CN114087108B

CN114087108B - Wave energy power generation device

Info

Publication number: CN114087108B
Application number: CN202111473499.4A
Authority: CN
Inventors: 张玉良; 李金富; 程亮; 张开源; 林海斌
Original assignee: Quzhou Intelligent Manufacturing Technology And Equipment Research Institute
Current assignee: Quzhou Intelligent Manufacturing Technology And Equipment Research Institute
Priority date: 2021-11-30
Filing date: 2021-11-30
Publication date: 2023-09-29
Anticipated expiration: 2041-11-30
Also published as: CN114087108A

Abstract

The invention relates to the technical field of power generation devices, in particular to a wave power generation device, which comprises a setting table, wherein the surface of the setting table is connected with a wave energy acquisition system in a sliding manner, the wave energy acquisition system comprises a wave energy acquisition part, the wave energy acquisition part comprises a rope which is connected to the setting table in a sliding manner, the rope performs circular motion, a floating ball and a sliding block are fixedly connected to the rope, the floating ball and the sliding block are arranged in the vertical direction and are correspondingly arranged in positions, meanwhile, the movement directions are opposite, and an induction piece is arranged on the floating ball and is used for acquiring wave height information; the sliding block is rotationally connected with a motion conversion part, the motion conversion part is in transmission connection with a generator, the motion conversion part is electrically connected with the generator, and the motion conversion part is electrically connected with the sensing piece. The invention can achieve the purpose of adapting to the wave height change.

Description

Wave energy power generation device

Technical Field

The invention relates to the technical field of power generation devices, in particular to a wave energy power generation device.

Background

In recent years, the problems of energy shortage, ecological environment deterioration, climate warming and the like are increasingly serious worldwide, and the development of renewable energy sources has become a common consensus for various countries and regions. Wherein the generation of electricity by ocean wave energy is one of the technologies for new energy utilization. The wave energy has the characteristics of large quantity and wide range, is not limited by time and space, has huge development potential, and is an important component of future energy. However, the wave height is continuously changed, so that a wave power generation device capable of adapting to the wave height change is needed to solve the problem.

Disclosure of Invention

The invention aims to provide a wave energy power generation device so as to solve the problems and achieve the purpose of adapting to the change of wave height.

In order to achieve the above object, the present invention provides the following solutions: the wave energy power generation device comprises a placement table, wherein the surface of the placement table is connected with a wave energy acquisition system in a sliding manner, the wave energy acquisition system comprises a wave energy acquisition part, the wave energy acquisition part comprises a rope which is connected to the placement table in a sliding manner, the rope performs circular motion, a floating ball and a sliding block are fixedly connected to the rope, the floating ball and the sliding block are arranged in the vertical direction and are correspondingly arranged in positions, meanwhile, the movement directions are opposite, an induction piece is arranged on the floating ball, and the induction piece is used for acquiring wave height information;

the sliding block is rotationally connected with a motion conversion part, the motion conversion part is in transmission connection with a generator, the motion conversion part is electrically connected with the generator, and the motion conversion part is electrically connected with the sensing piece.

Preferably, the motion conversion part comprises a first connecting rod, one end of the first connecting rod is rotationally connected with the sliding block, the other end of the first connecting rod is rotationally connected with one end of a second connecting rod, the other end of the second connecting rod is rotationally connected with one end of a crank, one end of the crank is in transmission connection with the generator, one end of a control rod is slidingly connected with the middle part of the first connecting rod, the other end of the control rod is in transmission connection with a control part, the control part is in electrical connection with the sensing part and the generator, and the middle part of the other end of the control rod is rotationally connected with the placing table.

Preferably, the control part comprises a servo motor, the servo motor is electrically connected with the induction piece and the generator, the bottom of the servo motor is fixedly connected with the placement table, a gear is fixedly connected with an output shaft of the servo motor, a plurality of straight teeth are fixedly connected with one end of the control rod, which is close to the servo motor, and the straight teeth are meshed and connected with the gear.

Preferably, the sensing element is a liquid level sensor.

Preferably, the placement table is fixedly connected with at least four fixed pulleys, a plurality of fixed pulleys are vertically arranged in a rectangular mode, and the ropes are sleeved on the fixed pulleys.

Preferably, a support is fixedly connected above the placement table, a driving shaft is rotatably connected in the middle of the support, a driving belt pulley is fixedly connected in the middle of the driving shaft, the driving belt pulley is in transmission connection with the generator, and one end of the driving shaft is fixedly connected with the other end of the crank.

Preferably, the first driven shaft is rotatably connected above the placement table, one end of the first driven shaft is fixedly connected with a driven belt pulley, the other end of the first driven shaft is fixedly connected with a driving bevel gear, the driven belt pulley and the driving belt pulley are respectively sleeved with two ends of a belt, and the driving bevel gear is in transmission connection with the generator.

Preferably, the second driven shaft is rotatably connected above the placement table and is perpendicular to the first driven shaft, one end of the second driven shaft is fixedly connected with a driven bevel gear, the driven bevel gear is in meshed connection with the drive bevel gear, and the other end of the second driven shaft is fixedly connected with the generator.

Preferably, the generator is provided with a generator shaft, one end of a coupler is fixedly connected with the generator shaft, the other end of the coupler is fixedly connected with the second driven shaft, the generator is electrically connected with a storage battery, and the storage battery is electrically connected with the servo motor.

Preferably, a base is fixedly connected below the placement table.

The invention has the following technical effects: the wave energy acquisition system converts the kinetic energy of waves into mechanical energy, the motion conversion part converts vertical reciprocating motion into circular motion to enable the generator to rotate for generating electricity, the generator supplies part of electric energy to the motion conversion part to provide power for the motion conversion part, and the induction part transmits information to the motion conversion part after acquiring the wave height, so that the device is integrally adapted to different wave heights; the rope is in a tensioning state, the sliding block is connected with the floating ball, and when waves impact the floating ball, the floating ball ascends and the sliding block descends; otherwise, after the waves are removed, the floating ball descends under the action of gravity, the sliding block ascends, the floating ball and the sliding block move in opposite directions, the sliding block drives the motion conversion part to move, and the vertical reciprocating motion of the sliding block is converted into circular motion so that the generator rotates to generate electricity.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions of the prior art, the drawings that are needed in the embodiments will be briefly described below, it being obvious that the drawings in the following description are only some embodiments of the present invention, and that other drawings may be obtained according to these drawings without inventive effort for a person skilled in the art.

FIG. 1 is a schematic diagram of the overall structure of the present invention;

FIG. 2 is a front view of the park bench of the present invention;

FIG. 3 is a rear view of the inventive park bench;

FIG. 4 is a diagram of a transmission system of the present invention;

FIG. 5 is a schematic diagram of a partial construction of a transmission system according to the present invention;

1, arranging a table; 2. a storage battery; 3. a floating ball; 4. a slide block; 5. a liquid level sensor; 6. a rope; 7. a fixed pulley; 8. a base; 9. a first link; 10. a control lever; 11. a second link; 12. a coupling; 13. a generator; 14. a servo motor; 15. a gear; 16. a crank; 17. a driving pulley; 18. a belt; 19. a driven pulley; 20. a bearing seat bracket; 21. a drive bevel gear; 22. a driven bevel gear; 23. a bearing seat; 24. a first wire; 25. a second wire; 26. a bracket; 27. a driving shaft; 28. a first driven shaft; 29. a second driven shaft; 30. a generator shaft.

Detailed Description

The following description of the embodiments of the present invention will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present invention, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

In order that the above-recited objects, features and advantages of the present invention will become more readily apparent, a more particular description of the invention will be rendered by reference to the appended drawings and appended detailed description.

Referring to fig. 1-5, the present embodiment provides a wave power generation device, including a setting table 1, a wave power acquisition system is slidably connected to the surface of the setting table 1, the wave power acquisition system includes a wave power acquisition portion, the wave power acquisition portion includes a rope 6 slidingly connected to the setting table 1, the rope 6 performs a circular motion, a floating ball 3 and a sliding block 4 are fixedly connected to the rope 6, the floating ball 3 and the sliding block 4 are disposed in a vertical direction and are disposed in positions corresponding to each other, meanwhile, the moving directions are opposite, a sensing member is disposed on the floating ball, and the sensing member is used for acquiring wave height information;

the sliding block 4 is rotatably connected with a motion conversion part through a bearing, the motion conversion part is in transmission connection with a generator 13, the motion conversion part is electrically connected with the generator 13, and the motion conversion part is electrically connected with the sensing piece.

The wave energy acquisition system converts the kinetic energy of waves into mechanical energy, the motion conversion part converts vertical reciprocating motion into circular motion to enable the generator 13 to rotate for power generation, the generator 13 supplies part of electric energy to the motion conversion part to provide power for the motion conversion part, and the induction part transmits information to the motion conversion part after acquiring the wave height, so that the device is integrally adapted to different wave heights; the rope 6 is in a tensioning state, meanwhile, the sliding block 4 is connected with the floating ball 3, when waves impact the floating ball 3, the floating ball 3 ascends, and the sliding block 4 descends; on the contrary, after the wave is removed, the floating ball 3 descends under the action of gravity, the sliding block 4 ascends, the moving direction of the floating ball 3 is opposite to that of the sliding block 4, the sliding block 4 drives the motion conversion part to move, and the vertical reciprocating motion of the sliding block 4 is converted into circular motion so that the generator 13 rotates to generate electricity.

Further optimizing scheme, motion conversion portion includes first connecting rod 9, first connecting rod 9 one end is connected with slider 4 rotation, the one end that first connecting rod 9 other end rotated and is connected with second connecting rod 11, the one end that the second connecting rod 11 other end rotated and is connected with crank 16, crank 16's one end and generator 13 transmission are connected, first connecting rod 9 middle part sliding connection has the one end of control lever 10, control lever 10 other end limit portion transmission is connected with the control division, control division and inductor, generator 13 electric connection, control lever 10 other end middle part is connected with setting table 1 rotation.

The control rod 10 is of an arc-shaped structure, an arc-shaped groove is formed in the middle of the first connecting rod 9, the control rod 10 can slide along the arc-shaped groove, the control part can control the movement and the rest of the control rod 10, when the control rod 10 is static, the sliding block 4 drives the first connecting rod 9 to do reciprocating swing around the end part of the control rod 10, the first connecting rod 9 drives the second connecting rod 11 to swing up and down, the tail end of the second connecting rod 11 drives the crank 16 to do circular motion, and the crank 16 drives the generator 13 to rotate through other transmission parts to generate electricity.

Further optimizing scheme, the control portion includes servo motor 14, servo motor 14 and sensing piece, generator 13 electric connection, servo motor 14 bottom and setting table 1 rigid coupling, and servo motor 14 output shaft rigid coupling has gear 15, and control lever 10 is close to servo motor 14 one end rigid coupling and has a plurality of straight teeth, and the straight teeth is connected with gear 15 meshing.

When the wave height changes, the water level information is collected by the sensing piece, the sensing piece transmits signals to the controller (not shown in the figure), the controller can select a PLC (programmable logic controller) and the like, the connection mode is the prior art, details are omitted here, the controller controls the servo motor 14 to rotate, the servo motor 14 drives the control rod 10 to rotate around the setting table 1 by meshing of the gear 15 and the straight teeth for a certain angle, one end of the control rod 10, which is close to the first connecting rod 9, slides along a groove in the middle of the first connecting rod 9 for a certain distance, a four-bar mechanism formed by the first connecting rod 9, the second connecting rod 11 and the crank 16 meets bar length conditions again, and the crank 16 can continue to rotate at a constant speed, so that the wave power generation device of the embodiment can adapt to the wave height changes, and the power generation device stably operates.

In a further preferred embodiment, the sensor is a liquid level sensor 5. The liquid level sensor 5 can collect wave height information and transmit the information to a controller, and the controller controls the servo motor 14 to rotate.

In a further optimized scheme, the placement table 1 is fixedly connected with at least four fixed pulleys 7, the fixed pulleys 7 are vertically arranged in a rectangular mode, and the ropes 6 are sleeved on the fixed pulleys 7. The rope 6 is tensioned by the fixed pulleys 7, and the floating ball 3 and the sliding block 4 are respectively positioned between the fixed pulleys 7 in the same vertical direction.

In a further optimized scheme, a support 26 is fixedly connected above the placement table 1, a driving shaft 27 is rotatably connected in the middle of the support 26, a driving belt pulley 17 is fixedly connected in the middle of the driving shaft 27, the driving belt pulley 17 is in transmission connection with the generator 13, and one end of the driving shaft 27 is fixedly connected with the other end of the crank 16. The rotation of the crank 16 drives the driving shaft 27 to rotate, the driving shaft 27 drives the driving belt pulley 17 to rotate, the driving belt pulley 17 drives the generator 13 to rotate through other parts to generate electricity, and the support 26 plays a role in supporting the driving shaft 27.

In a further optimized scheme, a first driven shaft 28 is rotatably connected above the placement table 1, one end of the first driven shaft 28 is fixedly connected with a driven belt pulley 19, the other end of the first driven shaft 28 is fixedly connected with a driving bevel gear 21, the driven belt pulley 19 and the driving belt pulley 17 are respectively sleeved with two ends of a belt 18, and the driving bevel gear 21 is in transmission connection with the generator 13. Two bearing seat brackets 20 are fixedly connected above the placement table 1, a bearing seat 23 is fixedly connected above the bearing seat brackets 20, the two bearing seats 23 support a first driven shaft 28 to rotate, the driving belt pulley 17 drives the driven belt pulley 19 to rotate through the belt 18, and the rotating speed of the first driven shaft 28 is higher than that of the driving belt pulley 17 because the diameter of the driving belt pulley 17 is larger than that of the driven belt pulley 19, so that the rotating speed requirement of the generator 13 is met.

In a further optimized scheme, a second driven shaft 29 is rotatably connected above the placement table 1, the second driven shaft 29 is perpendicular to the first driven shaft 28, one end of the second driven shaft 29 is fixedly connected with a driven bevel gear 22, the driven bevel gear 22 is in meshed connection with the driving bevel gear 21, and the other end of the second driven shaft 29 is fixedly connected with the generator 13. Another bearing seat support 20 is fixedly connected above the setting table 1, another bearing seat 23 is fixedly connected above the bearing seat support 20, the bearing seat 23 is used for supporting a second driven shaft 29 to rotate, the first driven shaft 28 transmits power to the driven bevel gear 22 through the driving bevel gear 21, the driven bevel gear 22 drives the second driven shaft 29 to rotate, and the second driven shaft 29 drives the generator 13 to rotate for generating electricity.

In a further optimized scheme, the generator 13 is provided with a generator shaft 30, one end of the coupler 12 is fixedly connected with the generator shaft 30, the other end of the coupler 12 is fixedly connected with the second driven shaft 29, the generator 13 is electrically connected with the storage battery 2, and the storage battery 2 is electrically connected with the servo motor 14.

The second driven shaft 29 drives the generator shaft 30 of the generator 13 to rotate through the coupling 12, so that the generator 13 generates electricity, the generator 13 transmits electric energy to the storage battery 2 through the first lead 24, and the storage battery 2 transmits electric energy to the servo motor 14 through the second lead 25.

In a further optimized scheme, a base 8 is fixedly connected below the placement table 1. The base 8 serves to support the setting table 1.

The working procedure of this embodiment is as follows: because the floating ball 3 and the sliding block 4 are respectively positioned between the fixed pulleys 7 in the same vertical direction, the floating ball 3 can be ensured to reciprocate up and down under the action of wave motion, and the sliding block 4 can be driven to swing up and down. Meanwhile, the liquid level sensor 5 arranged on the floating ball 3 feeds the acquired liquid level information back to the servo motor 14 through the controller, the servo motor 14 drives the gear 15 to rotate by a certain angle, and the control rod 10 also rotates by a certain angle under the meshing action of the gear, so that the other end of the control rod 10 slides to a proper position along the groove on the first connecting rod 9. After the adjustment of the servo motor 14 and the control rod 10, wave energy of any height can be obtained and converted into stable rotary mechanical energy through a transmission mechanism consisting of the first connecting rod 9, the control rod 10, the second connecting rod 11 and the crank 16. The crank 16 is connected with the driving shaft 27 through a key slot to drive the driving shaft 27 to start rotating, and the number of teeth of the driving belt pulley 17 is larger than that of the driven belt pulley 19, so that the rotating speed is improved, and the rotating speed requirement of the generator 13 is met. The transmission direction is changed through the meshing transmission of the driving bevel gear 21 and the driven bevel gear 22, so that the layout of the whole arrangement table 1 is more reasonable. The second driven shaft 29 is connected to the generator shaft 30 via the coupling 12, thereby driving the generator 13 to operate. The electric energy generated by the generator 13 is stored in the battery 2 via the first conductor 24, while a small part of the electric energy in the battery 2 is supplied to the servomotor 14 via the second conductor 25.

In the description of the present invention, it should be understood that the terms "longitudinal," "transverse," "upper," "lower," "front," "rear," "left," "right," "vertical," "horizontal," "top," "bottom," "inner," "outer," and the like indicate or are based on the orientation or positional relationship shown in the drawings, merely to facilitate description of the present invention, and do not indicate or imply that the devices or elements referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus should not be construed as limiting the present invention.

The above embodiments are only illustrative of the preferred embodiments of the present invention and are not intended to limit the scope of the present invention, and various modifications and improvements made by those skilled in the art to the technical solutions of the present invention should fall within the protection scope defined by the claims of the present invention without departing from the design spirit of the present invention.

Claims

1. The utility model provides a wave energy power generation facility which characterized in that: the device comprises a placement table (1), wherein a wave energy acquisition system is connected to the surface of the placement table (1) in a sliding manner, the wave energy acquisition system comprises a wave energy acquisition part, the wave energy acquisition part comprises a rope (6) which is connected to the placement table (1) in a sliding manner, the rope (6) moves circularly, a floating ball (3) and a sliding block (4) are fixedly connected to the rope (6), the floating ball (3) and the sliding block (4) are arranged in the vertical direction, the positions of the floating ball and the sliding block (4) are correspondingly arranged, meanwhile, the movement directions of the floating ball are opposite, and an induction piece is arranged on the floating ball and is used for acquiring wave height information; the sliding block (4) is rotationally connected with a motion conversion part, the motion conversion part is in transmission connection with a generator (13), the motion conversion part is electrically connected with the generator (13), and the motion conversion part is electrically connected with the sensing piece;

the motion conversion part comprises a first connecting rod (9), one end of the first connecting rod (9) is rotationally connected with the sliding block (4), one end of a second connecting rod (11) is rotationally connected with the other end of the first connecting rod (9), one end of a crank (16) is rotationally connected with the other end of the second connecting rod (11), one end of the crank (16) is in transmission connection with the generator (13), one end of a control rod (10) is slidingly connected in the middle of the first connecting rod (9), a control part is in transmission connection with the edge of the other end of the control rod (10), the control part is electrically connected with the sensing part and the generator (13), and the middle of the other end of the control rod (10) is rotationally connected with the placement table (1);

the control part comprises a servo motor (14), the servo motor (14) is electrically connected with the induction piece and the generator (13), the bottom of the servo motor (14) is fixedly connected with the placement table (1), a gear (15) is fixedly connected with an output shaft of the servo motor (14), a plurality of straight teeth are fixedly connected with one end of the control rod (10) close to the servo motor (14), and the straight teeth are meshed and connected with the gear (15).

2. A wave energy power unit according to claim 1, characterized in that: the sensing piece is a liquid level sensor (5).

3. A wave energy power unit according to claim 1, characterized in that: the positioning table (1) is fixedly connected with at least four fixed pulleys (7), a plurality of fixed pulleys (7) are vertically arranged in a rectangular mode, and the ropes (6) are sleeved on the fixed pulleys (7).

4. A wave energy power unit according to claim 1, characterized in that: the device is characterized in that a support (26) is fixedly connected above the placement table (1), a driving shaft (27) is rotationally connected in the middle of the support (26), a driving belt pulley (17) is fixedly connected in the middle of the driving shaft (27), the driving belt pulley (17) is in transmission connection with the generator (13), and one end of the driving shaft (27) is fixedly connected with the other end of the crank (16).

5. A wave energy power unit according to claim 4, characterized in that: a first driven shaft (28) is rotationally connected above the placement table (1), one end of the first driven shaft (28) is fixedly connected with a driven belt pulley (19), the other end of the first driven shaft (28) is fixedly connected with a driving bevel gear (21), the driven belt pulley (19) and the driving belt pulley (17) are respectively sleeved at two ends of the belt (18), and the driving bevel gear (21) is in transmission connection with the generator (13).

6. A wave energy power unit according to claim 5, characterized in that: the device is characterized in that a second driven shaft (29) is connected above the placement table (1) in a rotating mode, the second driven shaft (29) is perpendicular to the first driven shaft (28), a driven bevel gear (22) is fixedly connected to one end of the second driven shaft (29), the driven bevel gear (22) is connected with the driving bevel gear (21) in a meshed mode, and the other end of the second driven shaft (29) is fixedly connected with the generator (13).

7. The wave energy power unit of claim 6, wherein: the generator (13) is provided with a generator shaft (30), one end of a coupler (12) is fixedly connected with the generator shaft (30), the other end of the coupler (12) is fixedly connected with a second driven shaft (29), the generator (13) is electrically connected with a storage battery (2), and the storage battery (2) is electrically connected with the servo motor (14).

8. A wave energy power unit according to claim 1, characterized in that: a base (8) is fixedly connected below the placement table (1).