KR20090097080A - Power generation devise using buoyancy, gravity and air pressure - Google Patents

Abstract

A power generation device using buoyancy, gravity and air pressure is provided to generate electricity by rotating a rotator with gravity that occurs when a buoyancy sinker falls down after being risen through buoyancy. A power generation device using buoyancy, gravity and air pressure includes a buoyancy chamber(170), a buoyancy chamber, a buoyancy control chamber(160), a lifting device(161), a load standby room(175), a buoyancy extraction door, first and second rollers, a chain, a conveyor belt and a generating turbine(400). The inside of the buoyancy chamber is filed with buoyancy flows, and the buoyancy loading chamber is formed at the lower portion of the buoyancy room. The buoyancy control chamber is formed at the lower portion of the buoyancy loading chamber, and the lifting device is formed at the lower portion of the buoyancy control chamber. The first and second roller are distanced a certain interval in the vertical direction at the both sides of the buoyancy chambers, and the chain is installed between the first and second rollers. The conveyor belt connects the door with the second roller, and the generating turbine is coupled to the first roller.

Description

Power Generation Devise using buoyancy, gravity and air pressure}

The present invention relates to a power generator using a combination of buoyancy, gravity and pneumatic pressure, more specifically, a first power source generator for generating gravity and pneumatic pressure using a separate potential energy fluctuation device, a chain of multiple buoyancy bodies or The present invention relates to a power generation device comprising a second power source generator for generating buoyancy according to the movement of a belt, and a third power source generator for generating a power source according to pneumatic pressure by having a pneumatic generating chamber and a pneumatic storage chamber.

In general, electricity generation includes thermal power, hydro, nuclear, wind, tidal and solar power.

Thermal power generation is the most widely used method, but there are problems of air pollution and fossil fuel depletion, and in the case of nuclear power generation, it exposes a fatal risk of radioactive leakage and is difficult to manage.

Here, tidal power is not polluted by the environment and large-scale power generation is possible, but the installation cost is high, and the difference between tidal water is possible, and without the sea, it is affected by geography.

Wind power is easier to install than tidal power and has less geographic constraints, but due to space problems, large-scale power generation is difficult and wind strength is not constant.

In the case of solar power, installation is easy, but due to space constraints, large-scale power generation is difficult, and only when there is the sun, it is impossible to generate electricity at night, and is affected by weather such as rain and snow.

Therefore, there is a demand for structural devices capable of overcoming limited natural requirements and generating power in an environmentally friendly manner.

In general, when a body is submerged in a fluid, the body receives a buoyancy force equal to the weight of a fluid having a volume equal to the volume of the body submerged in the fluid, and the direction of the buoyancy force is opposite to gravity. For example, when a float is accommodated in a cylinder to which fluid is supplied, the float rises with buoyancy when supplying a fluid such as water to such a cylinder. On the contrary, when discharging the fluid supplied in the cylinder, the floating body will be lowered by the action of gravity. As described above, when the float is accommodated in the cylinder and water is fluidly supplied to and discharged from the cylinder, the float will alternately rise, thereby inducing the lifting motion of the float to generate power.

Accordingly, although a power generation apparatus using gravity and buoyancy has been conventionally used, a power generating apparatus using a buoyancy force of a conventional floating body controls a supply of a fluid, which is a buoyancy generating means, so that buoyancy continuously acts on the floating body and is caused by the action of such buoyancy. Power was obtained through the movement of the floating body, but there was a problem that the efficiency is low.

The present invention is to solve the conventional problems as described above, the main object according to the present invention, the buoyant weight flows into the mechanism filled with liquid to rise by the buoyancy and then fall to the outside to rotate the gravity generated at this time Rotating to operate the turbine associated with this to produce power.

In addition, a separate buoyancy generating chamber is provided to rotate a plurality of buoyancy bodies along the chain or belt provided up and down to use the power source generated at this time, pneumatic pressure generated during the buoyancy generating process of liquid movement and liquid level control It is to provide a device that can be used as a power source by using.

In addition, it is intended to enable the continuous production of power by producing a reorganization and reuse configuration of the organic relation and pneumatic pressure so that the buoyancy weight input and external falling process is repeated.

In addition, the air pressure generated in the buoyancy generating process by connecting the hose to a separate pneumatic generating chamber to extract and to recycle it to improve the energy efficiency.

The power generation device configuration according to the present invention to solve the above problems and achieve the object, the position energy fluctuating chamber which is located at the bottom and has a plurality of pneumatic generating chamber, a plurality of pressure control valves and potential energy fluctuation device, and A first buoyancy chamber positioned to fill the buoyancy fluid upwards after loading the buoyancy weights to transfer the buoyancy weights upwardly, a first gate which is a boundary between the position energy fluctuation chamber upper portion and the lower portion of the first buoyancy chamber, and the buoyancy weight transfer. A first power source generator for generating gravity energy using a device, a first buoyancy chamber feeder, and a dropping device provided outside the first buoyancy chamber; A second buoyancy chamber including a plurality of pneumatic storage chambers, pneumatic filling devices, pneumatic extraction valves, pneumatic inlet valves, and pneumatic control valves, and a pneumatic generating chamber, twin gears, chain belts, and buoyancy pneumatic extraction valves inside the second buoyancy chamber. And a second power source generator for generating buoyancy energy using a plurality of buoyancy bodies utilizing pneumatic pressure; And a third power source generator for generating pneumatic energy, comprising a plurality of pneumatic generating chambers, pneumatic storage chambers, pneumatic inlet valves, pneumatic extraction valves and pneumatic charging devices, pneumatic control valves, and pneumatic motors. Pneumatic pressure generated in the first power source generator by interlocking the first to third power source generator by using the gravity energy generated during the buoyancy weight fall movement in the first power source generator device as a power source of an external power device; The second and third power sources are generated using energy to generate the second and third power sources.

In the first power source generator, a space (air layer) is formed on the top of the potential energy chamber, and a first buoyancy chamber is formed on the space (air layer). It is characterized in that the structure formed in three steps to open and control the liquid and buoyancy chamber liquid.

In addition, the second power source generating device and the third power source generating device are operated in conjunction with the pneumatic pressure generated by the operation of the first power source generating device, and the first power source generating device, the second power source generating device, and the third power source as necessary. The generator can be operated separately.

The second power source is buoyancy and pneumatic pressure, the third power source is characterized in that the pneumatic, the position energy fluctuating chamber, so that the level of the liquid liquid filled by the vertical movement of the position energy fluctuation device by the vertical movement Characterized in that the formed structure.

The first gate is formed between the potential energy chamber and the first buoyancy chamber, characterized in that for opening and controlling the liquid and pressure of the potential energy chamber and the first buoyancy chamber, the plurality of pressure control valve, The first buoyancy chamber, which is formed to interconnect and communicate with the buoyancy chamber and the potential energy fluctuation chamber, is opened by controlling the pressure of the first buoyancy chamber and the potential energy fluctuation chamber so as to be opened. It is characterized in that it is easy to open the first door formed in the lower portion.

In this case, the pressure is provided by a first pressure regulating valve, a second pressure regulating valve and a pneumatic jockey on the boundary of the first passage, and the pneumatic jockey is operated in conjunction with the second pressure regulating valve and the first pneumatic. It is characterized by.

In addition, the potential energy fluctuation device is introduced into or inflated into the liquid filled in the potential energy fluctuation chamber to adjust the level of the liquid level in the upper part of the potential energy fluctuation chamber liquid and the upper level of the first buoyancy chamber liquid, It is characterized by having a piston in the inner center of the cylindrical structure formed a plurality of stages to reduce the inner diameter to the inside.

In addition, the position energy fluctuator cap portion upper surface is a linear movement toward the upper direction to push up the introduced buoyancy weight to facilitate the opening and closing of the first door, characterized in that it further comprises a plurality of vertical rods in the vertical direction The inside of the potential energy fluctuation device may include a first pneumatic generating chamber having a first pneumatic extraction valve and a first air inlet valve.

In addition, a second pneumatic generating chamber having a second pneumatic extraction valve and a second air inlet valve on the upper surface of the potential energy chamber or the lower part of the first passage.

In addition, the first buoyancy chamber structure is firm, but attached to the appropriate buoyancy effect, when the gate between the first buoyancy chamber and the potential energy fluctuation chamber is opened to rise as buoyancy, or formed in anti-gravity state, the buoyancy chamber transfer device with minimal power The first buoyancy chamber is characterized in that the transfer in the vertical direction.

In addition, the position energy fluctuation lower chamber is characterized in that it comprises a third pneumatic generating chamber having a third pneumatic extraction valve and the third air inlet valve.

In addition, one side of the potential energy chamber is characterized in that it comprises a fourth pneumatic generating chamber having a fourth pneumatic extraction valve and the fourth air inlet valve.

In addition, a fifth pneumatic generating chamber having a fifth pneumatic extraction valve and a fifth air inlet valve is provided at one side of the first buoyancy chamber.

In addition, the buoyancy chamber transfer device is installed on the upper side of the first buoyancy chamber, and after opening the door between the first buoyancy chamber and the potential energy chamber, only the first buoyancy chamber structure transfers the proper distance in the upper vertical direction, the door Is closed, and when air enters the potential energy chamber, the weight of the structure (mass) of the first buoyancy chamber and the weight of the liquid (mass) inside the first buoyancy chamber are combined (mass), and the first buoyancy chamber is in its original position. It is characterized in that the pneumatic pressure is generated by the movement of the weight (mass) while returning to the lower vertical direction.

In this case, the buoyancy weight transfer device is formed on one side of the first buoyancy chamber upper portion is formed with an induction rail in order to raise the buoyancy weight appropriately upwards and then to the external automatic dropping device and after the first door is opened When the first buoyancy chamber rises in the upper vertical direction due to buoyancy, buoyancy pneumatics are generated, and are operated using the generated buoyancy pneumatics, characterized in that an actuator using pneumatic pressure is formed on one side.

The automatic dropping device is characterized in that it comprises a vertical support frame and the external drop-shaped "b" shaped to prepare to drop the buoyancy weight conveyed along the first inclined buoyancy chamber upper surface.

It is formed on one side of the position energy fluctuation chamber, and provided with a buoyancy thrust room that is communicated by the second gate, characterized in that the lower support buoyancy chamber is formed inclined more inward to the rail.

In addition, the second door uses the surface pressure and the sensor or the pneumatic pressure of the buoyancy weight conveyed through the rail of the inclined support so that buoyancy addition flows into the potential energy chamber to be loaded buoyancy weight It characterized in that the opening and closing by.

In addition, the liquid filling device is further formed on one side of the buoyancy chamber.

A generator turbine and a motor are formed on an upper portion of the upper dropping band vertical frame, and the generator turbine is connected to a string formed on the dropping band to generate power by using a buoyant force natural fall motion, and the motor is moved downward. It is characterized in that to raise the drop back to the top.

And, the second pneumatic extraction valve formed in the second pneumatic generating chamber, the second pneumatic generation to facilitate the increase of the liquid level in the potential energy fluctuation chamber while the air pressure can be extracted but the liquid extraction and air inflow is not easy The second air inlet valve formed in the second pneumatic generating chamber is configured to extract the pneumatic pressure generated inside the chamber and use the extracted pneumatic as energy. In order to facilitate the water level is lowered, the air is introduced into the second pneumatic generating chamber.

The first pneumatic extraction valve may extract the pneumatic pressure generated to facilitate the contraction of the potential energy fluctuation device and utilize the extracted pneumatic as energy, and the first air inlet valve may be configured to change the potential energy. In order to facilitate the introduction or inflation of the device, the air is introduced into the first pneumatic chamber.

On the other hand, the second power source generator, a pneumatic storage chamber which is operated by the pneumatic inflow of the first power source generator, a pneumatic charging device and a liquid filling device connected to the pneumatic storage chamber, pneumatic for extracting the pneumatic pressure in the pneumatic storage chamber An extraction valve, a buoyancy pneumatic inlet valve which is connected to the pneumatic extraction valve and is formed at one side of the second buoyancy chamber to introduce extraction pneumatic pressure, a pneumatic generating chamber formed at an upper portion of the second buoyancy chamber, and into the second buoyancy chamber. It comprises a twin first gear and twin second gear provided, the chain or belt connected to the gear, a plurality of buoyancy body connected to the chain or belt is rotated in the upward motion under the effect of pneumatic buoyancy, A buoyancy pneumatic extraction valve for inserting the pneumatic to the buoyancy body is further formed, further forming a liquid filling device on one side of the second buoyancy chamber, the twin It is characterized by supplying an energy source to the external power unit connected to the first gear.

In addition, the second power source generating device, in addition to the pneumatic inflow of the first power source can be independently operated by the pneumatic charging of the pneumatic charging device which is connected to the pneumatic storage chamber and is recycled by reusing and regenerating the used pneumatic Characterized in that configured to be operated as.

In this case, the pneumatic storage chamber forms a space for generating pneumatic pressure above the upper portion of the second buoyancy chamber to generate air extracted from a plurality of buoyancy bodies again by pneumatic pressure and flow into the pneumatic storage chamber to recycle the pneumatic pressure repeatedly. It is possible to operate the power generation unit, and recycle the inlet air pressure as a power source, and by using a pneumatic charging device and a pneumatic control valve formed on one side it is characterized in that it maintains the pneumatic pressure as necessary.

In addition, the liquid filling device formed on one side fills an appropriate amount of liquid therein, and forms a plurality of pneumatic inlet valves at the lower portion of the liquid, and allows low pneumatic inflow to pass through the liquid so that it is relatively higher than the upper pneumatic storage chamber. Low low pneumatic pressure is introduced into the liquid to produce a high air pressure above the upper portion.

The buoyancy pneumatic extraction valve may further include a buoyancy pneumatic extraction device formed under the second buoyancy chamber to introduce air pressure into the buoyancy body at a suitable time and connected thereto. It is closed and the lower part is opened so that the inlet air pressure can be trapped and have a buoyancy effect rising to the upper part, and a buoyancy control valve is formed on the upper part so that the buoyant body is not extracted when the buoyant body rises to the upper part. When the buoyancy body is rotated 180 degrees and lowered to the bottom of the liquid to maintain the pneumatic pressure is extracted and the liquid is introduced, characterized in that the buoyancy body is formed to facilitate the rise and fall.

In addition, the pneumatic pressure of the pneumatic generating chamber inside the second buoyancy chamber is characterized in that to further increase the buoyancy effect of the second buoyancy chamber by applying pressure to the liquid in the second buoyancy chamber.

On the other hand, the third power source generator, in addition to the pneumatic inflow of the first power source to be independently operated by the pneumatic charging of the pneumatic charging device formed in the third power source generator and connected to the pneumatic storage chamber through, pneumatic Recycling and regeneration of the pneumatic pressure used in the motor is characterized in that it is configured to be repeatedly operated.

In addition, the pneumatic motor, pneumatic turbine and the RP gear box is characterized in that it is driven by the pneumatic extracted from the pneumatic extraction valve formed on one side of the pneumatic storage chamber.

And, the pneumatic generating chamber, when the pneumatic used to operate the pneumatic motor or pneumatic turbine is discharged into the pneumatic generating chamber so that the pneumatic pressure required to reuse the discharged pneumatic discharge and the extracted pneumatic pressure into the pneumatic storage On one side, it is characterized in that the pneumatic charging device and the pneumatic control valve is formed to properly maintain the pneumatic pressure as necessary.

In addition, an appropriate amount of liquid is filled inside, and an appropriate amount of pneumatic inlet valve is formed in the lower portion of the liquid, and a low pneumatic inflow is made through the liquid so that a lower pneumatic pressure is lower than that of the upper pneumatic generating chamber. It is characterized in that it is generated at a high pneumatic pressure from above.

In addition, the pneumatic storage chamber is recycled by using the pneumatic inlet as a power source and is formed by connecting the pneumatic charging device and the pneumatic control valve on one side is characterized in that to maintain the pneumatically appropriate to the required level.

In addition, an appropriate amount of liquid is filled therein, and a pneumatic inlet valve is formed at the bottom of the liquid, so that pneumatic inflow is made through the liquid so that low pneumatic pressure lower than that of the upper pneumatic storage chamber can be introduced into the liquid. It is characterized in that it is generated by pneumatic.

When using the power generation apparatus according to the present invention, the buoyancy weight flows into the mechanism filled with liquid and is raised by the buoyancy, and then falls to the outside to rotate the rotating body by gravity generated at this time to operate the turbine linked to it to produce power. It becomes possible.

In addition, a separate buoyancy generating chamber is provided to rotate a plurality of buoyancy bodies along the chain or belt provided up and down to use the power source generated at this time, pneumatic pressure generated during the buoyancy generating process of liquid movement and liquid level control It can be used as a power source by using.

In addition, there is an effect of enabling the continuous production of power by producing a reorganization and reuse of the organic relation and pneumatic pressure so that the buoyancy weight and the external drop process is repeated.

In addition, by extracting the air pressure generated in the buoyancy generating process by connecting the hose to a separate pneumatic generating chamber and to reuse it has the effect of improving the energy efficiency.

Hereinafter, a power generation apparatus using gravity, buoyancy, and pneumatic pressure according to the present invention will be described in detail with reference to the accompanying drawings.

1 is a cross-sectional view showing a first embodiment of a first power source generator according to the present invention, FIG. 2 is a cross-sectional view of a second embodiment of a first power source generator according to the present invention, and FIGS. Fig. 9 is a configuration sectional view showing the operation sequence of the first power source generator according to the present invention, Fig. 9 is a configuration diagram of the pneumatic relations of the first to third power source generators according to the present invention, and Fig. 10 is a sectional view of the second power source generator according to the present invention. 11 is a configuration diagram of a third power source generator according to the present invention, FIG. 12 is a combination diagram of a first gate configuration according to the present invention, FIG. 13 is a sectional view of a second power source generator according to the present invention, and FIG. A plan view of a second power source generator according to the present invention.

Hereinafter, a first embodiment of a first power source generator according to the present invention will be described in detail with reference to FIG.

First there is provided a buoyancy chamber 170 filled with a buoyancy fluid therein. The buoyancy chamber 170 is a hollow column so that the filled water can not escape, it is preferable to be configured in a cylindrical shape to withstand the pressure of the water well. The buoyancy loading chamber is formed below the buoyancy chamber 170. The buoyancy loading chamber is a relatively small space compared to the buoyancy chamber is a place where the buoyancy body 10 temporarily stays in the buoyancy chamber 170. An on-off valve is formed between the buoyancy chamber and the buoyancy loading chamber to open and close as necessary so that water in the buoyancy chamber and water in the buoyancy loading chamber can communicate with each other. A gate 181 is formed between the buoyancy chamber and the buoyancy loading chamber.

One side of the buoyancy charge chamber is provided with an air valve for introducing air, and an air duct is connected to the air valve so that the top of the air duct is higher than the buoyancy charge chamber.

The buoyancy variable chamber is formed below the buoyancy charge chamber. The buoyancy variable room 160 is able to flow in and out of the buoyancy loading chamber to the lower lifting device 161 is formed to raise and lower the water to a certain height by the operation of the lifting device. The elevating device 161 is installed under the buoyancy loading chamber is made of a hydraulic jockey to lift or lower the lifting plate. The hydraulic jockey can be done manually, but it is preferable to lift up and down using a motor.

At one side of the buoyancy loading chamber, a loading waiting chamber 175 is formed. The loading waiting room 175 temporarily waits before entering the buoyancy body 10 buoyancy loading chamber and is formed with a push rod spring to push the buoyancy body 10 forward as needed.

The buoyancy main gate is formed between the buoyancy loading room and the loading waiting room. The buoyancy order door is formed to be opened and closed. At the bottom of the buoyancy chamber 170, a door 181 communicating with the buoyancy loading chamber is formed. The gate 181 is installed on the bottom of the buoyancy chamber 170, one side is fixed to the bottom of the buoyancy chamber 170, so that the link can be opened and closed while rotating the link up and down the axis, in this case using a material similar in specific gravity to water It is desirable to.

A sluice is formed at the top of the buoyancy chamber 170. The water gate is hinged to the wall of the buoyancy chamber 170 so as to rotate outwardly about the hinge. When the contact sensor is formed inside the water gate and the buoyancy body 10 rises and contacts, the motor 450 is operated to open while the water gate rotates to the outside. On the outside of the buoyancy chamber 170, a first roller and a second roller spaced apart from each other by a predetermined distance up and down are installed to substantially match the height of the buoyancy chamber 170, and a chain is mounted therebetween. Generator turbines are combined.

A conveyor belt is connected between the first roller and the water gate, and the conveyor belt guides the buoyancy bodies falling through the water gate to be connected to the chain. When combined with the chain, the turbine is dropped by gravity to rotate the chain and is connected to the first roller. To turn.

Referring to the operation of the buoyancy generator according to the present invention configured as described above are as follows. The buoyancy chamber is filled with water, buoyancy chamber, buoyancy loading chamber, buoyancy variable chamber are closed and buoyancy body is provided in the loading waiting room.

In order to put the buoyancy body 10 provided in the loading waiting room into the buoyancy loading chamber, the water of the buoyancy loading chamber should be drained. The lift plate is lowered by driving the hydraulic jockey formed in the lower part of the buoyancy variable chamber with the loading chamber valve open to drain water from the buoyancy loading chamber. At this time, the air valve formed on one side of the buoyancy loading chamber is opened so that the negative pressure does not occur when the water in the loading waiting chamber escapes. When the lifting plate 161 is lowered, the water in the loading chamber flows into the buoyancy variable chamber 160 through the loading chamber valve, and when the water in the loading chamber completely escapes into the buoyancy variable chamber 160, the buoyancy column installed in the buoyancy loading chamber. Open the door. When the buoyancy injection door is opened, the buoyancy body prepared in the loading waiting room is pushed into the buoyancy loading room.

When the buoyancy body 10 is inserted into the buoyancy loading chamber, the hydraulic jockey is driven in reverse to raise the lifting plate, and when the lifting plate is raised, the water in the buoyancy variable chamber flows into the buoyancy loading chamber through the loading chamber valve and the water in the buoyancy changing room. When fully introduced into the buoyancy chamber, the valve of the buoyancy chamber is closed to prevent water from escaping from the buoyancy chamber. When the water is completely filled in the buoyancy chamber, close the air valve to prevent water from flowing out through the air valve.

When the buoyancy chamber is completely filled with water, the buoyancy chamber valve is opened to allow the water in the buoyancy chamber to communicate with the water in the buoyancy chamber, so that the buoyancy chamber and the buoyancy chamber are pressure balanced. The buoyancy body (10) inserted into the buoyancy loading chamber rises up by the buoyancy and the pressure balance is made, so when the pressure is applied to the door and the door is lifted up around the hinge, the buoyancy body (10) opens the door (181). Through the buoyancy chamber.

The buoyancy body 10 introduced into the buoyancy chamber 170 is raised to the top of the buoyancy chamber by the buoyancy of the water filled in the buoyancy chamber 170. In the buoyancy chamber, an induction rail for guiding the buoyancy body is formed so that it rises without flow. . Since the buoyancy body 10 has its own weight, even if it goes up to the top of the buoyancy chamber, some are submerged and some are out of the water.

When the buoyancy body 10 is raised to the upper end is in contact with the sensor formed on one side of the water gate, the water gate is rotated to open the outside when the sensor is in contact, the weight is slipped or rolled along the inclined surface of the buoyancy member to fall out of the water gate. When the weight is separated from the buoyancy member, the buoyancy member floats and is only submerged in the water. At this time, the arm operated from the motor is rotated to push the buoyancy member out of the water gate. The buoyancy member may be connected to the weight and connecting muscles to hang the buoyancy member when the weight is dropped out of the gate and dropped by gravity.

While the buoyancy body 10, which is made up of the buoyancy member and the weight, moves to the upper side of the buoyancy chamber 170, the door 181 is reversed and the buoyancy chamber valve is closed to close the buoyancy chamber 170 and the buoyancy loading chamber.

When the buoyancy chamber 170 is closed, the lifting plate 161 is lowered by the operation of the hydraulic jockey to completely drain the water of the buoyancy loading chamber into the buoyancy variable chamber 160 and when the water of the buoyancy loading chamber is completely drained, Open to prevent negative pressure in the buoyancy chamber. When negative pressure is generated, water does not drain well.

Weights that fall out of the water gate are transported down the conveyor belt formed near the water gate to the second roller. The weight transferred to the second roller is combined with the chain connected to the second roller and hung down by the gravity chain, where the first roller is connected to the first roller and the first turbine is connected to the generator turbine. As it rotates, the generator turbine rotates to produce power. The first roller may be used by directly connecting a power machine without connecting a generator turbine.

The weight coming down the chain is separated by passing through the first roller and falls into the loading waiting room, and the buoyancy body first falls into the loading waiting room and combines the weight and the buoyancy member. That is, the first loading standby state. Thus, if the buoyancy body is raised and lowered repeatedly, continuous development is possible.

Hereinafter, the configuration according to the second embodiment of the first power source generator 100 according to the present invention will be described in detail. Hereinafter, although the names of the components are different, the identification numbers in the drawings will be described collectively.

First, in the first power source generator 100, the buoyancy weight 10 is moved upward by using the buoyancy principle, and then the first power source is moved through the vertical drop motion by the gravity of the buoyancy weight 10 in the external dropping device. Generate. Hereinafter, the first power source generator 100 according to the present invention will be described in detail with reference to FIG. 2.

First, the first buoyancy chamber 170 in which buoyancy fluid is filled therein is provided at an upper portion thereof. Here, the buoyancy fluid can be used in various ways, such as water, brine, antifreeze, but it is preferable to use the water that is most easily available around us.

The first buoyancy chamber 170 has a hollow pillar shape to prevent liquid from escaping and has a cylindrical shape to withstand the pressure of the liquid. In addition, the first buoyancy chamber 170 should be opened and controlled with the potential energy chamber 160.

The lower portion of the first buoyancy chamber 170 is provided with a cylindrical position energy fluctuation chamber 160 having a larger circumferential length with the first passage 181 as a boundary. The potential energy fluctuation chamber 160 is a place where the incoming buoyancy weight 10 temporarily stays. A first pressure regulating valve 184 and a second pressure regulating valve 185 are formed between the first buoyancy chamber 170 and the positional energy fluctuation chamber 160 to open and close as necessary to open and close the first buoyancy chamber 170. The pressure and the pressure of the potential energy fluctuation chamber 160 may be communicated with each other, and are configured around the first gate 181.

The jockey 186 formed by being connected to the first passage 181 and the second pressure control valve 185 under the first buoyancy chamber 170 is the buoyancy chamber moving device 190 after the first passage 181 is opened. It is configured to fix the first door 181 does not close until the first buoyancy chamber 170 is properly pulled up.

In addition, the potential energy variable device 161 is provided inside the potential energy variable chamber 160. Here, the position energy fluctuating device 161 is a cylindrical structure having a plurality of stages formed so that the inner diameter of the central portion is reduced to the inside of the central portion having a piston part 162 at the inner center thereof, and the up and down by the incoming power or hydraulic and pneumatic pressure. Or lateral movement. To this end, it is preferable to provide the rail unit 164 on the outside of the potential energy changer between outer frames having different diameters.

In addition, the rod portion bar 165 in the vertical direction to facilitate the opening and closing of the first gate 181 by pushing the buoyant weight (10) flowing in the linear direction toward the upper direction on the upper surface of the lid portion 165 of the position energy change device (161). It is preferable to provide a plurality of 163 more.

In addition, a first pneumatic generating chamber 110 having a first pneumatic extraction valve 111 and a first air inlet valve 112 is provided inside the potential energy varying apparatus 161 in the potential energy varying chamber 160. Have it ready.

At this time, the first pneumatic extraction valve 111 is connected to the first pneumatic inlet valve 113 of the 2-1 pneumatic storage chamber 230 of the 2-1 power source generator 200A. In this case, the first air inlet valve 112 is formed so that air is introduced but not pneumatic.

In addition, a second pneumatic generating chamber having a second pneumatic extraction valve 121 and a second air inlet valve 122 between the liquid level portion of the potential energy fluctuation chamber 160 and the first gate 181. 120.

At this time, the second pneumatic extraction valve 121 is connected to the second pneumatic inlet valve 123 of the 2-1 pneumatic storage chamber 230 of the 2-1 power source generator 200A.

 In addition, a lower portion of the potential energy fluctuation chamber 160 includes a third pneumatic generating chamber 130 having a third pneumatic extraction valve 131 and a third air inlet valve 132.

At this time, the third pneumatic extraction valve 131 is connected to the third pneumatic inlet valve 133 of the 3-1 pneumatic storage chamber 310 of the 3-1 th power source generator 300A.

In addition, one side of the potential energy chamber 160 is provided with a fourth pneumatic generating chamber 140 having a fourth pneumatic extraction valve 141 and a fourth air inlet valve 142.

At this time, the fourth pneumatic extraction valve 143 is connected to the fourth pneumatic inlet valve 143 of the 3-1 pneumatic storage chamber 310 of the 3-1 th power source generator 300A.

In addition, a fifth pneumatic generating chamber 150 including a fifth pneumatic extraction valve 151 and a fifth air inlet valve 152 is provided at one outside of the first buoyancy chamber 170.

At this time, the fifth air extraction valve 151 is connected to the fifth pneumatic inlet valve 153 of the 3-1 pneumatic storage chamber 310 of the 3-1 th power source generator 300A.

Meanwhile, a plurality of first pressure control valves 184 are provided in the door to communicate the pressures of the first buoyancy chamber 170 and the potential energy change chamber 160, and a second portion of the first buoyancy chamber 170 is disposed below the second buoyancy chamber 170. And a pressure regulating valve 185.

In addition, the first passage 181 and the second pressure control valve 185 is more preferably formed by connecting the jockey 186. The jockey 186 is formed by opening the second pressure regulating valve and connected to the first gate so that the first gate 181 is formed by friction and resistance of the liquid when the buoyancy chamber is vertically moved upward by the first buoyancy chamber transfer device. ) To prevent it from closing first.

Here, the first and second pressure control valves 184 and 185 are formed such that the pressure of the first buoyancy chamber 170 and the pressure change chamber 160 is connected to each other to communicate with the first buoyancy chamber 170. And the pressure in the potential energy chamber 160 to easily open the first door 181 that supported the weight and pressure of the liquid in the first buoyancy chamber 170.

On the other hand, the upper side of the first buoyancy chamber 170, the upper portion of the buoyancy weight conveying device 191 is formed in order to transfer the buoyancy weight 10 to the outer dropping table 171 after the up.

The automatic drop device includes a vertical support frame 173 and the upper drop 171 of the "b" shaped to prepare to drop the buoyancy weight 10 conveyed along the upper inclined surface of the first buoyancy chamber 170. To configure, but the lower side of the vertical support frame 173 and the side of the drop 171 is coupled to the roller 176 to form a rail 174 along the combined axis.

In addition, the upper dropping table 171 and the generator turbine 400 are connected in a line to generate energy using gravity as a first power source by using the rotational force of the turbine formed in the power unit according to the natural dropping motion of the buoyancy weight 10. Let it be

In addition, the first buoyancy chamber 170 is installed above the first buoyancy chamber 170 by using the liquid movement of the first buoyancy chamber attached to the appropriate buoyancy effect is transferred to the vertical direction in the vertical and pneumatic It has a first buoyancy chamber feeder 190 that can be generated. To this end, it is configured to form a plurality of O-rings 172 on the lower outer side of the first buoyancy chamber frame.

In addition, the buoyancy thruster 175 is formed on one side of the position energy change chamber 160 and is communicated by the second gate 182, and the rail further inclined inward to the lower support of the buoyancy thruster 175. The second gate 182 is introduced into the potential energy chamber 160, the surface of the buoyancy weight 10 is transferred through the rail of the inclined support so that the buoyancy weight 10 can be loaded It is configured to open and close by using pressure and sensor or pneumatic by weight (mass).

In addition, a liquid filling device is further formed on one side of the buoyancy attracting chamber 175 to allow an appropriate amount of water to flow into the potential energy chamber 160 as needed. This is to adjust the liquid level so that the power generator can continue to operate.

On the other hand, the second pneumatic extraction valve 121 formed in the second pneumatic generating chamber 120, the pneumatic pressure generated to facilitate the liquid level of the position energy fluctuation chamber 160 is extracted and extracted The air inlet valve 122 formed in the second pneumatic generating chamber 120 may allow air to be utilized as energy, so that the liquid liquid level in the potential energy variable chamber 160 may be lowered. It characterized in that the inflow.

In addition, the first pneumatic extraction valve 111 formed in the first pneumatic generating chamber 110 formed in the potential energy variable device 161, to facilitate the potential energy variable device 161 to contract. The first air inlet valve 112 is formed in the first pneumatic generating chamber 110 formed in the potential energy fluctuation device 161 to extract the generated pneumatic pressure and use the extracted pneumatic as energy. The potential energy fluctuation medium 161 is characterized in that the air is introduced to facilitate the inflow or inflation.

Hereinafter, an operation of the first power source generator 100 will be described in detail with reference to FIG. 2.

First, an appropriate amount of liquid is filled in the first buoyancy chamber 170, and an appropriate liquid is filled so that the buoyancy weight 10 easily flows into the potential energy fluctuation chamber 160, and the buoyancy buoyancy chamber 175 is buoyant. The weight 10 is provided.

When the second communication door 182 is formed between the buoyancy propelling chamber 175 and the potential energy fluctuation chamber 160 by using the sensor and power or pneumatic pressure for the buoyant weight (mass) to control traffic, the buoyancy weight ( 10) the second entrance 182 is closed by the pneumatic pressure, the sensor and the power is lowered due to the buoyant weight movement is placed in the position energy fluctuation chamber 160 along the inclined rail. Here, the rail is inclined because the buoyancy force waiting chamber 175 is slightly higher and the potential energy variable chamber 160 is low, so that the buoyancy weight 10 naturally flows into the potential energy variable chamber 160.

The position energy fluctuation device 161 formed inside the position energy fluctuation chamber 160 by a sensor and a power flows upward or leftward or inflated to increase the liquid level, and an upward bar on the position energy fluctuation device 161. Rods 163 are formed in a large number to push up the buoyancy weight (10) lower. Accordingly, the buoyancy weight 10 rises under the force of its own buoyancy and the force pushed by the positional energy fluctuation device 161, and pushes up the first pressure control valve 184 formed at the upper portion of the first buoyancy chamber 170. And by adjusting the pressure of the potential energy chamber 160 to easily open the first door 181 and flows into the first buoyancy chamber 170. In this case, the first pressure control valve 184 may be connected by pushing the power unit in addition to the buoyancy of the buoyancy weight 10 and the force pushed up by the position energy fluctuation device 162.

In general, in order to raise the entire liquid level, a force to lift the weight (mass) of the entire liquid by a certain height is required, but the potential energy changer 161 is introduced or swelled by a certain volume into the liquid to adjust the liquid level. Raise the liquid level with less force than lifting the entire liquid.

Jockey, which is a device for operating the second pressure control valve 185 formed below the first buoyancy chamber 170 and opening the door by the sensor and the power at the time when the potential energy change device 161 is introduced or inflated. It is preferable to open the second pressure control valve 185 and to open the pressure of the first buoyancy chamber 170 and the potential energy change chamber 160 to facilitate the pressure and liquid level control.

Here, the shape of the first pressure control valve 184 and the second pressure control valve 185 is formed so that the end of the portion introduced into the first buoyancy chamber 170 is pointed and there is less surface contact with the liquid. It is formed so that it can be easily introduced under the minimum pressure.

The first air inlet valve 112 and the first pneumatic extraction valve 111 are formed in the first pneumatic generating chamber 110 below the potential energy fluctuation device 161 and the potential energy fluctuation device 161 is introduced or inflated. When the air is introduced through the first air inlet valve 112, when it exits or contracts, the pneumatic pressure is the first pneumatic inflow of the 2-1 power source generator 200A connected to the first pneumatic extraction valve 111 It is moved to the 2-1 pneumatic storage chamber 230 through the valve 113. In addition, the first air inlet valve 112 is formed so that air is introduced, but the pneumatic pressure is not extracted.

A second air inlet valve 122 and a second pneumatic extraction valve 121 are formed in the second pneumatic generating chamber 120 at the upper portion of the potential energy fluctuation chamber 160. The pneumatic pressure generated as the liquid level is increased is the second pneumatic pressure. When the liquid level is lowered and is moved to the 2-1 pneumatic storage chamber 230 through the second pneumatic inlet valve 123 of the 2-1 power source generator 200A connected to the extraction valve 121, the second air inflow Air flows into the valve 122.

In this case, the second pneumatic extraction valve 121 is formed to extract the pneumatic pressure, but not to extract the liquid, and the second air inlet valve 122 is formed so that the air is introduced but the liquid is not extracted.

When the pressure of the potential energy chamber 160 is opened with the first buoyancy chamber 170, the first gate 181 formed under the first buoyancy chamber 170 and under the weight and pressure of the liquid is easily opened and buoyant weight 10 is opened by pushing up the first passage 181, the buoyancy weight 10 is introduced into the first buoyancy chamber 170 to rise to the top.

The potential energy fluctuation device 161 continuously or appropriately flows in order to easily move from the upper portion to the external dropping device after the buoyancy weight 10 flows into the first buoyancy chamber 170 even after the first door 181 is opened. It is preferable to keep the liquid level of the first buoyancy chamber 170 appropriately at all times.

This is because when the buoyancy weight 10 is moved from the top to the outer dropping zone 171 after the first gate 181 is closed, the liquid level of the first buoyancy chamber 170 is lowered by the volume of the buoyancy weight 10 and is positioned. This is because the liquid level of the energy fluctuation chamber 160 is relatively high, which hinders the repeated operation of the first power source generator 100.

When the two openings are opened, the liquid weight (mass) and the side pressure of the first buoyancy chamber 170 are moved to the potential energy chamber 160, and the third pneumatic generating chamber 130 is formed below the potential energy chamber 160. In the pneumatic pressure generated by using the liquid weight (mass) of the first buoyancy chamber 170 moved in the fourth pneumatic pressure generating chamber 140 formed on one side using the liquid side pressure of the first buoyancy chamber 170 moved Creates pneumatics.

The third pneumatic generating chamber 130 expands and contracts up and down. When receiving the weight (mass) of the moved liquid, the third pneumatic generating chamber contracts to generate pneumatic pressure, and the generated pneumatic pressure is connected to the third pneumatic extraction valve 131. 1 is moved to the 3-1 pneumatic storage chamber 310 through the third pneumatic inlet valve 133 of the power source generator 300A.

The fourth pneumatic generating chamber 140 expands and contracts to the side, and upon receiving the moved liquid side pressure, the fourth pneumatic generating chamber contracts to generate pneumatic pressure, and the generated pneumatic pressure is generated through the 3-1 power source generator connected to the fourth pneumatic extraction valve 141 ( The fourth pneumatic inlet valve 143 of 300A is moved to the 3-1 pneumatic storage chamber 310.

On the other hand, as the first gate 181 formed below the first buoyancy chamber 170 is closed and the position energy fluctuation device 161 contracts, the liquid level of the potential energy fluctuation chamber 160 is lowered, and when the air is introduced, the potential energy fluctuation chamber 160 and the first buoyancy chamber 170 is separated.

Accordingly, when the liquid weight (mass) and the side pressure are moved back to the first buoyancy chamber 170 and the liquid weight (mass) and the side pressure of the potential energy variable chamber 160 is lowered, the third pneumatic generating chamber 130 and the third pressure are lowered. 4 pneumatic generation chamber 140 is formed so that the air can be expanded to the original state.

In this case, the pneumatic extraction valves 131 and 141 formed in the third pneumatic generating chamber 130 and the fourth pneumatic generating chamber 140 are extracted with pneumatic pressure, but air is not introduced, and air inlet valves 132 and 142 are provided. The air is introduced but the pneumatic pressure is not extracted.

In addition, the first gate 181 is fixed to the lower portion of the first buoyancy chamber 170, the link is formed so as to open and close the link up and down on the axis and give a firm but buoyant effect to act close to anti-gravity, but to sink itself It is preferable to.

In this case, the first buoyancy chamber 170 is connected to the potential energy chamber 160, but is formed to be separated so as to move up and down a proper distance, but firmly so that the liquid pressure can not escape from the connected portion and on the outside one side The fifth pneumatic generating chamber 150 is formed.

And, the first buoyancy chamber 170 structure is firm but attached to the appropriate buoyancy effect when the door between the first buoyancy chamber 170 and the potential energy change chamber 160 is formed to rise to buoyancy or configured to anti-gravity state The buoyancy chamber feeder transfers the first buoyancy chamber 170 to the upper vertical direction with minimal power.

Accordingly, the first passage 181 of the lower portion of the first buoyancy chamber 110 is opened and the buoyancy weight 10 rises upward through the first passage 181 and is formed on the first buoyancy chamber 170. The fifth pneumatic generating chamber 150 is easily pulled up when the first buoyancy chamber feeding device 190 pulls up the first buoyancy chamber 170 a proper distance to generate air pressure in the fifth pneumatic generating chamber 150. The air is introduced into the fifth air inlet valve 152. In this case, it is preferable to form an air hole 159 in the lower outer frame of the fifth pneumatic generating chamber 150 to appropriately adjust the pressure.

In addition, in this case, a guide rail is formed between the lower portion of the outer diameter of the first buoyancy chamber of the cylindrical shape and the inner diameter portion of the larger structure surrounding the same to facilitate the movement when the first buoyancy chamber is moved up and down and to easily hold the center movement. You can do it.

In this case, since the first gate 181 below the first buoyancy chamber 170 is open, only the structure in which the liquid remains and the first buoyancy chamber 170 is raised.

When the first passage 181 is opened, the jockey 186 acting as the second pressure regulating check ball 185 and the opening opening fixing device formed under the first buoyancy chamber 170 is the first buoyancy chamber 170. The first door 181 is not closed until it rises upward. After the first buoyancy chamber 170 is sufficiently raised, the jockey 186 closes the second pressure control valve 185 by the sensor and the power. While releasing the fixing of the first passage 181, the first passage 181 sinks and closes itself.

When the first gate 181 is closed and the position energy fluctuation device 161 properly exits or contracts, air flows into the position energy fluctuation chamber 160 while the liquid and the pressure in the first buoyancy chamber 170 are positioned. The first pressure control valve 184, which is separated from the energy fluctuation chamber 160 and formed at the bottom of the first buoyancy chamber 170, is automatically closed under the influence of the liquid and the pressure of the first buoyancy chamber 170 to escape. do.

As the liquid weight (mass) and the pressure of the potential energy variable chamber 160 and the first buoyancy chamber 170 are separated by the first gate 181, the first buoyancy chamber 170 is the weight of the liquid in the structure and the sum ( Mass) and descends to the lower portion, pressurizing the fifth pneumatic generating chamber 150 and descending to the original position while generating pneumatic pressure.

The pneumatic pressure generated in the fifth pneumatic generating chamber 150 is controlled through the fifth pneumatic inlet valve 153 of the 3-1 power source generator 300A connected to the fifth pneumatic extraction valve 151. Is moved to 310.

The fifth air inlet valve 152 of the fifth pneumatic generating chamber 150 is formed so that air is introduced but air is not extracted, and the fifth pneumatic extraction valve 151 of the fifth pneumatic generating chamber 150 extracts pneumatic pressure. However, air is not formed.

When the buoyancy weight 10 rises to the upper portion of the first buoyancy chamber 170, the buoyancy force feeding device 191 formed at the upper portion transfers the buoyancy weight to the external dropping device by the sensor and the power.

In addition, the buoyancy weight conveying device 191 may be generated by the buoyancy pneumatic pressure when the first buoyancy chamber ascends in the upper vertical direction due to the buoyancy after the first door is opened and may be operated using the generated buoyancy pneumatic pressure. have.

The prepared buoyancy weight 10 falls by gravity and falls to the buoyancy force waiting room 175 after falling to the lower buoyancy weight automatic transfer device 172 to be in an initial state.

One side of the buoyancy propelling chamber 175 constitutes a first liquid filling device so that when the liquid volume of the first power source generator 100 is naturally reduced or insufficient, the liquid volume is always appropriate by filling an appropriate amount of liquid by the sensor and the power. It is desirable to keep it.

The generator turbine 400 is connected to the string formed in the dropping table 171 to generate power while the generator turbine 400 rotates when the buoyancy weight 10 falls freely. Of course, the motor 450 is formed on the upper portion of the vertical frame 173, and the motor 450 is operated by the sensor and the power after the dropping band is lowered to pull up the dropping band to its original home position.

In the above, only one example of the dropping device is exemplified, and various other dropping devices and power driving system configurations that can be implemented are, of course, possible.

Hereinafter, the second power source generator 200A will be described in detail with reference to FIG. 3.

 The pneumatic pressure generated in the first pneumatic generating chamber 110 and the second pneumatic generating chamber 120 of the first power source generator 100 is determined by the 2-1 pneumatic storage chamber 230 of the second power source generating apparatus 200A. Pneumatic inflow valves (113, 123) are introduced into.

In addition, the 2-1 pneumatic storage chamber 230 may be a high pneumatic pressure by the low pneumatic inflow by allowing the inlet air pressure to pass through the liquid appropriately filled therein to be generated at the appropriate pneumatic pressure from the top. In this case, the liquid filling device 238 is connected to one side of the pneumatic storage chamber 230, and when the liquid is naturally reduced or insufficient, it is operated by the sensor and the power to fill the appropriate liquid to maintain the liquid volume at all times.

 One side of the 2-1 pneumatic storage chamber 230 is formed with a pneumatic charging device 237 such as a compressor so that the proper pneumatic pressure can be maintained by operating by the sensor and the power.

 Pneumatic pressure of the 2-1 pneumatic storage chamber 230 flows into the buoyancy body through the 2-1 buoyancy pneumatic inlet valve 233 connected to the 2-1 pneumatic extraction valve 231 through the buoyancy pneumatic extraction valve 256 Be sure to

 The 2-1 pneumatic control valve 235 formed in the 2-1 pneumatic storage chamber 230 extracts pneumatic pressure so that the air pressure of the 2-1 pneumatic storage chamber 230 is properly maintained as necessary.

Inside the second buoyancy chamber 200A sealed in a hollow cylindrical shape, an appropriate amount of liquid is filled, and a 2-1 pneumatic generation chamber 210 is formed on the upper portion of the liquid, and a twin second having the same size above the liquid. The gears 253 are formed to be spaced apart by a predetermined distance, and the twin first gears 254 having the same standard are formed to be spaced apart by a predetermined distance, and a 2-1 liquid filling device is formed at an outer side.

A chain 259 or a belt is vertically disposed on the right gear 253b of the twin second gear 253 formed in the second buoyancy chamber 200A and the right gear 254b of the twin first gear 254 formed in the lower portion. A chain 259 or a belt is connected to the left gear of the twin second gear 253 formed in the upper portion and the left gear of the twin first gear 254 formed in the upper portion.

The buoyancy body 251 is formed so that the left side, the right side, the upper part is blocked, and the lower part is opened so as to trap the inflow air pressure and have the buoyancy effect rising to the upper portion of the second buoyancy chamber 200A, and the buoyancy control valve ( 258 is formed to prevent air from being extracted when the buoyancy body rises, thereby maintaining the buoyancy effect, and the raised buoyancy body 251 turns the second gear 253 by the chain 259 or the belt and falls back to the lower portion of the liquid. When the upper and lower sides of the buoyancy body 251 is changed so that the air is extracted and the liquid is introduced into the buoyancy body 251 to facilitate the buoyancy body 251 to rise and fall.

The left side of the buoyancy body 251 is connected and fixed to one side of the chain 259 or the belt 259 connected to the left side 254a of the lower twin first gear 254 and the left side 253a of the upper twin second gear 253. The right side is formed to be connected to and fixed to the chain 259 or belt 259 connected to the right side of the upper twin first gear 253 and the right side of the lower twin twin gear 254 buoyancy body 251 Traps air and ascends without play and rotates the twin first gear and twin second gear.

The buoyancy pneumatic extraction valve 256 formed at one side of the lower portion of the second buoyancy chamber 200A is connected to the pneumatic extraction valve 231 of the 2-1 pneumatic storage chamber 230 and the buoyancy body 251 may receive pneumatic pressure. When it is in an appropriate position, the buoyancy pneumatic extraction valve 256 is opened by the sensor, and the pneumatic pressure of the 2-1 pneumatic storage chamber 230 is extracted and introduced into the buoyancy body 251, and the buoyancy body 251 is formed of pneumatic buoyancy. The effect rises above the second buoyancy chamber.

The buoyancy pneumatic extraction valve 256 may be formed and mounted so that the pneumatic extraction device is connected to facilitate pneumatic extraction as necessary.

The chain 259 or the belt 259 formed on the twin first gear and the twin second gear is formed by appropriately connecting a large number of buoyancy bodies 251, and a time point at which the previously raised buoyancy body 251 arrives above the buoyancy chamber. In this case, it is preferable that the rear buoyancy body 251 rises to allow the first twin gear and the second twin gear to rotate continuously without stopping.

The buoyancy body 251 floated upward rotates 180 ° along the twin second gear and descends to the lower portion of the second buoyancy chamber while releasing air, and when descending, the buoyancy control valve introduces liquid to facilitate the buoyancy body descending. This is preferred.

Meanwhile, an appropriate amount of pneumatic pressure is filled in the 2-1 pneumatic generation chamber 210 above the 2-1 buoyancy chamber 200A, and the air flowing out of the buoyancy body 251 is continuously collected to increase the pneumatic pressure.

The pneumatic pressure generated in the 2-1 pneumatic generation chamber 210 is a 2-2 power source generator connected to the 2-1 pneumatic extraction valve 211 formed on the 2-1 buoyancy chamber 200A as needed ( The 2-2 power source generator 200B and the 2-2 power source generator 200C by the method of recycling the inlet into the 2-2 pneumatic inlet valve 213 of the 2-2 pneumatic storage chamber 240 of 200B). It is possible to increase power generation efficiency while generating power repeatedly until the pneumatic pressure is exhausted.

Meanwhile, 2-1 pneumatic regulating valve 215 and 2-1-2 pneumatic regulating valve 235 are formed at one side of the 2-1 pneumatic generating chamber 210 and 2-1 pneumatic storage chamber 230. So that proper air pressure is maintained.

In another embodiment, the pneumatic pressure generated inside the 2-1 pneumatic generating chamber 210 is applied to the lower liquid and the buoyancy effect is increased when the liquid pressure is increased, so that the buoyancy body 251 is more easily raised. I can do it.

In this case, the 2-1 liquid filling device 218 is formed at one side of the 2-1 buoyancy chamber 200A, and when the liquid volume is naturally reduced or insufficient, the liquid is filled with an appropriate amount by the sensor and the power. It is desirable to keep the ratio appropriately at all times.

That is, according to the configuration and operation, the twin first gear is continuously rotated and the connected generator turbine 400 is also continuously rotated to produce power. Of course, the twin first roller can also be used by directly connecting the power machine without connecting the generator turbine.

 In addition, the second power source generator 200A forms a pneumatic storage chamber in which a pneumatic charging device is independently formed as needed without connecting to the first power source generator, thereby recycling the pneumatic pressure in the same manner as above and repeatedly producing power.

 Hereinafter, the third power source generator 300 according to the present invention will be described in detail with reference to FIGS. 2 and 4.

The 3-1 power source generator 300A includes the 3-1 pneumatic storage chamber 310, the 3-1 pneumatic charging device 317, the 3-1 pneumatic extraction valve 311, and the 3-1 air inflow. The valve 133, 143, 153, 3-1 pneumatic regulating valve 315, 3-1 pneumatic turbine 317 and 3-1 AlpH regulating gear box 316 are configured, and the third The -1 pneumatic turbine 319 is preferably configured to be driven by pneumatic extracted from the 3-1 pneumatic extraction valve 311 formed at one side of the 3-1 pneumatic storage chamber 310 outside.

 In addition, the 3-1 power source generator 300A introduces the pneumatic pressure generated by the first power source generator 100 into the 3-1 pneumatic storage chamber 310 and utilizes the pneumatic pressure of the 3-1 pneumatic storage chamber 310. To operate the generator 319.

In more detail, in the 3-1 pneumatic storage chamber 310 filled with pneumatic pressure therein, the first power source generator 100, the third pneumatic generating chamber 130, and the third pneumatic extraction valve 131 are connected to each other. 3-1 pneumatic inlet valve 133, the first power source generator 100, the fourth pneumatic inlet valve 143, the first power source connected to the fourth pneumatic extraction valve 141 of the fourth pneumatic generating chamber 140 The generator 100 includes a fifth pneumatic inlet valve 153 connected to the fifth pneumatic extraction valve of the fifth pneumatic generating chamber 150.

 On the other hand, one side of the 3-1 pneumatic storage chamber 131 is provided with a pneumatic charging device such as compressor 317 and a pneumatic control device to ensure that the necessary pneumatic pressure is always maintained by the sensor and power.

The pneumatic air flowing into the 3-1 pneumatic storage chamber 310 is extracted by the 3-1 pneumatic extraction valve 311 formed at one side of the 3-1 pneumatic storage chamber 310 to operate the pneumatic motor, and 3-1 Pneumatic turbine 319 is rotated to produce power, if necessary, can be used by directly connecting the power machine by pneumatic without using a pneumatic motor.

In addition, the 3-1 pneumatic storage chamber 310 may generate a high pneumatic pressure with a low pneumatic inflow by allowing the inlet pneumatic pressure to pass through the liquid appropriately filled therein to be generated at an appropriate pneumatic pressure at the top. In this case, the liquid filling device 318 is connected to one side of the pneumatic storage chamber 310, and when the liquid is naturally reduced or insufficient, the liquid is operated by the sensor and the power to fill the appropriate liquid so that the liquid volume is always maintained properly.

On the other hand, each of the pneumatic storage chamber (310, 330) and one side of the pneumatic generating chamber 320 is preferably provided with a pneumatic control valve (315, 325, 335) for appropriately adjusting the internal pneumatic pressure.

The pneumatic pressure used to drive the 3-1 pneumatic motor is introduced back into the 3-2 pneumatic pressure generating chamber 320 to be regenerated to the required pneumatic pressure, and the generated pneumatic pressure is stored in the 3-2 pneumatic storage chamber 330. To generate energy to run the turbine 339 by recycling it to another power source, increasing it to the third power source generator 300A, the third power source generator 300B, and the like until the pneumatic pressure is exhausted. Can generate power to increase power generation efficiency.

In addition, the 3-2 pneumatic generating chamber 320 may generate a high pneumatic pressure with a low pneumatic inlet by passing the incoming pneumatic pressure through the liquid appropriately filled therein to generate a proper pneumatic pressure from the top. At this time, the liquid filling device 328 is connected to one side of the pneumatic generating chamber 320, and when the liquid is naturally reduced or insufficient, it is operated by the sensor and the power to fill the proper liquid to maintain the liquid volume at all times. .

In addition, the third power source generator 300A forms a pneumatic storage chamber and a pneumatic generation chamber in which a pneumatic charging device is independently formed as needed, without being connected to the first power source generator 100, and recycles the pneumatic pressure in the same manner as described above. Can produce power.

 As described in detail above, the portion of which power is used in the power generation apparatus according to the present invention is formed on one side of the buoyancy buoyancy chamber, the potential energy is formed in the second energy gate, the potential energy fluctuation chamber to communicate with the potential energy fluctuation chamber The first device, the second pressure control valve actuating and the door opening fixing device, which are formed at the top of the fluctuation device, the potential energy fluctuation chamber to communicate with the first buoyancy chamber, and the first buoyancy chamber formed at the top of the first buoyancy chamber, A buoyancy weight feeder for moving the dropping zone, a first buoyancy chamber feeder formed on the first buoyancy chamber to raise the first buoyancy chamber structure up, pneumatic charging device formed in the 1 to 3 power generator.

However, since the available power source is generated from the gravity energy of the first power source generator, the buoyant energy of the second power source generator and the pneumatic energy of the third power source generator, the required power energy source is smaller than the combined generated energy source power. Efficient power generation

 When the first buoyancy chamber and each pneumatic generating chamber of the first power source generator are raised, the power generation capacity is increased at a large rate and the power used is increased at a relatively small rate, thereby further increasing the power generation capacity.

  In addition, the first power source generator, the second power source generator, the third power source generator can be formed independently to generate power, and the pneumatic (energy) generated and used in one operation of the first power source generator is the second power source generator After the operation of the third power source generator, the air pressure is regenerated and used through the pneumatic generating chamber and the pneumatic storage chamber, and the power generation efficiency can be increased by repeatedly operating until the pneumatic pressure is exhausted.

As described above, although the present invention has been described by way of limited embodiments and drawings, the present invention is not limited thereto and is intended by those skilled in the art to which the present invention pertains. Various modifications and variations will be possible within the equivalent scope of the claims to be described.

1 is a configuration cross-sectional view showing a first embodiment of a first power source generator according to the present invention.

2 is a cross-sectional view of a second embodiment of a first power source generator according to the present invention;

3 to 8 are sectional views showing the operation sequence of the first power source generator according to the present invention.

9 is a pneumatic relation configuration diagram of the first to third power source generator according to the present invention.

10 is a cross-sectional view of a second power source generator in accordance with the present invention.

11 is a block diagram of a third power source generator according to the present invention.

12 is a first door configuration coupling diagram according to the present invention.

13 is a cross-sectional view of a second power source generator according to the present invention.

14 is a plan view of a second power source generator according to the present invention;

<Description of Signs for Main Parts of Drawings>

100: first power source generator 200: second power source generator

300: third power source generator 110: first pneumatic generating room

120: second pneumatic generating room 130: third pneumatic generating room

140: fourth pneumatic generating room 150: fifth pneumatic generating room

160: potential energy moving room 161: potential energy moving device

162: piston portion 163: vertical rod

165: lid 170: first buoyancy chamber

171: upper dropping band 173: vertical support frame

175: Buoyancy Room 176: Hinge Shaft

181: first gateway 182: second gateway

184: first pressure control valve 185: second pressure control valve

186: Jockey

210, 220: Pneumatic generating room 230: 2-1 Pneumatic storage room

310: 3-1 pneumatic storage chamber 320: pneumatic generating chamber

315, 325, 335: pneumatic control valve

Claims (43)

    A buoyancy chamber filled with buoyancy fluid therein; A buoyancy recommendation chamber formed under the buoyancy chamber; A buoyancy variable chamber formed below the buoyancy recommendation chamber; An elevating device formed below the buoyancy variable chamber to move up and down; A loading waiting room formed at one side of the buoyancy recommendation chamber; A buoyancy extraction door formed between the buoyancy recommendation chamber and the loading waiting room; An air valve formed at one side of the buoyancy recommendation chamber; A gate formed between the buoyancy chamber and the buoyancy recommendation chamber; A buoyancy chamber valve formed between the buoyancy chamber and the buoyancy recommendation chamber; A charge chamber valve formed between the buoyancy recommendation chamber and the buoyancy variable chamber; A water gate installed at an upper side of the buoyancy chamber; First and second rollers spaced apart from each other by a predetermined distance up and down on the buoyancy chamber; A chain installed between the first and second rollers; A conveyor belt connected between the water gate and the second roller; And The generator turbine connected to the first roller; Buoyancy generator characterized in that it comprises a. Located in the lower part, the position energy changing room including a plurality of pneumatic generating chambers, a plurality of pressure regulating valves, and a position energy changing device, and located in the upper part to charge the buoyancy fluid upward after loading the buoyancy weight to transfer the buoyancy weight upwards. Gravity energy using a first gate that is a boundary between a first buoyancy chamber, an upper portion of the potential energy chamber, and a lower portion of the first buoyancy chamber, a buoyant weight transfer device, a buoyancy chamber transfer device, and a drop device provided outside the first buoyancy chamber. A first power source generator for generating a; A second buoyancy chamber having a plurality of pneumatic storage chambers, a pneumatic filling device, a pneumatic extraction valve, a pneumatic inlet valve, a pneumatic control valve, a liquid filling device, and the inside of the second buoyancy chamber is a pneumatic generating chamber, twin gear and A second power source generator having a chain belt and a buoyancy pneumatic extraction valve to generate buoyancy energy using a plurality of buoyancy bodies utilizing pneumatic pressure; And a third power source generator for generating pneumatic energy, comprising a plurality of pneumatic generating chambers, pneumatic storage chambers, pneumatic inlet valves, pneumatic extraction valves and pneumatic charging devices, pneumatic control valves, and pneumatic motors. Pneumatic pressure generated in the first power source generator by interlocking the first to third power source generator by using the gravity energy generated during the buoyancy weight fall movement in the first power source generator device as a power source of an external power device; Generating device using buoyancy, gravity and pneumatic, characterized in that for generating the second and third power source by driving the second and third power source generator using energy.  The method of claim 2,  Apparatus using buoyancy, gravity and pneumatic, characterized in that the buoyancy attached to the inside of the first buoyancy chamber structure to form a buoyancy when the first door is opened. The method of claim 2, Inside the first buoyancy chamber to form an appropriate buoyancy body in the anti-gravity state so that the buoyancy chamber transfer device to transfer the first buoyancy chamber in the vertical direction with the minimum power to the buoyancy, gravity and pneumatic Used power generation device. The method of claim 2, The first power source generator, A space (air layer) is formed above the potential energy chamber, and a first buoyancy chamber is formed above the space (air layer) to open the liquid and the buoyancy chamber liquid in the potential energy chamber as necessary around the space (air layer). Power generation device using buoyancy, gravity and pneumatic, characterized in that the structure formed in three stages to control. The method of claim 2, It operates by interlocking a second power source generator and a third power source generator by pneumatic pressure generated by the operation of the first power source generator, and the first power source generator, the second power source generator, and the third power source generator as necessary. Generating device using buoyancy, gravity and pneumatic, characterized in that each can be operated separately. The method of claim 2, The second power source is a buoyancy and pneumatic, the third power source is a generator using buoyancy, gravity and pneumatic, characterized in that the pneumatic. The method of claim 5, The potential energy change room, A generator using buoyancy, gravity, and pneumatic pressure, characterized in that the structure is formed so that the level of the upper liquid filled by the vertical movement of the potential energy fluctuation device. The method of claim 2, The first door, A generator using buoyancy, gravity and pneumatic pressure, formed between the potential energy chamber and the first buoyancy chamber, and opening and controlling the liquid pressure of the potential energy chamber and the first buoyancy chamber. The method of claim 2, Many pressure control valves, The first buoyancy chamber, which is formed to interconnect and communicate with the first buoyancy chamber and the potential energy fluctuation chamber, is opened by controlling the pressure of the first buoyancy chamber and the potential energy fluctuation chamber to support the liquid weight and pressure of the first buoyancy chamber. A generator using buoyancy, gravity, and pneumatic pressure, characterized in that to easily open the first door formed in the lower portion. The method of claim 10 Buoyancy is characterized in that the first pressure control valve and the second pressure control valve and the jockey on the boundary to communicate the pressure and the joki is operated in conjunction with the second pressure control valve and the first door , Gravity and pneumatic generators. The method of claim 5, The potential energy variable device, Inflow or inflation of the liquid filled in the potential energy fluctuation chamber to adjust the level of the liquid level of the upper position energy fluctuation chamber liquid and the liquid level of the upper portion of the first buoyancy chamber liquid, and a plurality of inner diameters to be smaller inward in the upward or horizontal direction Cylindrical structure formed with a stage, buoyancy, gravity and pneumatic power generation apparatus characterized in that it comprises a piston in the inner center. The method of claim 11, Buoyancy, characterized in that the position energy fluctuating device has a plurality of vertical rods in the vertical direction to facilitate the opening and closing of the first door by pushing the buoyant weight in a linear motion toward the upper direction in the upper surface of the lid portion, Generator using gravity and pneumatics. The method according to any one of claims 2 to 13, And a first pneumatic generating chamber having a first pneumatic extraction valve and a first air inlet valve. The method according to any one of claims 2 to 13, And a second pneumatic generating chamber having a second pneumatic extraction valve and a second air inlet valve on an upper surface of the potential energy change chamber or a lower portion of the first gate. The method according to any one of claims 2 to 13, And a third pneumatic generating chamber having a third pneumatic extraction valve and a third air inlet valve beneath the potential energy fluctuating chamber. The method according to any one of claims 2 to 13, One side of the potential energy fluctuation chamber comprises a fourth pneumatic generating chamber having a fourth pneumatic extraction valve and a fourth air inlet valve, buoyancy, gravity and pneumatics. The method according to any one of claims 2 to 13, And a fifth pneumatic generation chamber having a fifth pneumatic extraction valve and a fifth air inlet valve on one side of the first buoyancy chamber. The method of claim 2, The buoyancy chamber transfer device, Installed in the upper part of the first buoyancy chamber, the door between the first buoyancy chamber and the potential energy chamber is opened, and after transporting only the first buoyancy chamber structure in the vertical direction at an appropriate distance, the door is closed and air is supplied to the potential energy chamber. When it flows in, the weight of the structure (mass) of the first buoyancy chamber and the weight of the liquid (mass) inside the first buoyancy chamber are combined (mass), and the first buoyancy chamber returns to the lower vertical direction in its original position. Generating device using buoyancy, gravity and pneumatic, characterized in that to generate a pneumatic by the movement of mass). The method of claim 2, Buoyant weight feeder, It is formed on the upper side of the first buoyancy chamber is formed with an induction rail in order to raise the buoyancy weight appropriately up and to transfer to an external automatic dropping device, after the first door is opened due to buoyancy A buoyancy, gravity, and pneumatic power generating device, characterized in that the buoyancy pneumatic is generated when rising in the upper vertical direction and is operated using the generated buoyancy pneumatic, the operation device using the pneumatic pressure is formed on one side. The method of claim 19, The automatic drop device, An apparatus using buoyancy, gravity, and pneumatic pressure, comprising a vertical support frame and an external dropper having a “b” shape for preparing to drop the buoyancy weights transported along the upper inclined surface of the first buoyancy chamber. The method of claim 2, It is formed on the upper side of the potential energy fluctuation chamber and has a buoyancy thrust room which is communicated by a second gate, and the lower support of the buoyancy thrust room has a rail further inclined inward, characterized in that the power generation using buoyancy, gravity and pneumatic Device. The method of claim 22, The second door is a pneumatic pressure using the surface pressure of the buoyancy weight and sensor, or the buoyancy weight (mass) of the buoyancy weight is transferred through the rail of the inclined support so that buoyancy addition flows into the potential energy chamber to be loaded buoyancy weight By means of opening and closing, one side of the power generation device using buoyancy, gravity and pneumatic, characterized in that the opening and closing device is formed using pneumatic. The method of claim 23, wherein The buoyancy, gravity and pneumatic power generation apparatus characterized in that the liquid filling device is further formed on one side of the buoyancy chamber. The method of claim 21, A generator turbine and a motor are formed at an upper portion of the upper dropping band vertical frame, and the generator turbine is connected to a string formed in the dropping band to generate power by using a buoyant natural fall motion, and the motor is moved downward. A generator using buoyancy, gravity, and pneumatic pressure to raise the base back to the upper portion. The method of claim 15, The second pneumatic extraction valve formed in the second pneumatic generation chamber, Pneumatic can be extracted, but liquid extraction and air inflow can be extracted, and the pneumatic generated in the second pneumatic generating chamber can be extracted and the extracted pneumatic can be used as energy to facilitate the increase of the liquid level in the potential energy chamber. Generating device using buoyancy, gravity and pneumatic, characterized in that. The method of claim 15, The second air inlet valve formed in the second pneumatic generation chamber, A power generation apparatus using buoyancy, gravity, and pneumatic pressure, characterized in that the air is introduced into the second pneumatic generating chamber to facilitate the liquid level of the potential energy fluctuation chamber while preventing pneumatic extraction and liquid extraction. The method of claim 14, The first pneumatic extraction valve, The power generation device using buoyancy, gravity and pneumatic, characterized in that to extract the pneumatics generated to facilitate the contraction of the potential energy changer and to use the extracted pneumatics as energy. The method of claim 14, The first air inlet valve, The generator using buoyancy, gravity and pneumatic, characterized in that the air flows into the first pneumatic generating chamber to facilitate the inlet or inflation of the potential energy fluctuation device. The method of claim 2, The second power source generator, It is connected to the pneumatic storage chamber which is operated by the pneumatic inlet of the first power source generator, the pneumatic charging device and the liquid filling device connected to the pneumatic storage chamber, a pneumatic extraction valve for extracting the pneumatic pressure in the pneumatic storage chamber, the pneumatic extraction valve A buoyancy pneumatic inlet valve formed on one side of the second buoyancy chamber for introducing the extraction pneumatics, a pneumatic generating chamber formed in the upper portion of the second buoyancy chamber, and a twin first gear and twin second gear provided inside the second buoyancy chamber. Is configured to include a chain or belt connected to the gear,  A plurality of buoyancy bodies connected to the chain or belt is further formed by a buoyancy pneumatic extraction valve for rotating the gear in the upward motion under the effect of pneumatic buoyancy, and put the pneumatic pressure in the buoyancy body, the liquid filling device on one side of the second buoyancy chamber Forming further, the generator using buoyancy, gravity and pneumatic, characterized in that for supplying an energy source to the external power unit connected to the twin first gear. The method of claim 30 The second power source generator, In addition to the pneumatic inflow of the first power source can be independently operated by the pneumatic charging of the pneumatic charging device which is connected to the pneumatic storage chamber and can be regenerated by pneumatic to re-use the pneumatic used for the buoyancy effect of the buoyancy body and A generator using buoyancy, gravity, and pneumatic, characterized in that configured to be repeatedly operated by recycling. The method of claim 30, The pneumatic generating room, Forming a space for generating air pressure above the upper portion of the second buoyancy chamber to generate air extracted from a plurality of buoyancy body again by pneumatic and to recycle the pneumatic to operate the power generator repeatedly Generator using buoyancy, gravity and pneumatics. The method of claim 30, The pneumatic storage chamber, Recycling the incoming pneumatic power as a power source, using the pneumatic charging device and pneumatic control valve formed on one side to properly maintain the pneumatic pressure as necessary, and further comprising a turbo motor, generating power using buoyancy, gravity and pneumatic Device. The method according to any one of claims 31 to 33. The pneumatic storage chamber, The liquid filling device formed on one side fills a proper amount of liquid inside and forms a plurality of pneumatic inlet valves in the lower portion of the liquid, and allows low pneumatic inflow to pass through the liquid so that it is relatively lower than the upper pneumatic storage chamber. Low-pneumatic power supply device is characterized in that the buoyancy, gravity and pneumatic pressure is introduced to generate a high air pressure above the liquid. The method of claim 30, The buoyancy pneumatic extraction valve, The buoyancy, gravity and pneumatic power generation apparatus, characterized in that the buoyancy pneumatic extracting device which is formed in the lower portion of the second buoyancy chamber to introduce the pneumatic to the buoyancy body at a suitable time and connected thereto. The method of claim 30, The buoyancy body, The left, right and upper parts are blocked and the lower part is opened so that the inlet air pressure can be trapped and have a buoyancy effect rising to the upper part.A buoyancy control valve is formed on the upper part to extract the pneumatic pressure when the buoyant body rises above the liquid. Buoyancy effect by maintaining the buoyancy effect and when the buoyancy body is rotated 180 degrees and lowered to the bottom of the liquid, the pneumatic pressure is extracted and the liquid can be introduced so that the buoyancy body is formed to facilitate the rise and fall buoyancy, gravity and Generator using pneumatic. The method of claim 34, The air pressure of the pneumatic generating chamber in the second buoyancy chamber is to increase the buoyancy effect of the second buoyancy chamber by applying pressure to the liquid in the second buoyancy chamber further power generation apparatus using a buoyancy, gravity and pneumatic. The method of claim 2, The third power source generator, In addition to the pneumatic inflow of the first power source can be operated independently by the pneumatic charging of the pneumatic charging device formed in the third power source generator and connected to the pneumatic storage chamber, used for the operation of the pneumatic motor and pneumatic turbine A power generation apparatus using buoyancy, gravity, and pneumatic pressure, characterized in that it is configured to be repeatedly operated by regenerating and recycling the pneumatic pressure to be utilized again. The method of claim 36, The pneumatic motor, pneumatic turbine and LPPM regulating gear box, The generator using buoyancy, gravity and pneumatic, characterized in that driven by pneumatic extracted from the pneumatic extraction valve formed on one side of the pneumatic storage chamber. The method of claim 2, The pneumatic generation chamber of the third power source generator, When the pneumatic used to operate the pneumatic motor or pneumatic turbine is discharged, the pneumatic generating chamber is introduced into the pneumatic generating chamber so as to be reproduced with the necessary pneumatic pressure for reuse, and the pneumatic charging unit is extracted to one side. And a pneumatic control valve is formed to maintain the pneumatic pressure as necessary, and further comprising a turbo motor, buoyancy, gravity and pneumatic generators. The method of claim 40,  The pneumatic generating room, The inside is filled with an appropriate amount of liquid, and a proper number of pneumatic inlet valves are formed at the bottom of the liquid, and low pneumatic inflow is made through the liquid so that low pneumatic pressure is lower than that of the upper pneumatic generating chamber. Generating device using buoyancy, gravity and pneumatic, characterized in that generated by pneumatic. The method of claim 38, The pneumatic storage chamber, It is a device that stores the supplied pneumatic pressure and uses the stored pneumatic pressure to drive the generator through the pneumatic extraction valve, and re-introduces the pneumatic used for driving the generator as needed to recycle it to another power source. A charging device and a pneumatic control valve are connected to form a power generation device using buoyancy, gravity and pneumatic, characterized in that to properly maintain the pneumatic pressure as necessary.  The method of claim 42, wherein  The pneumatic storage chamber,  A proper amount of liquid is filled inside and a pneumatic inlet valve is formed at the bottom of the liquid to allow pneumatic inflow to pass through the liquid so that low pneumatic pressure lower than that of the upper pneumatic storage chamber can be introduced into the liquid. Generating device using buoyancy, gravity and pneumatic, characterized in that generated by.

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