specification.

Next, a power generating apparatus using air according to an embodiment of the present invention will be described with reference to FIGS. 1 to 5.

1 is a cross-sectional view of a power generator using air according to an embodiment of the present invention. 2 to 3 is an operation of the air supply unit according to an embodiment of the present invention. 4 to 5 is an operation of the buoyancy member according to an embodiment of the present invention.

1 to 5, the power generator 1 (hereinafter, referred to as a power generator) using air according to an embodiment is largely a water tank 10, an air supply unit 20, a buoyancy member 30, and power generation. The part 40 is included.

The water tank 10 is a basic body of the power generator 1 according to one embodiment. The inside of the water tank 10 is empty, and the fluid 2 is accommodated therein.

The air supply unit 20 communicates with a lower portion of the water tank 10 to supply air 3 to the water tank 10. The air 3 supplied into the water tank 10 becomes a bubble. The air supply unit 20 is not limited to being communicated to the lower portion of the water tank 10, it may be installed in communication with the side surface of the water tank (10).

The air supply unit 20 includes a main body 200, a piston 201, a first supply valve 210, and a second supply valve 220. In addition, the air supply unit 20 further includes a movable unit 230 connected to the piston 201.

First, the main body 200 is tubular, one side is in communication with the lower portion of the water tank 10, the side is in communication with the supply pipe 240 for supplying the air (3). The piston 201 is disposed inside the main body 200 and is connected to the movable unit 230 to linearly reciprocate through power transmitted through the movable unit 230. The first supply valve 210 is disposed in the supply pipe 240, and supplies the air 3 into the main body 200 depending on whether the first supply valve 210 is open or closed. The second supply valve 220 is mounted to one side of the main body 200 and opened and closed. When the first supply valve 210 is opened and the air 3 is supplied into the main body 200, the second supply valve 220 is closed to allow the air 3 into the water tank 10. ) Is not discharged. As a result, when the piston 201 linearly reciprocates the inside of the main body 200, the air 3 inside the main body 200 is compressed. When the piston 201 is linearly reciprocated so that the air 3 inside the main body 200 is compressed, the first supply valve 210 is closed to allow the air 3 into the main body 200. ) Is not supplied. Instead, the air 3 compressed by the second supply valve 220 is opened and supplied into the water tank 10. At this time, since the air 3 is compressed, it is more quickly and smoothly supplied into the water tank 10. Thereafter, the second supply valve 220 is closed again, and the first supply valve 210 is opened to supply the air 3 to the inside of the main body 10. The first supply valve 210 and the second supply valve 220 are one-way valves to prevent the fluid 2 inside the water tank 10 from flowing backward and outflowing into or out of the main body 200. .

The movable unit 230 includes a solar cell unit 231 and a storage battery 232. The solar cell unit 231 is installed outside the water tank 10. The solar cell unit 231 includes a plurality of solar cell modules in which a plurality of solar cells for converting solar energy into electrical energy are connected in series or in parallel. The storage battery 232 serves to store energy transferred from the solar cell unit 231. In this case, the storage battery 232 linearly reciprocates the piston 201 as it is connected to the piston 201.

In addition, the movable unit 230 is not limited to the solar cell unit 231, and may supply energy through various eco-friendly power generation mechanisms such as tidal power, wind power, and solar heat. In addition, the movable unit 230 according to the present invention is an external combustion engine 234 operating through the heat of the heat storage unit 233 and the heat storage unit 233 for storing the waste heat or solar heat discarded at home or industrial sites, etc. Energy may be transmitted through units to linearly reciprocate the piston 201. Accordingly, it is eco-friendly and does not need to produce power separately, thereby reducing the cost of power energy.

The buoyancy member 30 is disposed inside the water tank 10. At this time, the air supply unit 20 is disposed directly above the portion where the communication. This is for collecting the air 3 discharged from the air supply unit 20.

The buoyancy member 30, one side, that is, the upper portion is connected to the power generating portion 40, the other side, that is, the lower portion is open. Since the lower part of the buoyancy member 30 is open, the air 3 discharged through the air supply unit 20 is collected into the buoyancy member 30. As the air 3 is collected inside the buoyancy member 30, the buoyancy member 30 is stronger than the force of gravity, and gradually rises above the water tank 10. At this time, the detection sensor 312 is mounted inside the water tank 10. The sensor 312 may be installed by a buoy in the tank as shown in the figure. The sensor 312 opens the discharge valve 311 connected to the side of the buoyancy member 30 when the buoyancy member 30 exceeds the portion where the sensor 312 is mounted. The air 3 collected in the buoyancy member 30 is discharged to the outside of the buoyancy member 30. Thereafter, when the buoyancy member 30 does not exceed the portion where the detection sensor 312 is mounted, the discharge valve 311 is closed. As a result, the buoyancy member 30 naturally has a force of gravity stronger than that of the buoyancy and gradually descends from the water tank 10. The discharge valve 311 may be a solenoid that is a one-way valve.

In addition, the diameter of the discharge valve 311 should be larger than the diameter of the portion where the air supply unit 20 is in communication with the water tank (10). This is to make the lifting of the buoyancy member 30 more smooth. In more detail, the air 3 is continuously discharged from the air supply unit 20 and supplied to the buoyancy member 30. At this time, when the diameter of the discharge valve 311 is small and the air 3 trapped inside the buoyancy member 30 cannot be discharged quickly, the air buoyancy member 30 continues to collect the air 3. As the buoyancy force continues to increase and only rises but does not cause a problem. Accordingly, the diameter of the discharge valve 311 is larger than the diameter of the portion where the air supply unit 20 communicates with the water tank 10 so as to view the air 3 collected inside the buoyancy member 30. It is desirable to discharge quickly and smoothly.

The power generator 40 is a generator. At this time, the buoyancy member 30 and the power generating unit 40 is connected to the gear device including the wheel gear. Accordingly, when the buoyancy member 30 is raised and lowered, power is transmitted to the power generator 40. However, the connected method is not limited to the gear unit including the shock gear, and can be connected and transmitted in various ways.

The power generator 1 according to an embodiment may supply energy using solar heat or waste heat. At this time, the supplied energy is connected to the air supply unit 20 to operate the air supply unit 20. The air supply unit 20 repeatedly supplies the air 3 into the water tank 10 by a linear reciprocating motion of the piston 201. When the air 3 is supplied into the water tank 10, the air 3 is collected into the buoyancy member 30 disposed in the water tank 10. Accordingly, the buoyancy member 30 is buoyant force stronger than the force of gravity is gradually raised in the tank. When the raised buoyancy member 30 rises to a predetermined height, the air 3 collected in the buoyancy member 30 is discharged by the discharge valve 311. As a result, the force of the buoyancy is weakened, and the buoyancy member 30 is gradually lowered into the water tank 10. As the buoyancy member 30 repeatedly moves up and down, power is transmitted to the power generator 40 connected to the buoyancy member 30 to produce power.

6 is a cross-sectional view of a buoyancy member according to another embodiment of the present invention.

Components of other embodiments according to the present invention are similar to those of the components of the embodiments described with reference to FIGS. 1 to 5, and thus, detailed descriptions thereof will be omitted.

As shown, the buoyancy member 30 in another embodiment includes a first member 300 and a second member 310 connected to the first member 300. One side of the first member 300 is connected to the power generating unit 40, the inside is sealed in a vacuum state. In addition, one side of the second member 310 is integrally connected with the first member 300, and the other side is opened to collect the air 3 discharged from the air supply unit 30 therein. At this time, the discharge valve 311 is mounted in communication with the second member (310).

Since the inside of the first member 300 is sealed, the buoyancy member 300 has a predetermined amount of buoyancy force. Accordingly, the gravity force of the buoyancy member 30 should be stronger than the buoyancy force of the first member 300. If not, even if the air (3) is not supplied to the buoyancy member 30 will rise in the water tank 10 will not be able to lift itself.

In this way, the buoyancy member 30 is sealed inside the first member 300 in a vacuum state and the air 3 collected in the second member 310 as already has a predetermined amount of buoyancy force. The amount of can be lifted at least, which can be quickly lifted in a short time has the advantage of high power generation efficiency.

7 is a cross-sectional view of a power generator using air according to another embodiment of the present invention.

Components of other embodiments according to the present invention are similar to those of the components of the embodiments described with reference to FIGS. 1 to 5, and thus, detailed descriptions thereof will be omitted.

As shown, the buoyancy member 30 in another embodiment includes a turning unit 320 and a buoyancy body 330.

In more detail, the turning unit 320 is disposed in the water tank 10 so as to swing inside the water tank 10. The pivot unit 320 includes a first gear 321, a second gear 323, and a chain member 324.

The first gear 321 is mounted to the upper end portion of the water tank 10, the second gear 323 is mounted to the lower portion of the water tank 10. At this time, it is preferable that the air supply unit 20 communicates directly under the second gear 323. The chain member 324 connects the first gear 321 and the second gear 323. In addition, a rotation member 322 is connected to one side of the first gear 321.

One side of the buoyancy body 330 is connected to one side of the chain member 324 in multiple stages. In addition, the other side of the buoyancy body 300 is opened to collect the air (3) discharged from the air supply unit 20 therein.

As the chain member 324 pivots the inside of the water tank 10, the buoyancy body 330 naturally also turns, and when it rises through the second gear 323, the other side of the buoyancy body 330 is located on one side. It is located below. Accordingly, the air 3 supplied from the air supply unit 20 is collected inside through the other side of the buoyancy body 330. The buoyancy body 330 rises along the chain member 324 by the trapped air 3. When the raised buoyancy body 330 descends through the first gear 321, the raised buoyancy body 330 is rotated and flipped along the first gear 321 so that the fluid 2 contained therein and the air collected therein. (3) are all discharged to the outside. After that, the lowering is submerged in the fluid 2 contained in the water tank 10 again.

The power generating unit 40 is connected to the turning unit 320, and receives the rotational force generated by the turning unit 320 while turning indefinitely by the buoyancy body 330. It serves to generate.

The power generator 40 includes a roller 400, a connection member 410, and a generator 420. The connecting member 410 connects the roller 400 and the rotating member 322 of the first gear 321. In addition, the roller 400 is connected to the generator 420. At this time, a third gear is formed on one side of the roller 400, and is connected to the generator 420 and the like.

The power generating unit 40 having such a configuration transmits the rotational force generated by the rotation of the turning unit 320 to the generator 420 by the connecting member 410, the roller 400, and the chain. , Generator 420 may produce power.

8 is a cross-sectional view of a buoyancy member according to another embodiment of the present invention.

Components of other embodiments according to the present invention are similar to the description of the components of the embodiments described above with reference to FIGS. 1 to 7, and thus detailed description thereof will be omitted.

As shown in FIG. 6, the buoyancy member 30, like the buoyancy member illustrated in FIG. 6, has a first member 300 and a second member 310 connected to the first member 300. It includes.

Accordingly, the buoyancy member 30 is sealed inside the first member 300 in a vacuum state, and the air collected in the second member 310 as already having a predetermined amount of buoyancy force ( The amount of 3) can be lifted at least, which can be lifted quickly in a short time has the advantage of increasing the power generation efficiency.

Although the preferred embodiments of the present invention have been described in detail above, the scope of the present invention is not limited thereto, and various modifications and improvements of those skilled in the art using the basic concepts of the present invention defined in the following claims are also provided. It belongs to the scope of rights.

1: power generating device 2: fluid
3: air 10: water tank
20: air supply 200: main body
201: piston 210: first supply valve
220: second supply valve 230: movable unit
231: solar cell unit 232: storage battery
233: heat storage 234: external combustion engine
240: supply pipe
30: buoyancy member 300: first member
310: second member 311: discharge valve
312 detection sensor
320: swing unit 321: first gear
322: rotating member 323: second gear
324: chain member 330: buoyant body
40: power generating unit 400: roller
410: connection member 420: generator

Claims (14)

A water tank containing fluid;
An air supply unit communicating with the water tank and supplying air into the water tank;
A buoyancy member for elevating the inside of the tank by the air supplied from the air supply unit; And
And a power generating unit connected to the buoyancy member and generating power by receiving power generated by lifting of the buoyancy member. The method of claim 1, wherein the air supply unit,
One side is in communication with the bottom of the water tank, the side is connected to the main body and the supply pipe for supplying air,
A piston disposed inside the main body and linearly reciprocating;
A first supply valve disposed inside the supply pipe and supplying air into the main body depending on whether the air is opened or closed;
A second supply valve mounted on one side of the main body and supplying air received in the main body into the tank according to whether the main body is opened or closed;
The power supply device using air, characterized in that the first supply valve and the second supply valve is a one-way valve. The method of claim 2, wherein the air supply unit,
And a movable unit connected to the piston to linearly reciprocate the piston. The method of claim 3, wherein the movable unit,
A solar cell unit comprising a plurality of solar cell modules in which a plurality of solar cells converting solar energy into electrical energy are connected in series or in parallel;
A storage battery connected to the solar cell unit and configured to store electric power generated by the solar cell unit;
The piston is a power generator using air, characterized in that the linear reciprocating motion is supplied from the storage battery. The method of claim 3, wherein the movable unit,
Regenerators for storing heat supplied from solar or waste heat
An external combustion engine unit connected to the heat accumulator and operating through heat provided from the heat accumulator,
The piston is a power generator using air, characterized in that the linear reciprocating motion is supplied with the energy of the external combustion engine unit. The method of claim 1, wherein the buoyancy member,
One side is connected to the power generating unit, the other side is open to collect the air discharged from the air supply therein, the side is characterized in that the discharge valve for discharging the collected air to the outside Power generator using air. The method of claim 1, wherein the buoyancy member,
One side is connected to the power generating unit and the first member is sealed in a vacuum state inside and
One side is integrally connected with the first member and the other side is open to include a second member for collecting the air discharged from the air supply unit therein,
And the second member is provided with a discharge valve for discharging the collected air to the outside. The method according to any one of claims 6 to 7,
And the first member and the power generating unit are connected via a gear device. The method of claim 1, wherein the buoyancy member,
A swing unit arranged to swing inside the tank;
And at least one buoyant body mounted on the turning unit and receiving air supplied from the air supply unit and lifting up and down along the turning unit. The rotating unit of claim 9,
A first gear disposed on the tank and
A second gear disposed under the tank and
And a chain member connected to the first gear and the second gear. In claim 10,
One side of the first gear is connected to the rotating member,
The power generation unit,
With roller
A connecting member connecting the roller and the rotating member to receive the rotational force generated from the turning unit;
And a generator which is connected to the roller and generates a rotational force transmitted through the connection member as a power. The method of claim 9, wherein the buoyancy body,
A power generator using air, characterized in that arranged in multiple stages along the longitudinal direction of the chain member. The method of claim 9, wherein the buoyancy body,
One side is connected to the chain member and the other side is open to the power generating device using air, characterized in that to collect the air discharged from the air supply therein. The method of claim 9, wherein the buoyancy body,
One side is connected to the chain member and the first member is sealed in a vacuum state and
One side is integrally connected with the first member and the other side is open, the power generating device using air, characterized in that it comprises a second member for collecting the air discharged from the air supply therein.

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