CN113309655A - Floating power generation system utilizing ocean wave energy - Google Patents

Abstract

The invention discloses a floating power generation system utilizing ocean wave energy, and relates to the technical field of wave energy power generation. According to the invention, by arranging the first power generation mechanism and the second power generation mechanism, when the waves are huge, the force of upward movement of the first rack by the floating mechanism is large enough, the vertical movement fall of the first rack is large, the first rack moves to enable the first gear to rotate to enable the first power generation mechanism to generate power, meanwhile, the control plate at the bottom end of the first rack moves upward to enable the idle stroke ring to move upward, and the second power generation mechanism also generates power, so that the energy utilization rate of the huge waves is increased.

Description

Floating power generation system utilizing ocean wave energy

Technical Field

The invention relates to the technical field of wave energy power generation, in particular to a floating power generation system utilizing ocean wave energy.

Background

Wave energy is one of the most abundant energy sources in ocean energy and is the ocean energy source which is most researched recently in ocean energy utilization research, the development and utilization technology of the wave energy tends to be mature and is entering or approaching the commercial development stage, and the wave energy utilization has very important significance for the development of ocean resources in coastal areas and the development far away from continental islands.

In the prior art, a floating power generation system using ocean wave energy drives a floating member to move up and down by means of the energy of the ocean wave to enable a related component to generate power, but the power generation device can utilize a small amount of wave energy and has low energy utilization rate for huge waves, so that the floating power generation system using the ocean wave energy is disclosed.

Disclosure of Invention

The invention aims to provide a floating power generation system utilizing ocean wave energy, which solves the problem of low energy utilization rate of some huge waves of power generation devices proposed in the background art, the invention arranges a free-wheeling ring on a cutting plate on a second power generation mechanism, so that when the waves are small, the moving fall of a first rack along with the floating mechanism is small, a control plate at the bottom end of the first rack moves in the inner cavity of the free-wheeling ring and can not move the free-wheeling ring, only a first power generation mechanism generates power at the moment, when the waves are huge, the upward moving force of the first rack by the floating mechanism is large enough, the moving fall of the first rack is large, the first rack moves to rotate a first gear to enable the first power generation mechanism to generate power, and simultaneously, the control plate at the bottom end of the first rack moves upwards to enable the free-wheeling ring to move upwards, and then the second power generation mechanism also generates power, thereby making the energy efficiency of the large waves high.

In order to achieve the above purpose, the present application provides the following technical solutions: a floating power generation system utilizing ocean wave energy comprises a floating air bag, wherein a core control box is installed at the bottom end of the floating air bag, connecting rods are installed on four sides of the core control box, a power generation box is installed at one end, far away from the core control box, of the four connecting rods, a first power generation mechanism is installed on the inner side of the power generation box, an installation block is installed on the inner side of the power generation box, a first gear is installed on the installation block in a rotating mode and is connected with the first power generation mechanism through a transmission mechanism, a first rack is movably installed on one side of the first gear and is meshed with the first gear, a floating mechanism enabling the first rack to move is installed at the top end of the first gear, a control plate is installed at one end, close to the installation block, of the bottom end of the first rack, and a free-stroke ring is movably sleeved on the control plate, the bottom of idle stroke ring is installed and is cut the board, the adaptation is installed to the bottom of idle stroke ring the second power generation mechanism of cutting the board.

Based on the structure, the idle stroke ring is arranged on the cutting plate on the second power generation mechanism, so that when waves are small, the fall of the first rack moving along with the floating mechanism is small, the control plate at the bottom end of the first rack moves in the inner cavity of the idle stroke ring and cannot move the idle stroke ring, only the first power generation mechanism generates power at the moment, when the waves are huge, the force of the first rack moving upwards by the floating mechanism is large enough, the fall of the first rack moving is large, the first rack moves to enable the first gear to rotate to enable the first power generation mechanism to generate power, meanwhile, the control plate at the bottom end of the first rack moves upwards to enable the idle stroke ring to move upwards, the second power generation mechanism also generates power at the moment, and therefore the energy utilization rate of the huge waves is increased.

Preferably, first generating mechanism includes the mounting box, the mounting box is installed power generation box inner chamber top, two opposite magnetic pole pieces are installed to the inner chamber both sides of mounting box, rotate between two magnetic pole pieces and install the cutting frame.

Further, through the installation of the magnetic pole piece in the inner chamber both sides of mounting box to the rotation sets up the cutting frame, makes the cutting frame rotate, cuts magnetic induction line, generates electricity.

Preferably, drive mechanism includes the ring gear, the ring gear rotates and installs on the mounting box, ring gear inboard rotate install with cutting frame coaxial coupling's second gear, the one-way limiting mechanism who makes the one-way pivoted of second gear is installed to the ring gear inboard, the ring gear with the cover is equipped with the hold-in range on the first gear, the installation piece is kept away from reset mechanism is installed to the one end of hold-in range.

Further, through setting up the second gear coaxial with the cutting frame, when making first gear revolve, the second gear revolve, makes the cutting frame rotate.

Preferably, the one-way limiting mechanism comprises a plurality of supporting blocks, the supporting blocks are uniformly installed in the inner cavity of the gear ring, movable gear teeth are rotatably installed on the supporting blocks, and first springs are installed between the movable gear teeth and the gear ring.

Furthermore, the plurality of movable gear teeth are movably arranged in the inner cavity of the gear ring, so that the second gear can only rotate when the gear ring rotates clockwise.

Preferably, the reset mechanism comprises a slide rail, a second rack is slidably mounted in the slide rail, the second rack is meshed with the first gear, and an elastic mechanism is mounted on one side of the second rack.

Further, through sliding in the slide rail and setting up the second rack, make first gear revolve, the second rack also removes, and when the wave passed, the second rack made first gear reset.

Preferably, the elastic mechanism comprises a second spring, one end of the second spring is connected with the second rack, and the other end of the second spring is connected with the power generation box.

Furthermore, a second spring is arranged at one end of the second rack, so that the second spring is stretched when the second rack moves, and power is provided for resetting of the second rack.

Preferably, the second power generation mechanism comprises an installation frame, the inner side of the installation frame is located at two ends of the cutting plate, and the bottom end of the installation block is provided with a buffer mechanism.

Furthermore, the power generation components are arranged at the two ends of the inner side of the mounting frame, so that the power generation components generate power when the cutting plate moves up and down.

Preferably, the buffer mechanism comprises a plurality of third springs, the plurality of third springs are mounted at the bottom end of the mounting block, and a buffer plate is mounted at the bottom end of the plurality of third springs.

Further, by providing a plurality of third springs at the top end of the buffer plate, a buffering force is applied after the idle stroke ring is moved upward.

Preferably, the floatation mechanism comprises a rubber air bag filled with gas.

Further, a rubber air bag filled with gas is arranged at the top end of the first rack, so that when waves come, the rubber air bag moves upwards, and the first rack moves upwards.

Preferably, the installation piece in one side of first rack installs a plurality of pivots, and is a plurality of all rotate the cover in the pivot and be equipped with the gyro wheel.

Furthermore, through installing a plurality of pivots on the installation piece to all set up the gyro wheel in the pivot, when making first rack activity, frictional force diminishes.

In conclusion, the technical effects and advantages of the invention are as follows:

1. according to the invention, the idle stroke ring is arranged on the cutting plate on the second power generation mechanism, so that when waves are small, the upward moving force of the first rack along with the floating mechanism is small, the fall is small, at the moment, the control plate at the bottom end of the first rack moves in the cavity of the idle stroke ring and cannot move the idle stroke ring, at the moment, only the first power generation mechanism generates power, when the waves are huge, the upward moving force of the first rack by the floating mechanism is large enough, the upward moving fall of the first rack is large, at the moment, the first rack moves to enable the first gear to rotate to enable the first power generation mechanism to generate power, at the same time, the control plate at the bottom end of the first rack moves upward to enable the idle stroke ring to move upward, at the moment, the second power generation mechanism also generates power, and the energy utilization rate of the huge waves is increased.

2. In the invention, the second spring is arranged at one end of the second rack, so that the second spring is stretched when the second rack moves, and power is provided for the resetting of the second rack.

3. According to the invention, the plurality of movable gear teeth are movably arranged in the inner cavity of the gear ring, so that the second gear can rotate only when the gear ring rotates clockwise, and the cutting frame cannot rotate reversely when the first gear is reset.

4. In the invention, the plurality of third springs are arranged at the top end of the buffer plate, so that after the idle stroke ring moves upwards, a buffering force is provided, and related components cannot be damaged.

5. According to the invention, the installation blocks are provided with the plurality of rotating shafts, and the rollers are arranged on the rotating shafts, so that the friction force is reduced when the first rack moves.

Drawings

In order to more clearly illustrate the embodiments of the present application or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present application, and other drawings can be obtained by those skilled in the art without creative efforts.

FIG. 1 is a perspective view of a floating power generation system using ocean wave energy according to an embodiment;

FIG. 2 is a schematic view of the inside structure of the power generation box in the present embodiment;

FIG. 3 is a schematic structural view of the reset mechanism in the present embodiment;

FIG. 4 is a schematic structural view of the second rack of the present embodiment;

FIG. 5 is a schematic structural view of the mounting block in the present embodiment;

FIG. 6 is a schematic structural view of the inner side of the gear ring in the present embodiment;

fig. 7 is a schematic structural view at the second power generation mechanism in the present embodiment;

fig. 8 is a schematic structural view of an inner cavity of the mounting box in this embodiment.

In the figure: 1. a floating airbag; 2. a first rack; 3. a rubber air bag; 4. a power generation box; 5. a core control box; 6. a connecting rod; 7. mounting a box; 8. a ring gear; 9. a synchronous belt; 10. a first gear; 11. mounting blocks; 12. a control panel; 13. cutting the frame; 14. a rotating shaft; 15. a second gear; 16. a first spring; 17. a support block; 18. movable gear teeth; 19. a power generation member; 20. cutting the board; 21. installing a frame; 22. a lost motion ring; 23. a second rack; 24. a second spring; 25. a slide rail; 26. a buffer plate; 27. a third spring; 28. a roller; 29. a magnetic pole block.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Example (b): referring to fig. 1 to 8, there is shown a floating power generation system using ocean wave energy, comprising a floating airbag 1, a core control box 5 being installed at the bottom end of the floating airbag 1, the floating airbag 1 being any one of the prior art.

Connecting rods 6 are all installed on four sides of the core control box 5, the power generation box 4 is all installed at one end, far away from the core control box 5, of the four connecting rods 6, the power generation box 4 is all arranged on four sides of the core control box 5 through the four connecting rods 6, and power generation efficiency is high.

The inner side of the power generation box 4 is provided with a first power generation mechanism, the inner side of the power generation box 4 is provided with an installation block 11, the installation block 11 is rotatably provided with a first gear 10, the first gear 10 is connected with the first power generation mechanism through a transmission mechanism, one side of the first gear 10 is movably provided with a first rack 2, the first rack 2 is meshed with the first gear 10, the top end of the first gear 10 is provided with a floating mechanism which enables the first rack 2 to move, one end of the bottom end of the first rack 2, which is close to the installation block 11, is provided with a control plate 12, the control plate 12 is movably sleeved with a free stroke ring 22, the bottom end of the free stroke ring 22 is provided with a cutting plate 20, the bottom end of the free stroke ring 22 is provided with a second power generation mechanism which is matched with the cutting plate 20, the first gear 10 is arranged on one side of the first rack 2 and is connected with the first power generation mechanism through the transmission mechanism, when the top end floating mechanism of the first rack 2 is jacked up by waves, first rack 2 upward movement, first gear 10 rotated this moment, made first power generation mechanism generate electricity, when meetting huge wave, first rack 2 was by the floating mechanism completely, quick pull-up, and the inner chamber top of first rack 2 bottom control panel 12 motion to idle stroke ring 22 this moment pulls up cutting board 20, cuts the magnetic induction line in second power generation mechanism this moment, and second power generation mechanism generates electricity.

Based on the structure, the idle stroke ring 22 is arranged on the cutting plate 20 on the second power generation mechanism, so that when waves are small, the upward moving force of the first rack 2 along with the floating mechanism is small, the fall is small, at the moment, the control plate 12 at the bottom end of the first rack 2 moves in the inner cavity of the idle stroke ring 22 and cannot enable the idle stroke ring 22 to move, at the moment, only the first power generation mechanism generates power, when the waves are huge, the upward moving force of the first rack 2 on the floating mechanism is large enough, the upward moving fall of the first rack 2 is large, at the moment, the first rack 2 moves to enable the first gear 10 to rotate to enable the first power generation mechanism to generate power, at the same time, the control plate 12 at the bottom end of the first rack 2 moves upwards to enable the idle stroke ring 22 to move upwards, at the second power generation mechanism also generates power, and accordingly the energy utilization rate of the huge waves is increased.

In this embodiment, as shown in fig. 8, the first power generation mechanism includes the mounting box 7, and the mounting box 7 is installed on the top of the inner chamber of the power generation box 4, and two opposite magnetic pole blocks 29 are installed on two sides of the inner chamber of the mounting box 7, and the cutting frame 13 is installed between the two magnetic pole blocks 29 in a rotating manner, and through installing the magnetic pole blocks 29 on two sides of the inner chamber of the mounting box 7 and rotating the cutting frame 13, the cutting frame 13 is rotated to cut the magnetic induction lines, and power generation is performed.

In this embodiment, as shown in fig. 5, the transmission mechanism includes a gear ring 8, the gear ring 8 is rotatably installed on the installation box 7, a second gear 15 which is coaxially connected with the cutting frame 13 is rotatably installed on the inner side of the gear ring 8, a one-way limiting mechanism which enables the second gear 15 to rotate in one-way is installed on the inner side of the gear ring 8, the synchronous belt 9 is sleeved on the gear ring 8 and the first gear 10, a reset mechanism is installed at one end, away from the synchronous belt 9, of the installation block 11, the reset mechanism is installed through the second gear 15 which is coaxial with the cutting frame 13, when the first gear 10 is rotated, the second gear 15 rotates, and the cutting frame 13 is rotated.

In this embodiment, as shown in fig. 6, the one-way limiting mechanism includes a plurality of supporting blocks 17, the supporting blocks 17 are uniformly installed in the inner cavity of the gear ring 8, the supporting blocks 17 are all rotatably installed with movable gear teeth 18, a first spring 16 is installed between each movable gear tooth 18 and the gear ring 8, and the plurality of movable gear teeth 18 are movably arranged in the inner cavity of the gear ring 8, so that the gear ring 8 can rotate the second gear 15 only when rotating clockwise.

In this embodiment, as shown in fig. 3, the reset mechanism includes a slide rail 25, a second rack 23 is slidably mounted in the slide rail 25, the second rack 23 is engaged with the first gear 10, an elastic mechanism is mounted on one side of the second rack 23, the second rack 23 is slidably disposed in the slide rail 25, so that when the first gear 10 rotates, the second rack 23 also moves, and when a wave passes, the second rack 23 resets the first gear 10.

In this embodiment, as shown in fig. 4, the elastic mechanism includes a second spring 24, one end of the second spring 24 is connected to the second rack 23, and the other end is connected to the power generation box 4, and when the second rack 23 moves, the second spring 24 is stretched by the second spring 24 arranged at one end of the second rack 23, so as to provide power for the second rack 23 to return.

In this embodiment, as shown in fig. 7, the second power generation mechanism includes a mounting frame 21, the power generation members 19 are mounted on both ends of the cutting board 20 inside the mounting frame 21, the buffer mechanism is mounted on the bottom end of the mounting block 11, and the power generation members 19 are provided on both ends of the mounting frame 21 inside, so that the power generation members 19 generate power when the cutting board 20 moves up and down.

In this embodiment, as shown in fig. 6, the buffer mechanism includes a plurality of third springs 27, the plurality of third springs 27 are mounted at the bottom end of the mounting block 11, the buffer plate 26 is mounted at the bottom end of the plurality of third springs 27, and the idle ring 22 is moved upward by the plurality of third springs 27, so that a buffering force is generated.

In this embodiment, as shown in fig. 5, the floating mechanism includes a rubber air bag 3, the rubber air bag 3 is filled with gas, and the rubber air bag 3 filled with gas is provided at the tip of the first rack 2, so that the first rack 2 is moved upward by the upward movement of the rubber air bag 3 when the waves come.

In this embodiment, as shown in fig. 5, the mounting block 11 has a plurality of rotating shafts 14 mounted on one side of the first rack 2, the plurality of rotating shafts 14 are rotatably sleeved with rollers 28, and the plurality of rotating shafts 14 are mounted on the mounting block 11, and the rollers 28 are disposed on the rotating shafts 14, so that the friction force is reduced when the first rack 2 moves.

The working principle of the invention is as follows: through setting up idle stroke ring 22 on cutting board 20 on the second power generation mechanism, make the wave less, first rack 2 is less along with the power that floats mechanism rebound, the drop is little, control panel 12 of first rack 2 bottom moves in idle stroke ring 22 inner chamber this moment, can not make idle stroke ring 22 move, only first power generation mechanism electricity generation this moment, when the wave is huge, first rack 2 receives the power of floating mechanism rebound enough big and first rack 2 reciprocates the drop big this moment, first rack 2 activity makes first gear 10 rotate and makes first power generation mechanism electricity generation this moment, control panel 12 of first rack 2 bottom moves upward simultaneously, make idle stroke ring 22 rebound this moment, second power generation mechanism also generates electricity this moment, thereby make the energy utilization rate of huge wave uprise grow.

The magnetic pole blocks 29 are arranged on two sides of the inner cavity of the mounting box 7, the cutting frame 13 is arranged in a rotating mode, the cutting frame 13 is made to rotate, magnetic induction lines are cut, power generation is carried out, when the first gear 10 is made to rotate by arranging the second gear 15 which is coaxial with the cutting frame 13, the second gear 15 is made to rotate, the cutting frame 13 is made to rotate, the plurality of movable gear teeth 18 are movably arranged in the inner cavity of the gear ring 8, the second gear 15 can be made to rotate only when the gear ring 8 rotates clockwise, the second rack 23 is arranged in the sliding rail 25 in a sliding mode, when the first gear 10 rotates, the second rack 23 also moves, when waves pass, the second rack 23 enables the first gear 10 to reset, when one end of the second rack 23 is provided with the second spring 24, when the second rack 23 moves, the second spring 24 is stretched to provide power for resetting the second rack 23, and the power generation components 19 are arranged at two ends of the inner side of the mounting box 21, when the cutter plate 20 is moved up and down, the power generating member 19 generates power, and a plurality of third springs 27 are provided at the top end of the buffer plate 26, so that the idle stroke ring 22 moves upward and then has a buffering force, and when the wave comes, the rubber air bag 3 moves upward by providing the rubber air bag 3 filled with gas at the top end of the first rack 2, so that the first rack 2 moves upward, and the plurality of rotating shafts 14 are mounted on the mounting block 11, and the rollers 28 are provided on the rotating shafts 14, so that the friction force is reduced when the first rack 2 moves.

Finally, it should be noted that: although the present invention has been described in detail with reference to the foregoing embodiments, it will be apparent to those skilled in the art that modifications may be made to the embodiments or portions thereof without departing from the spirit and scope of the invention.

Claims (10)

1. A floating power generation system using ocean wave energy, comprising a floating airbag (1), characterized in that: the floating airbag is characterized in that a core control box (5) is installed at the bottom end of the floating airbag (1), connecting rods (6) are installed on four sides of the core control box (5), four connecting rods (6) are far away from one end of the core control box (5) and are provided with a power generation box (4), a first power generation mechanism is installed on the inner side of the power generation box (4), an installation block (11) is installed on the inner side of the power generation box (4), a first gear (10) is installed on the installation block (11) in a rotating mode, the first gear (10) is connected with the first power generation mechanism through a transmission mechanism, a first rack (2) is movably installed on one side of the first gear (10), the first rack (2) is meshed with the first gear (10), a floating mechanism enabling the first rack (2) to move is installed at the top end of the first gear (10), a control panel (12) is installed at the bottom end of the first rack (2) close to one end of the installation block (11), the movable sleeve is equipped with idle stroke ring (22) on control panel (12), cutting board (20) are installed to the bottom of idle stroke ring (22), the adaptation is installed to the bottom of idle stroke ring (22) the second power generation mechanism of cutting board (20).

2. A floating power generation system using ocean wave energy according to claim 1 wherein: first generating mechanism includes mounting box (7), mounting box (7) are installed power generation box (4) inner chamber top, two opposite magnetic pole pieces (29) are installed to the inner chamber both sides of mounting box (7), rotate between two magnetic pole pieces (29) and install cutting frame (13).

3. A floating power generation system using ocean wave energy according to claim 2 wherein: drive mechanism includes ring gear (8), ring gear (8) rotate to be installed on mounting box (7), ring gear (8) inboard rotate install with cutting frame (13) coaxial coupling's second gear (15), ring gear (8) inboard is installed and is made second gear (15) unidirectional rotation's one-way limiting mechanism, ring gear (8) with the cover is equipped with hold-in range (9) on first gear (10), installation piece (11) are kept away from reset mechanism is installed to the one end of hold-in range (9).

4. A floating power generation system using ocean wave energy according to claim 3 wherein: the one-way limiting mechanism comprises a plurality of supporting blocks (17), the supporting blocks (17) are uniformly installed in an inner cavity of the gear ring (8), movable gear teeth (18) are installed on the supporting blocks (17) in a rotating mode, and a first spring (16) is installed between each movable gear tooth (18) and the gear ring (8).

5. A floating power generation system using ocean wave energy according to claim 3 wherein: the resetting mechanism comprises a sliding rail (25), a second rack (23) is arranged in the sliding rail (25) in a sliding mode, the second rack (23) is meshed with the first gear (10), and an elastic mechanism is arranged on one side of the second rack (23).

6. A floating power generation system using ocean wave energy according to claim 5 wherein: the elastic mechanism comprises a second spring (24), one end of the second spring (24) is connected with the second rack (23), and the other end of the second spring (24) is connected with the power generation box (4).

7. A floating power generation system using ocean wave energy according to claim 1 wherein: the second power generation mechanism comprises an installation frame (21), the inner side of the installation frame (21) is located at the two ends of the cutting plate (20) and is provided with a power generation component (19), and the bottom end of the installation block (11) is provided with a buffer mechanism.

8. A floating power generation system using ocean wave energy according to claim 7 wherein: the buffer mechanism comprises a plurality of third springs (27), the third springs (27) are arranged at the bottom end of the mounting block (11), and a buffer plate (26) is arranged at the bottom end of the third springs (27).

9. A floating power generation system using ocean wave energy according to claim 1 wherein: the floating mechanism comprises a rubber air bag (3), the rubber air bag (3) is installed on the top end of the first rack (2), and the rubber air bag (3) is filled with gas.

10. A floating power generation system using ocean wave energy according to claim 1 wherein: the installation piece (11) in a plurality of pivots (14) are installed to one side of first rack (2), and are a plurality of all rotate the cover on pivot (14) and be equipped with gyro wheel (28).

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