KR20100014045A - Buoyant engine - Google Patents

Abstract

PURPOSE: A buoyancy engine is provided to generate electricity by supplying air successively to buoyancy boxes so that the buoyancy boxes repetitively ascend and descend and a power transmission shaft rotates. CONSTITUTION: A buoyancy engine comprises a plurality of buoyancy range boxes(100), buoyancy boxes, two disks, a bottom support part, an air supply part, and a power transmission shaft. The buoyancy range boxes are filled with water and move up and down. The buoyancy boxes are inserted in the buoyancy range boxes and float on the water or sink under the water as air is injected or discharged. The disks horizontally moves under the buoyancy range boxes to keep the upper buoyancy range box from moving down. The bottom support part moves down with the power of one buoyancy range box moving down while the disks are opened, and raises another buoyancy range box and controls the horizontal movement of the disks. The air supply part is operated by the up and down motion of the buoyancy boxes to supply air into the buoyancy boxes. The power transmission shaft converts the up and down motion of the buoyancy range boxes to rotational motion and transmits it to outside.

Description

Buoyant engine

1 is a plan view showing a configuration in which the power transmission shaft is arranged between the buoyancy section box in the buoyancy engine according to an embodiment of the present invention

2: perspective view of buoyancy box

Figure 3: Cross section of the buoyancy box

4 is a plan view showing the configuration of a circular flat plate

5 is a cross-sectional view showing the configuration of the buoyancy section box, the circular flat plate and the lower support portion

6 is a cross-sectional view showing the configuration of the buoyancy section box, the plate and the lower support portion

Figure 7: Cross section of the air supply

8: Front view of the power transmission shaft

9 is a diagram briefly showing the configuration of the wire apparatus.

10 is a perspective view briefly showing the stopper.

The present invention relates to a device for generating rotational force, and more particularly, to a buoyancy engine capable of obtaining a continuous rotational force without using a combustion engine or the like.

The present invention devised to solve the above problems, the main object is to provide a buoyancy engine that can obtain a continuous rotational force without using fossil fuel or the like that causes environmental pollution.

The present invention is provided with a plurality and is filled with water to move up and down

Buoyancy section box is installed; Insert one by one into the buoyancy section box to form a cylindrical shape, the bellows of varying volume is laid so that air flows in or out. A buoyancy box configured to sit; A circular flat plate having two installed to move horizontally below the buoyancy section box to control the movement of the upper buoyancy section box downward; A lower support part which moves downward by the force of the buoyancy section box moving downward in the open state of the circular flat plate, thereby lifting another buoyancy section box upward and controlling horizontal movement of the circular flat plate; An air supply unit which is operated according to the vertical reciprocation of the buoyancy box to supply air to the buoyancy box; The buoyancy engine, characterized in that consisting of; a buoyancy engine, characterized in that consisting of;

Preferably, the buoyancy section box is characterized in that configured to interact with the buoyancy section box facing each other arranged in two rows.

Preferably, the buoyancy box is composed of a bellows, the central portion is to change the volume; and made of a metal material and is located on the upper side of the upper portion and the upper portion of the pipes in which air is introduced or discharged to the central portion; It is made of a metal material and is coupled to the lower side of the lower portion; characterized in that consisting of.

Preferably, the buoyancy box is the upper portion of the central portion is projected to the upper side and the engaging portion and the one end is attached to the lower end of the engaging portion is attached to the inner and outer protrusions on the side and the other end is coupled to the bottom of the center portion The spring is pulled up and down the center portion, and the coupling line in the spring is provided with a limiting line to restrict the upper movement of the upper portion of the upper portion by combining the lower portion and the central portion, the lower side of the upper through hole is formed inside the coupling portion The engaging portion is inserted into the center and the upper portion of the engaging portion and the inner end is located at the lower side of the protrusion of the engaging portion and the buoyancy box reaches the uppermost side when hitting the upper wall to move to the lower side Press the outer end is characterized in that it is provided with an operating portion for the projection to enter the inside It is done.

Preferably, the air supply unit is installed as many as the number of buoyancy section box.

Preferably, the air supply unit is composed of two cylinders and connected to the buoyancy box and a wire so that the pistons in both cylinders move up and down at the same time. One cylinder discharges air to the outside when the other cylinder descends. It is characterized in that it is configured to discharge air.

Preferably, the air supply unit, the air of one cylinder is to be supplied to the buoyancy box through a pipeline installed with a circular switchgear and the other cylinder is characterized in that it is configured to supply to the same buoyancy box through a pipeline without a switch.

Preferably, the lower support portion is connected to a hydraulic cylinder at its end to apply pressure to the hydraulic cylinder when the buoyancy section box is lowered, and accordingly a circular located below the other buoyancy section box adjacent to the buoyancy section box connected to the hydraulic cylinder. It characterized in that the flat plate is moved horizontally.

Preferably, the lower support portion, the support plate is to be lowered with the falling of the buoyancy section box and a plurality of through holes formed; A support rod formed in a long rod shape and coupled to the through hole of the support plate and descending together when the support plate descends, and having a gear formed on the surface thereof; An intermediate gear part coupled to a gear formed on a surface of the support bar to convert vertical motion of the support bar into a rotational force; Hagoimbong is moved up and down by receiving the rotational force transmitted through the intermediate gear portion from the other side buoyancy section box adjacent; A clutch positioned between two lower buoyancy section boxes and alternately moving downwards of both side buoyancy section boxes to move horizontally toward the buoyancy section box to be moved upward; It is installed on the clutch and characterized in that the clutch is configured to transfer the front and rear movement to the buoyancy section box to the upper gear coupling.

Preferably, the power transmission shaft is a flat gear having a cylindrical shape having a flat and open one side, the gear is formed on the inner peripheral surface and the shaft is formed in the center; A first gear installed to be in contact with the inner circumferential surface of the circular gear and rotating along the shanghai east of the buoyancy section box; A first auxiliary gear installed at a position symmetrical with the first gear about the axis of the circular gear and connected to the first gear and the belt to receive rotation of the first gear; It is installed spaced apart from the inner peripheral surface of the circular gear by a predetermined distance, and is installed symmetrically with the second gear around the axis of the circular gear and the second gear that rotates along the shanghai east of the buoyancy section box is connected to the second gear and the belt A second auxiliary gear to receive the rotation of the second gear; Composed between the second gear and the inner peripheral surface of the circular gear or between the second auxiliary gear and the circular gear is composed of a third gear to convert the rotation direction of the second gear and the second auxiliary gear reversely and to transmit the circular gear It is characterized by.

Hereinafter, a buoyancy engine according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

The buoyancy engine of the present invention can be largely divided into a buoyancy section box 100 and buoyancy box 200 and the circular flat plate 300, the lower support and the air supply and the power transmission shaft.

First, the buoyancy section box 100 will be described. The buoyancy section box 100 forms a hollow cylindrical shape and the upper side is open. The buoyancy section box 100 is filled with water. The buoyancy section box 100 is arranged while facing each other in two rows. Since the buoyancy section box 100 is filled with water there is a risk of freezing in the winter, so that the heating wire is provided to prevent the water from freezing.

Next, the buoyancy box 200 will be described. The buoyancy box 200 is located inside the buoyancy section box 100 to inflow or discharge air from the outside

have. Accordingly, when the air flows in, the central portion 230 expands and extends upward and downward to increase the spring 233. In addition, the coupling part 231 is also pushed upwards to prevent the protrusion 232 of the coupling part 231 from being caught by the locking part 211 of the upper end part 210 to prevent it from moving downward.

After the buoyancy box 200 is buoyancy occurs in accordance with the expansion of the volume is moved to the upper side the operating part 213 hits the upper wall and descends to the lower side accordingly the end of the operating unit 213 unwinding part Press the end of 212. Accordingly, the release part 212 pushes the protrusion 232 into the coupling part 231 by the action of the lever, and the coupling part 231 is released from the locking part 211. At this time, the central portion 230 is quickly folded by the action of the spring 233 and the air inside is discharged to the outside through the air outlet pipe 215.

Next, the circular flat plate 300 will be described. The circular flat plate 300 is positioned at the lower portion of the buoyancy section box 100 and is formed in a form in which semi-circular plates face each other. The circular flat plate 300 is provided with an operating part made of a combination of the hydraulic cylinder 302 and the gear 301 is configured to open and close the two semi-circular plate to operate the operating part. The operation part of the circular plate 300 is configured to be connected to the buoyancy section box 100 facing the buoyancy section box 100 of the upper side is closed when the buoyancy section box (100) facing down and the buoyancy section facing When the box 100 rises, the vertical movement of the buoyancy section box 100 of the upper side is controlled. Here, instead of using the circular flat plate, it is also possible to use a flat plate as shown in FIG.

Next, the lower support will be described. The lower support portion is installed on the lower side of the circular flat plate 300 and transfers the buoyancy section box 100 facing the buoyancy section box 100 facing the force of the buoyancy section box 100 coming down from the upper side to the upper side. Will be moved. To this end, the lower support portion in one embodiment of the present invention, when the buoyancy section box 100 is lowered together and forms a long rod shape with the support plate 401 formed with a plurality of through-holes of the support plate 401 It is coupled to the through-hole and descends together when the support plate 401 descends and is coupled to the support rod 402 and the gear formed on the surface of the support rod 402, the gear is formed on the surface to rotate the vertical movement of the support rod 402 to the rotational force Receives the rotational force transmitted through the intermediate gear portion 406 from the other side buoyancy section box 100 adjacent to the intermediate gear portion 406 to be converted to move up and down the lower bar 403 and two buoyancy section box 100 Located between the clutch and the clutch to move horizontally to the side of the buoyancy section box 100 to move to the lower side of the two side buoyancy section box 100 to move upwards and the lower It is composed of a high bar 405 to transfer the upper movement of the high bar 403 to the buoyancy section box 100 of the upper side.

Next, the upper support will be described. The upper support portion is a clutch 407 which is provided with an outer rope or a silence chain suspended from the upper side of the buoyancy section box to move in contact with one gear 408 back and forth; When one buoyancy section box is raised by the ratio of the remaining gear 408, the remaining buoyancy section box is configured to descend. Since the buoyancy engine of the present invention is configured to supply air by circulating the buoyancy box 200 sequentially, the air supply unit supplies air to the buoyancy box 200 installed in the adjacent buoyancy section box 100. To this end, the air supply unit has a cylinder. In the cylinder is installed a reciprocating piston and the piston is connected to the buoyancy box 200 with a wire. Accordingly, the piston reciprocates in the cylinder as the buoyancy box 200 moves up and down to discharge the air in the cylinder. In one embodiment of the present invention, one air supply unit includes two cylinders. The pistons are respectively inserted in the two cylinders, but the pistons are configured to move up and down at the same time. However, the cylinder is configured so that both sides are different from each other and one side has an inlet and an exhaust port at the bottom to discharge air when the piston descends, and to suck the air delivered from the other buoyancy box 200 through the inlet when the piston descends. The other side is provided with an intake port and an exhaust port at the top to discharge the air when the piston rises and is configured to suck the air when descending.

Here, the air discharged from the cylinder is not directly supplied to the buoyancy section box 100, but is configured to be supplied after being stored in a storage tank provided at one side. The storage tank has a rectangular parallelepiped or cylindrical shape, and a plate coupled to move up and down is installed therein, and a rod 505 is connected to a lower portion of the plate, so that the rod 505 also moves when the piston of the cylinder moves. Configured to move. In addition, upper and lower sides of the storage tank are formed with intake holes and exhaust holes through which air is introduced, thereby storing air discharged from each cylinder separately. The air collected here is discharged as the plate moves up and down and is delivered to the buoyancy box 200.

Next, the power transmission shaft will be described. The power transmission shaft is flat and has a cylindrical shape with one side open, and a gear is formed on an inner circumferential surface and is installed to contact a circular gear having an axis formed in the center and the inner circumferential surface of the circular gear, and is located in the shanghai-dong of the buoyancy section box 100. The first auxiliary gear and the circular shape are installed in a position symmetrical with the first gear around the axis of the first gear and the circular gear to rotate along the first gear is connected to the belt and the first gear to receive the rotation of the first gear It is installed at a predetermined distance from the inner peripheral surface of the gear and is symmetrically installed with the second gear around the axis of the circular gear and the second gear which rotates along the shanghai east of the buoyancy section box 100 and is connected with the second gear and the belt. And the second auxiliary gear and the second gear and the circular gear inner circumferential surface to receive the rotation of the second gear or coupled between the second auxiliary gear and the circular gear It consists of a third gear that is transmitted to the circular gear by converting the rotational direction of the second gear and the second auxiliary gear reversely. In one embodiment of the present invention receives the fluid through a cylinder that is directly connected to the support rod 402 to apply this to the working cylinder to move the piston of the working cylinder up and down and to form a rack gear on the side of the piston And connect the first gear and the second gear to the rack gear, respectively. At this time, since the buoyancy section box 100 connected to the first gear and the buoyancy section box 100 connected to the second gear are configured to move in opposite directions, the piston of the operation cylinder may operate the first gear or the second gear. The piston of the other working cylinder should be separated from the first or second gear. To this end, in an embodiment of the present invention, when the piston is raised by laying the sprocket on the side of the piston, the sprocket is placed on the rotary gear so that power is transmitted only when the piston is vertically lowered from the first gear or the second gear. . Accordingly, the rotation is transmitted to the outside by the shaft formed in the center of the circular gear. The end of the shaft is provided with a generator to produce electricity by using the rotational force to be sent out.

Hereinafter, with reference to the accompanying drawings will be described the operation of the buoyancy engine according to an embodiment of the present invention.

Water is filled in the buoyancy section box 100 and the buoyancy box 200 is inserted therein. At this time, the upper end 210 of the buoyancy box 200 is connected to the inlet and outlet the air is introduced. The side of the buoyancy box 200 in the buoyancy section box 100 is placed in the wire device shown in FIG. The wire device according to the vertical movement of the buoyancy box 200 'c' child member 113 is caught in the buoyancy section box 100 so that the wire 114 is rotated and the rotation is transferred to the belt 115 to air Configured to actuate the piston 502 of the supply. In addition, the stopper shown in Figure is installed inside the buoyancy section box 100. The stop device is configured to stop the buoyancy box 200 is coupled to the groove formed in the lower 'U' member member 111 of the lower side of the buoyancy box 200. When the buoyancy box 200 is expanded, the stop device moves the upper end portion 210 of the buoyancy box 200 upwards, and accordingly, the projection of the operation member 112 attached to one side of the stop device is the buoyancy box ( The upper end 210 of the 200 is caught together to move upwards. Accordingly, the stopper device consisting of a plurality of gears is operated to release the buoyancy box 200 held by the 'U' member member 111 moving to the rear side so that the buoyancy box 200 can rise to the upper side.

In order to operate the buoyancy engine configured as described above, air is introduced into the buoyancy box 200 in the first buoyancy section box 100. Accordingly, when the buoyancy box 200 is expanded and the volume is increased, the 'U' member of the stop device reverses and releases the buoyancy box 200 to rise quickly. When it is raised as described above, the wire device is operated upward, and accordingly, the air supply unit for supplying air to the buoyancy box 200 in the buoyancy section box 100 is operated. As the piston of the air supply unit moves upward, the air inside the cylinder 501 is supplied to the upper side of the air tank 503, and the air above the air tank 503 is moved by the movement of the plate 504. It is then supplied to the buoyancy box 200. At this time, the rotary switch 201 is installed in the pipeline for supplying air to the buoyancy box 200 to block the flow of air.

In addition, the operation of the buoyancy box 200 is to operate the circular flat plate 300 in the lower portion of the buoyancy section box 100 by a wire. When the circular flat plate 300 is opened, the buoyancy section box 100 moves downward, and the buoyancy section box 100 moves downward by pressing the support plate 401 and the support bar 402. Accordingly, the hydraulic cylinder located on the lower side of the support plate is operated, and the circular flat plate 300 below the buoyancy section box 100 facing the fluid pressurized by the hydraulic cylinder starts to close. To this end, in the present invention, a flat plate gear is installed on the circular flat plate 300 and the flat plate gear is connected to the gear formed at the end of the piston rod 505 of the hydraulic cylinder on the flat plate side so that the circular flat plate 300 can be opened and closed. Will be configured. In addition, a gear is formed at the end of the support rod 402 to push up the high bar 403 located in the lower portion of the buoyancy section box 100 facing each other by the combination of the gears. In this case, since the high tension bar 403 is short in length and does not directly contact the buoyancy section box 100, the clutch is installed horizontally moving both sides of the lower buoyancy section box 100. The high rent is formed with a plurality of through holes and the high bar 405 is coupled to the through holes. The high rod 405 is configured so that the middle of the rod protrudes outward and does not fall to the bottom of the through hole. The high lease is moved to the lower side of the buoyancy section box 100 to be raised and accordingly the high tension bar 403 coming up from the bottom to push up the high tension bar 405 accordingly the high tension bar 405 buoyancy section box ( 100) will be lifted upwards.

When configured as described above, the air is sequentially supplied between the buoyancy box 200 to repeat the rise and fall and the circular flat plate 300 is opened and closed in accordance with the movement of the buoyancy box 200 to the buoyancy section box 100 Exercise up and down. As the buoyancy section box 100 moves up and down, the power transmission shaft connected to the buoyancy section box 100 rotates to generate power.

As described above, according to the buoyancy engine of the present invention, it is possible to obtain a continuous rotational force without generating pollutants, thereby preventing environmental pollution, and having a function as a new alternative energy by replacing the exhausted fossil fuel.

Claims (1)

A buoyancy section box provided with a plurality and filled with water and installed to move up and down; Insert one by one into the buoyancy section box to form a cylindrical shape, the bellows of varying volume is laid so that air flows in or out. A buoyancy box configured to sit; A circular flat plate having two installed to move horizontally below the buoyancy section box to control the movement of the upper buoyancy section box downward; A lower support part which moves downward by the force of the buoyancy section box moving downward in the open state of the circular flat plate, thereby lifting another buoyancy section box upward and controlling horizontal movement of the circular flat plate; An air supply unit which is operated according to the vertical reciprocation of the buoyancy box to supply air to the buoyancy box; A buoyancy engine comprising: a power transmission shaft for converting the up and down movement of the buoyancy section box into a rotational movement and transmitting it to the outside.

Images