KR20090093068A - Gear apparatus and rotary drive apparatus activated by buoyant force - Google Patents

Abstract

A gear mechanism and a rotary driving apparatus operated by buoyancy are provided to lower production facilities cost because the pollution caused by the power generation is not generated at all. A gear mechanism operated by buoyancy comprises a container(100), a float feeding unit(200), a top gear unit, a bottom gear unit, a connection chain unit(800), a guide frame unit(810), a float operating unit, and a lifting float guide unit. The container stores the water(8000). The float feeding unit is formed in the lower part of the front surface(110) of the container. The top and bottom gear units are rotated by the buoyancy. The connection chain unit connects the top and bottom gear units. The guide frame unit is L-section steel for protecting the connection chain unit. The float operating unit is horizontally fixed to the connection chain unit.

Description

Gear device and rotary drive device activated by buoyant force

The present invention relates to a gear device and a rotation drive device driven by buoyancy.

The prior art of the present invention relates to a gear device and a rotation drive device.

The present invention seeks to provide a gear device operated by buoyancy.

In addition, the present invention seeks to provide a rotational drive operated by buoyancy.

In order to solve the above problems, the present invention is formed of a container member containing water 8000 therein, the container part 100, the container part front part 110 which is a front part of the outer side of the container part 100. Is formed in the lower portion of the buoyancy sphere supply portion 200, formed of a portion for supplying a buoyancy sphere (7000) that is a plurality of members that are subjected to buoyancy to rise up in the water 8000, a plurality of the buoyancy sphere 7000 is a gear member that is rotated by buoyancy to rise up in the water 8000, and is formed of two gear members on both left and right sides, and an upper gear part formed on an upper portion of the container part 100. 700, a plurality of the buoyancy sphere 7000 is a gear member to be rotated by the buoyancy to rise up in the water 8000, formed of two gear members on both the left and right sides, the container portion 100 Lower gear unit 600 formed in the lower portion of the), the upper Connection chain member 800 formed of two connection chain members on both left and right sides and a connection chain member 800 connecting the gear unit 700 and the lower gear unit 600 to protect the connection chain portion 800 on both the left and right sides. The guide frame portion is formed of an L-shaped steel member, which is formed of four L-shaped steel members installed in the vertical length direction of the container part 100 and installed at four corners around the connecting chain part 800 ( 810, a photoreceptor member which is horizontally fixed to the connection chain part 800 on both the left and right sides, and the photoreaction member is formed in a plurality of stages along the height direction of the connection chain part 800, and is formed to be convex upward. The basket member is formed to capture and contain a plurality of buoyancy spheres 7000, and transmits the buoyancy received by the buoyancy spheres 7000 to the connection chain part 800 to contain the plurality of buoyancy spheres 7000. Fixed The buoyancy sphere (buoyancy sphere action portion 900, the buoyancy sphere action portion 900, the container portion front part 110 side of the buoyancy sphere action portion 900, which allows the portion of the connection chain portion 800 to move upward). 7000 is a plurality of linear members that help to be well captured and contained, formed of a plurality of linear members along the height direction of the container portion 100 and the connecting chain portion 800, the container front portion 110 A side buoyancy sphere guide portion 500 is formed to the side and the connecting chain portion 800 side, the upper portion of the container portion 100 is formed of a vertical passage connecting the buoyancy sphere supply portion 200, the container portion front portion Buoyancy is formed in the 110, a plurality of buoyancy spheres 7000 floating above the water 8000 from the upper portion of the container portion 100 is formed as a passage that is introduced into the buoyancy sphere supply unit 200 to fall down In the buoyancy which comprises the old moving passage portion 300 To provide a gear device and the rotary drive is operated.

The present invention provides a gear device operated by buoyancy.

In addition, the present invention provides a gear device and a rotation drive device which are driven by buoyancy.

1 is a perspective view of a gear device and a rotation drive device driven by the buoyancy of the present invention.

Figure 2 is an exploded perspective view of a gear device operated by the buoyancy of the present invention.

3 is a cross-sectional view of the gear device actuated by the buoyancy of the present invention, taken in the B-B direction of FIG. 1.

4 is a cross-sectional view of the gear device actuated by the buoyancy of the present invention, which is a cross-sectional view taken along the direction A-A of FIG. 1, showing a state before the buoyancy sphere 7000 enters the container portion 100.

5 is a cross-sectional view of the gear device operated by the buoyancy of the present invention, which is a cross-sectional view taken from the direction AA in FIG. It is a cross-sectional view showing a state in which the buoyancy sphere supply unit 200 and the buoyancy sphere supply unit 200 moves the fixed connection chain portion 800 upward.

6 is a cross-sectional view of the gear device operated by the buoyancy of the present invention, which is a cross-sectional view taken along the direction A-A of FIG. 1, and is a cross-sectional view showing a state in which a plurality of buoyancy ball supply parts 200 may be installed.

FIG. 7A is a cross-sectional view of the buoyancy bulb supply unit 200, which is a component of the gear device operated by the buoyancy of the present invention, seen in the CC direction of FIG. 1, and a plurality of buoyancy spheres 7000 are provided through the buoyancy inlet opening 251. A cross-sectional view showing a state flowing into the buoyancy bulb supply unit 200.

7B is a cross-sectional view of the buoyancy bulb supply unit 200, which is a component of the gear device operated by the buoyancy of the present invention, in the CC direction of FIG. 1, wherein the water 8000 is connected to the buoyancy bulb supply unit through the water inlet and outlet opening 255. 200 is a cross-sectional view illustrating a state in which the plurality of buoyancy holes 7000 are discharged to the container part 100 through the buoyancy hole discharge opening 252.

7C is a cross-sectional view of the buoyancy bulb supply unit 200 which is a component of the gear device operated by the buoyancy of the present invention in the CC direction of FIG. 1, and a plurality of buoyancy spheres 7000 are provided through the buoyancy outlet outlet opening 252. Sectional view showing a state that all discharged to the container portion 100.

7D is a cross-sectional view of the buoyancy bulb supply unit 200 that is a component of the gear device operated by the buoyancy of the present invention in the CC direction of FIG. It is a cross-sectional view showing a state in which the plurality of buoyancy sphere 7000 is introduced into the buoyancy sphere supply unit 200 through the buoyancy sphere inlet opening 251.

<Explanation of symbols for the main parts of the drawings>

100: container portion 110: container portion front portion

120: container portion side portion 150: upper gear shaft through portion

160: lower gear shaft through portion 200: buoyancy ball supply portion

201: outer cylindrical portion outer peripheral portion 202: outer cylindrical portion side portion

207: operating rod through hole 210: outer cylindrical portion

211: upper opening inside the container 212: lower opening inside the container

215: vessel outer upper opening 216: vessel outer lower opening

217: buoyancy ball deviation network 250: the inner cylindrical portion

251: buoyancy opening inlet opening 252: buoyancy opening inlet

255: water access opening 257: operating rod

300: buoyancy sphere moving passage portion 500: rising buoyancy sphere induction portion

501: guide band horizontal support 600: lower gear

601: lower gear shaft 700: upper gear portion

701: upper gear shaft 800: connection chain portion

810: guide frame portion 900: buoyancy sphere action portion

1000: water supply part 2000: water drainage part

3000: drive connection part 5000: buoyancy bulb supply part operating part

7000: buoyancy sphere 8000: water

The present invention relates to a gear device and a rotation drive device driven by buoyancy.

The present invention, the container 100, the buoyancy sphere supply unit 200, the upper gear portion 700, the lower gear portion 600, the connection chain portion 800, the guide frame portion 810, buoyancy sphere action portion 900 ), The rising buoyancy sphere induction part 500, and the buoyancy sphere moving passage part 300, and may further include a drive connection portion 3000.

The present invention will be described in detail with reference to the accompanying drawings.

1 is a perspective view of a gear device operated by the buoyancy of the present invention.

Figure 2 is an exploded perspective view of a gear device operated by the buoyancy of the present invention.

3 is a cross-sectional view of the gear device actuated by the buoyancy of the present invention, taken in the B-B direction of FIG. 1. However, in FIG. 3, the portion of the buoyancy bulb supply unit 200 is not a cross section, but a front portion thereof is shown.

4 is a cross-sectional view of the gear device actuated by the buoyancy of the present invention, which is a cross-sectional view taken along the direction A-A of FIG. 1, showing a state before the buoyancy sphere 7000 enters the container portion 100.

5 is a cross-sectional view of the gear device operated by the buoyancy of the present invention, which is a cross-sectional view taken from the direction AA in FIG. It is a cross-sectional view showing a state in which the buoyancy sphere supply unit 200 and the buoyancy sphere supply unit 200 moves the fixed connection chain portion 800 upward.

6 is a cross-sectional view of the gear device operated by the buoyancy of the present invention, which is a cross-sectional view taken along the direction A-A of FIG. 1, and is a cross-sectional view showing a state in which a plurality of buoyancy ball supply parts 200 may be installed.

FIG. 7A is a cross-sectional view of the buoyancy bulb supply unit 200, which is a component of the gear device operated by the buoyancy of the present invention, in the CC direction of FIG. 1. A cross-sectional view showing a state flowing into the buoyancy bulb supply unit 200.

7B is a cross-sectional view of the buoyancy bulb supply unit 200, which is a component of the gear device operated by the buoyancy of the present invention, in the CC direction of FIG. 1. 200 is a cross-sectional view illustrating a state in which the plurality of buoyancy holes 7000 are discharged to the container part 100 through the buoyancy hole discharge opening 252.

7C is a cross-sectional view of the buoyancy bulb supply unit 200 which is a component of the gear device operated by the buoyancy of the present invention in the CC direction of FIG. 1, and a plurality of buoyancy spheres 7000 are provided through the buoyancy outlet outlet opening 252. Sectional view showing a state that all discharged to the container portion 100.

7D is a cross-sectional view of the buoyancy bulb supply unit 200 that is a component of the gear device operated by the buoyancy of the present invention in the CC direction of FIG. It is a cross-sectional view showing a state in which the plurality of buoyancy sphere 7000 is introduced into the buoyancy sphere supply unit 200 through the buoyancy sphere inlet opening 251.

As shown in Figures 1 and 2, the present invention is formed of a container member containing water 8000 therein, the container part 100, the container part front part which is a front part of the outside of the container part 100; It is formed in the lower portion of the 110, formed of a portion for supplying a buoyancy sphere 7000, which is a plurality of members that are subjected to buoyancy to rise up in the water 8000, buoyancy sphere supply unit 200, a plurality of The buoyancy sphere 7000 is a gear member to be rotated by the buoyancy to rise up in the water 8000, formed of two gear members on both the left and right sides, is formed on the upper portion of the container portion 100 The upper gear part 700, the plurality of buoyancy sphere 7000 is a gear member to be rotated by the buoyancy to rise up in the water 8000, formed of two gear members on both the left and right sides, the container Lower gear unit 600 formed on the lower portion of the portion 100, the upper end Connection chain member 800 formed of two connection chain members on both left and right sides and a connection chain member 800 connecting the gear unit 700 and the lower gear unit 600 to protect the connection chain portion 800 on both the left and right sides. The guide frame portion is formed of an L-shaped steel member, which is formed of four L-shaped steel members installed in the vertical length direction of the container part 100 and installed at four corners around the connecting chain part 800 ( 810, a photoreceptor member which is horizontally fixed to the connection chain part 800 on both the left and right sides, and the photoreaction member is formed in a plurality of stages along the height direction of the connection chain part 800, and is formed to be convex upward. The basket member is formed to capture and contain a plurality of buoyancy spheres 7000, and transmits the buoyancy received by the buoyancy spheres 7000 to the connection chain part 800 to contain the plurality of buoyancy spheres 7000. Fixed The buoyancy sphere to the buoyancy sphere action portion 900, the buoyancy sphere action portion 900, the container portion front portion 110 side, the buoyancy sphere (300) to move the portion of the pre-chain portion 800, the buoyancy sphere ( 7000 is a plurality of linear members that help to be well captured and contained, formed of a plurality of linear members along the height direction of the container portion 100 and the connecting chain portion 800, the container front portion 110 A side buoyancy sphere guide portion 500 is formed to the side and the connecting chain portion 800 side, the upper portion of the container portion 100 is formed of a vertical passage connecting the buoyancy sphere supply portion 200, the container portion front portion Buoyancy is formed in the 110, a plurality of buoyancy spheres 7000 floating above the water 8000 from the upper portion of the container portion 100 is formed as a passage that is introduced into the buoyancy sphere supply unit 200 to fall down And a sphere moving passage part 300.

The fluid contained in the container part 100 may be used other fluid than water 8000.

As shown in FIG. 2, the container part 100 is formed as a through hole penetrating the upper part of the container part side part 120, which is a side portion of both sides of the container part 100, of the upper gear part 700. An upper gear shaft through part 150, which is a through hole through which the upper gear shaft 701 is an axis, is formed of a through hole penetrating through a lower portion of the container side surface part 120, and a lower gear that is an axis of the lower gear part 600. The shaft 601 may be formed to include a lower gear shaft through portion 160, which is a through hole.

A separate bearing for supporting the upper gear shaft 701 and the lower gear shaft 601 may be formed.

The container part 100 may be formed of a metal material or reinforced concrete.

The upper gear shaft through part 150 and the lower gear shaft through part 160 may be tightly formed by an auxiliary member such as a packing so that water 8000 does not leak.

As shown in Figure 2, 3, 7a, 7b, 7c, 7d, the buoyancy sphere supply unit 200 is formed of an outer cylinder portion of the two cylindrical portions forming the buoyancy sphere supply unit 200, the outer The height direction of the cylindrical portion is laid horizontally in a direction horizontal to the ground to be fixed to the lower portion of the container portion front portion 110, half of the circular cross section of the outer cylindrical portion is located inside the container portion 100 Two cylinders forming the outer cylindrical portion 210, the buoyancy ball supply 200, which is the outer cylindrical portion, which is fixed so that the other half of the circular cross section of the outer cylindrical portion is located inside the container portion 100. It may be formed as an inner cylindrical portion inscribed in the outer cylindrical portion 210 of the portion, and may include an inner cylindrical portion 250 formed as a portion through which the water 8000 and the buoyancy hole 7000 pass. have.

The outer cylindrical portion 210 is an outer cylindrical portion outer peripheral portion 201, which is the outer circumferential surface portion of the outer cylindrical portion 210, the outer cylindrical portion side portion 202 which is a circular portion on both sides of the outer cylindrical portion outer peripheral portion 201 ) Is an elongated opening formed in the outer cylindrical part outer periphery 201 and is located inside the container part 100 but is located in the upper part of the outer cylindrical part outer periphery 201 and the upper part of the container inner upper opening 211, the outer cylinder. An elongated opening formed in the outer peripheral part 201 is located inside the container part 100, but is located in the lower part of the outer inner cylindrical part 201 in the lower part of the outer cylindrical part 201 and the outer cylindrical part 201. An elongated opening formed in the container, which is positioned outside the container part 100, but is formed in the container outer upper opening part 215 positioned on the outer cylindrical part outer peripheral part 201, and the outer cylindrical part outer peripheral part 201. An elongated opening Located outside the container portion 100 but located below the outer cylindrical portion outer periphery 201, including a buoyancy sphere deviation prevention net 217 that is a mesh member that protects the buoyancy sphere 7000 from falling out The outer outer opening 216 is formed in the outer cylindrical portion side portion 202 is formed of an elongated through hole formed along the arc direction, the inner cylindrical portion 250 by rotating the water 8000 and the buoyancy sphere 7000 may be formed to include an operating rod through hole 207 that is a through hole through which the operating rod 257 to operate to pass through the buoyancy bulb supply unit 200.

The inner cylindrical portion 250 is formed on the inner cylindrical portion outer peripheral portion that is the outer circumferential surface portion of the inner cylindrical portion 250, the inner cylindrical side surface portion which is a circular portion on both sides of the inner cylindrical outer peripheral portion, the inner cylindrical portion outer peripheral portion A buoyancy hole which is located outside the container part 100 as an elongated shape, and the buoyancy hole 7000 is formed as an opening which flows from the buoyancy sphere moving passage part 300 into the buoyancy sphere supply unit 200. An inlet opening 251, an elongated opening formed in the outer circumferential portion of the inner cylinder portion, is located inside the container part 100, and the buoyancy hole 7000 is the container part 100 from the buoyancy hole supplying part 200. The water 8000 enters and exits through a buoyancy opening 252 formed as an opening discharged into the elongated opening, and an elongated opening formed below the buoyancy opening inlet 251 and the buoyancy opening 252. Dog It may be formed by including a water inlet opening 255 formed by a bend.

When the plurality of buoyancy spheres 7000 that are subjected to buoyancy in the water 8000 rises while lifting up a plurality of buoyancy sphere action units 900 and floats on the surface, the buoyancy sphere moving passage part 300 Falling into the buoyancy sphere supply unit 200 is introduced.

An auxiliary device such as a push rod that pushes the plurality of buoyancy balls 7000 floating on the water to the side of the buoyancy ball moving passage part 300 may be used.

7A, 7B, 7C, and 7D, the buoyancy bulb supply unit 200 is operated while being rotated by 60 °, which is 1/6 of 360 ° in the clockwise or counterclockwise direction.

FIG. 7A illustrates a state in which the plurality of buoyancy balls 7000 are introduced into the buoyancy hole supply unit 200 through the buoyancy hole inlet opening 251, and FIG. 7B illustrates the water inlet opening 255. As the water 8000 flows into the buoyancy bulb supply unit 200, a plurality of the buoyancy spheres 7000 are discharged to the container unit 100 through the buoyancy sphere discharge opening 252. FIG. 7C illustrates a state in which the plurality of buoyancy ports 7000 are all discharged to the container part 100 through the buoyancy outlet outlet opening 252, and the water through the water inlet and outlet openings 255. As the 8000 is discharged outward, the plurality of the buoyancy spheres 7000 are introduced into the buoyancy sphere supply unit 200 through the buoyancy sphere inlet opening 251.

2, 3, 4, 5, and 6, the buoyancy sphere action portion 900 is formed of a mesh member may be formed to capture and contain a plurality of the buoyancy sphere (7000).

As the buoyancy sphere action portion 900 is inverted at the upper portion of the container portion 100, the plurality of buoyancy spheres 7000 floats on the surface of the water.

As the container portion 100 increases in height and increases in size, the buoyancy sphere action portion 900 may be installed in large numbers.

In the first operation, since the buoyancy sphere 7000 is not trapped in all of the plurality of buoyancy sphere acting portions 900, sufficient buoyancy force for moving the connection chain portion 800 is not applied. The connection chain part 800 is moved by using a separate driving device connected to the gear part 700 or the lower gear part 600.

As shown in Figure 2, 3, 4, 5, 6, the rising buoyancy sphere guide portion 500 is the lower end portion of the rising buoyancy sphere guide portion 500 of the container portion front portion 110 side the buoyancy sphere supply portion Being inclined toward the 200, the buoyancy sphere 7000 discharged from the buoyancy sphere supply unit 200 may be formed to help to be well captured and contained in the buoyancy sphere action unit 900.

As shown in FIG. 1, the gear device actuated by the buoyancy may include a water drainage part 2000 and a container part for draining the water 8000 discharged from the buoyancy ball supply part 200 to the outside. It may be formed by further comprising a water supply unit 1000 is formed to replenish the water 8000 to 100.

As shown in FIGS. 2, 3, 4, 5, and 6, the buoyancy-operated gear device is configured to allow the water 8000 and the buoyancy hole 7000 to pass through the buoyancy hole supply 200. It may be formed by further comprising a buoyancy ball supply unit operating portion 5000 is formed as an operation device portion for rotating or rotating the cylinder 250.

As shown in FIG. 1, the rising buoyancy sphere induction part 500 is formed of a metal material, and supports the induction part that is a plurality of horizontal band members that are coupled to the guide frame part 810 on the container part front part 110 side. It may be formed to be supported by the horizontal strip 501.

The buoyancy sphere 7000 is circular or oval, it may be formed of a styropole or lightweight synthetic resin.

As shown in FIG. 1, the present invention is a driving part connected to the upper gear shaft 701 that is the shaft of the upper gear part 700 or the lower gear shaft 601 that is the shaft of the lower gear part 600. And a driving connection part 3000.

The present invention is to insert a large amount of buoyancy sphere (ball) in a way that there is little resistance in the bottom of a large bucket (vessel) of several tens of meters (meter) in the principle of producing power with a huge buoyancy force in the method of storing or utilizing water Thus, power can be continuously produced indefinitely.

As a one-to-one exchange with water, the buoyancy sphere is inserted in the bottom of the bucket (container), so there is little waste of water and it is easy to adjust the speed or the magnitude of the force.

In particular, there is no pollution caused in the production of power, there is an advantage that the cost of the production facility is cheap and do not need to buy a large land separately.

Claims (12)

A container part 100 formed of a container member containing water 8000 therein; The buoyancy sphere 7000 is formed in the lower portion of the container portion front portion 110, which is a front portion outside the vessel portion 100, and receives a buoyancy force to rise up in the water 8000. A buoyancy sphere supply unit 200, which is formed as a portion to supply; A plurality of the buoyancy sphere 7000 is a gear member to be rotated by the buoyancy to rise up in the water 8000, formed of two gear members on both the left and right sides, the upper portion of the container portion 100 An upper gear part 700 formed; A plurality of the buoyancy sphere 7000 is a gear member to be rotated by the buoyancy to rise up in the water 8000, formed of two gear members on both the left and right sides, the lower portion of the container portion 100 A lower gear part 600 formed; A connection chain part 800 formed as two connection chain members on both left and right sides as a connection chain member connecting the upper gear part 700 and the lower gear part 600 to each other; It is formed of an L-shaped steel member that protects the connecting chain portion 800 on both the left and right sides, is installed in the vertical longitudinal direction of the container portion 100, 4 which is installed at four corners around the connecting chain portion 800 A guide frame portion 810 formed of two L-shaped steel members; It is a basket member fixed horizontally to the connecting chain portion 800 on both left and right sides, the basket member is formed in a plurality of stages along the height direction of the connection chain portion 800, is formed convex upwards a plurality of the It is formed to capture the buoyancy sphere 7000, and transmits the buoyancy received by the buoyancy sphere 7000 to the connection chain portion 800 is fixed to the basket member containing a plurality of the buoyancy sphere (7000) Buoyancy sphere action portion 900, which is the basket member, which allows the portion of the connection chain portion 800 to move up; A plurality of linear members that help the buoyancy sphere 7000 is well captured and contained in the buoyancy sphere action portion 900 of the container portion front portion 110 side, the vessel portion 100 and the connection chain portion A rising buoyancy induction part 500 formed of a plurality of linear members along a height direction of the 800 and formed toward the container front part 110 and the connection chain part 800; It is formed as a vertical passage connecting the upper portion of the container portion 100 and the buoyancy ball supply portion 200, is formed in the container portion front portion 110, the water 8000 in the upper portion of the container portion 100 A buoyant ball moving passage part 300 formed as a passage into which the plurality of floating buoyancy balls 7000 floated up and down into the buoyant ball supply part 200; Gear device operated by buoyancy comprising a. The method of claim 1, wherein the container portion 100 An upper gear, which is formed as a through hole penetrating the upper portion of the container side surface portion 120, which is a side portion of both sides of the container portion 100, is a through hole through which the upper gear shaft 701, which is an axis of the upper gear portion 700, passes. Shaft through part 150; A lower gear shaft through portion 160 formed as a through hole penetrating the lower portion of the container side surface portion 120 and passing through a lower gear shaft 601 which is an axis of the lower gear portion 600; Gear device is operated by buoyancy, characterized in that the container portion including a. According to claim 1, wherein the buoyancy ball supply unit 200 It is formed as an outer cylindrical portion of the two cylindrical portions forming the buoyancy sphere supply unit 200, the height direction of the outer cylindrical portion is laid horizontally in a direction horizontal to the ground lower portion of the container portion front portion 110 Fixed to the outer half of the circular cross section of the outer cylindrical portion is located inside the container portion 100 and the other half of the circular cross section of the outer cylindrical portion is fixed to be located inside the container portion 100, the outer An outer cylindrical portion 210, which is a cylindrical portion; Of the two cylindrical portions forming the buoyancy sphere supply unit 200 is formed as an inner cylindrical portion inscribed to the outer cylindrical portion 210, formed of a portion through which the water 8000 and the buoyancy sphere 7000 passes. An inner cylindrical portion 250; Gear device which is operated by buoyancy, characterized in that the buoyancy ball supply unit comprising a. The method of claim 3, wherein the outer cylindrical portion 210 An outer cylindrical portion outer circumferential portion 201 which is an outer circumferential surface portion of the outer cylindrical portion 210; An outer circumferential cylindrical side surface portion 202 which is a circular portion on both sides of the outer circumferential outer peripheral portion 201; An inner upper opening portion 211 positioned inside the container portion 100 as an elongated opening formed in the outer cylindrical portion outer periphery 201 and positioned above the outer cylindrical portion outer periphery 201; A lower inner opening 212 positioned inside the container 100 as an elongated opening formed in the outer cylindrical part 201 but positioned below the outer cylindrical part 201; A container outer upper opening portion 215 positioned at an outer side of the container portion 100 as an elongated opening formed in the outer cylindrical portion outer periphery portion 201 and positioned above the outer cylindrical portion outer periphery portion 201; The outer cylindrical portion is formed in the elongated opening formed in the outer circumferential portion 201 located outside the container portion 100, but located below the outer cylindrical portion circumferential portion 201, so that the buoyancy port 7000 does not escape out A container outer lower opening 216 formed to include a buoyancy ball deviation preventing net 217 that is a net member for protecting; The outer circumferential cylindrical portion side portion 202 is formed of an elongated through hole formed along an arc direction, and the water 8000 and the buoyancy sphere 7000 are rotated by rotating the inner cylindrical portion 250 to supply the buoyancy sphere supply unit 200. An operating rod through hole 207, which is a through hole through which the operating rod 257 actuates to pass through; Gear device which is operated by buoyancy, characterized in that the outer cylindrical portion including a. The method of claim 3, wherein the inner cylinder portion 250 An outer circumferential portion of the inner circumference of the inner circumferential surface portion of the inner cylindrical portion 250; An inner cylindrical part side part which is a circular part on both sides of the inner cylindrical part outer peripheral part; An elongated opening formed in the outer circumferential portion of the inner cylindrical part is located outside the container part 100, and the buoyancy hole 7000 flows into the buoyancy hole supplying part 200 from the buoyancy hole moving passage part 300. A buoyancy port inlet opening 251 formed as an opening; An elongated opening formed in an outer circumferential portion of the inner cylindrical part is located inside the container part 100, and the buoyancy hole 7000 is an opening discharged from the buoyancy hole supply part 200 into the container part 100. A buoyancy port outlet opening 252 formed; A water inlet opening 255 formed as an opening through which the water 8000 enters and exits an elongated opening formed below the buoyancy port inlet opening 251 and the buoyancy port outlet opening 252; Gear device which is operated by buoyancy, characterized in that the inner cylindrical portion comprising a. The method of claim 1, wherein the buoyancy sphere action portion 900 Is formed of a mesh member is formed to capture and contain a plurality of the buoyancy sphere (7000), A buoyancy acting gear device, characterized in that the buoyancy action. The method of claim 1, wherein the rising buoyancy sphere induction part 500 The lower end of the rising buoyancy ball induction part 500 on the container part front part 110 side is inclined toward the buoyancy ball supply part 200, so that the buoyancy ball 7000 discharged from the buoyancy ball supply part 200 is The buoyancy sphere is formed to help to be well captured by the action portion 900, A buoyancy-powered gear device, which is a rising buoyancy induction part. According to claim 1, wherein the gear device actuated by the buoyancy force A water drain part 2000 for draining the water 8000 discharged from the buoyancy ball supply part 200 to the outside; A water supply part 1000 formed to replenish the container part 100 with the water 8000; Gear device which is operated by buoyancy, characterized in that it further comprises. 4. The gear device of claim 3, wherein the gear device actuated by buoyancy is The buoyancy bulb supply unit operating portion 5000 is formed as an operating device for rotating or reverse rotation of the inner cylindrical portion 250 so that the water 8000 and the buoyancy sphere 7000 passes through the buoyancy bulb supply unit 200. ); Gear device which is operated by buoyancy, characterized in that it further comprises. The method of claim 1, wherein the rising buoyancy sphere induction part 500 It is made of metal Supported by the guide part supporting horizontal band 501 which is a plurality of horizontal band members engaging with the guide frame part 810 on the container part front part 110 side, A buoyancy-powered gear device, which is a rising buoyancy induction part. The method of claim 1, wherein the buoyancy sphere (7000) Round or oval, Formed of styropol or lightweight synthetic resin, A buoyancy-driven gear device, characterized in that the buoyancy sphere. A gear device operated by the buoyancy force according to any one of claims 1 to 11, A drive that is a drive portion connected to the upper gear shaft 701, which is the axis of the upper gear part 700, or the lower gear shaft 601, which is the axis of the lower gear part 600, according to any one of claims 1 to 11. Including a connection portion 3000, Rotary drive driven by buoyancy.