阅读说明：本技术 一种风能波浪能安全太阳能发电设备 (Wind energy wave energy safety solar power generation equipment ) 是由 李爱蓝 于 2020-12-30 设计创作，主要内容包括：本发明涉及光伏太阳能技术领域,尤其是一种风能波浪能安全太阳能发电设备,包括机身,所述机身下方圆周阵列固定设置有六个使设备浮在水面上的支撑浮球,所述机身上端壁固定设置有向上延伸的锥形发电柱,所述机身外端壁圆周阵列固定设置有六个浮动支撑杆,所述浮动支撑杆上径向向外铰接设置有浮动架,所述机身内设置有液压齿轮腔,本发明提供的一种风能波浪能安全太阳能发电设备,本发明在晴天可通过光伏板转化为电能；在暴风雨天气时,光伏板自动闭合,海水起伏形成较大的高低落差,在此作用下发电效率更高；无论什么天气风能发电均可高效运行,在未达到光饱和点时,凹面镜反射阳光给光伏板进行第二次利用利用率远远超过了传统的光伏发电装置。(The invention relates to the technical field of photovoltaic solar energy, in particular to wind energy and wave energy safe solar power generation equipment which comprises a machine body, wherein six supporting floating balls for enabling the equipment to float on the water surface are fixedly arranged on the circumferential array below the machine body, an upward extending conical power generation column is fixedly arranged on the upper end wall of the machine body, six floating supporting rods are fixedly arranged on the circumferential array of the outer end wall of the machine body, floating frames are radially and outwards hinged on the floating supporting rods, and a hydraulic gear cavity is arranged in the machine body; in stormy weather, the photovoltaic panel is automatically closed, and the sea water fluctuates to form larger height drop, so that the power generation efficiency is higher; wind power generation can be operated efficiently no matter what weather, and when the light saturation point is not reached, the concave mirror reflects sunlight to carry out secondary utilization and utilization rate for the photovoltaic panel, which far exceeds the traditional photovoltaic power generation device.)

1. The utility model provides a wind energy wave energy safety solar power system, includes the fuselage, its characterized in that: six supporting floating balls which enable equipment to float on the water surface are fixedly arranged on the circumference array below the machine body, an upward extending conical power generation column is fixedly arranged on the upper end wall of the machine body, six floating support rods are fixedly arranged on the circumference array of the outer end wall of the machine body, a floating frame is hinged to the floating support rods radially outwards, a hydraulic gear cavity is arranged in the machine body, a hydraulic motor is fixedly arranged on the right side of the upper end wall of the hydraulic gear cavity, waves drive the floating frame to rotate in a reciprocating manner through a wave power generation mechanism, the hydraulic motor can be driven to rotate to generate wave power, a planetary cavity is arranged below the hydraulic gear cavity in the machine body, a power generator is fixedly arranged on the right end wall of the planetary cavity, a power generator shaft is arranged on the power generator to the left side, a relevant closed cavity is arranged below the power generation column, and a reset conical tooth cavity, a wind power main shaft which extends up and down and penetrates through the hydraulic gear cavity, the closing cavity and the reset bevel gear cavity is rotatably arranged between the upper end wall of the power generation column and the planetary cavity, a planetary mechanism which combines the rotation of the wind power main shaft and the rotation of the hydraulic motor into the rotation of the power generator shaft is arranged in the planetary cavity to generate power, three groups of four worm and worm gear cavities which are circumferentially arranged in an array manner and are provided with outward openings are arranged on the power generation column in an up-and-down array manner, photovoltaic shafts which extend up and down are rotatably arranged between the worm and worm gear cavities, a photoelectric power shaft which is coaxial with the photovoltaic shafts and extends up and down is rotatably arranged on the upper end wall of the closing cavity, the photoelectric power shaft and the photovoltaic shafts are connected by using a safety clutch, a worm is fixedly arranged in the worm and worm gear cavity, and a worm gear shaft which extends tangentially is rotatably arranged in the worm, the solar photovoltaic power generation device is characterized in that a worm wheel meshed with the worm is fixedly arranged on the worm wheel shaft close to the axis end, a photovoltaic plate extending outwards is hinged to the side, away from the axis, of the worm wheel shaft, a concave mirror extending outwards is fixedly arranged on the worm wheel shaft, the concave mirror is connected with the photovoltaic plate through an unfolding spring to enable the included angle of the photovoltaic plate to be kept at fifty-five degrees during working, a solar opening and closing mechanism for controlling the opening and closing of the photovoltaic plate is arranged in a reset conical tooth cavity, a wind power generation mechanism for driving a wind power main shaft to rotate is rotatably arranged at the upper end of a power generation column, storage batteries are fixedly arranged in the machine body in a bilateral symmetry mode, an oil tank is fixedly arranged in the machine body.

2. A wind energy, wave energy, safe solar power plant as claimed in claim 1, wherein: the wave power generation mechanism comprises hydraulic cylinders which are fixedly arranged on the circumferential array of the upper end wall of the machine body and correspond to the floating support rods, a piston rod extending in the radial direction is arranged in the hydraulic cylinder in a sliding manner, a floating ball groove is fixedly arranged at the end of the piston rod far away from the axis, a tangentially extending floating ball pin is fixedly arranged on the upper end wall of the floating frame close to the axle center side and can freely slide in the floating ball groove, the floating frame is provided with a floating ball shaft in a rotating way at the end far away from the axis, a floating ball is fixedly arranged on the floating ball shaft, the left side and the right side of the hydraulic cylinder are provided with pipelines extending downwards, the two pipelines are symmetrically communicated with one-way valves communicated in a downward one-way mode, oil inlet pipelines of the two check valves at the upper side are communicated with each other and connected to the bottom of the oil tank, oil outlets of the two check valves at the lower side are communicated with each other and connected to an oil inlet of the hydraulic motor, and the oil outlet of the hydraulic motor is communicated with the oil tank.

3. A wind energy, wave energy, safe solar power plant as claimed in claim 1, wherein: the planetary mechanism comprises a hydraulic shaft which is arranged between the hydraulic gear cavity and the planetary cavity in a rotating way and is coaxial with the wind power main shaft, the hydraulic motor is fixedly provided with a hydraulic driving gear under downward power, the upper end of the hydraulic shaft is fixedly provided with a hydraulic driven gear engaged with the hydraulic driving gear, a hydraulic input bevel gear is fixedly arranged at the lower end of the hydraulic shaft, a planetary shaft which extends up and down is rotatably arranged on the hydraulic shaft in the planetary cavity, an output bevel gear is fixedly arranged on the planet shaft, a planet carrier extending downwards and rightwards is fixedly arranged on the planet shaft, a planetary bevel gear shaft extending in the radial direction of the wind power main shaft is rotatably arranged on the planet carrier, a planetary bevel gear meshed with the hydraulic input bevel gear is fixedly arranged on the planetary bevel gear shaft close to the axis, and a wind power input bevel gear used for meshing the planetary bevel gears is fixedly arranged at the lower end of the wind power main shaft.

4. A wind energy, wave energy, safe solar power plant as claimed in claim 1, wherein: the solar opening and closing mechanism comprises a main reset bevel gear, a secondary reset bevel gear, a photoelectric bevel gear, a closing shaft, a main closing bevel gear, an opening and closing gear, a sliding rod and a sliding rod, wherein the main wind power shaft is positioned in the reset bevel gear cavity and is connected and arranged through a low-speed coupler, the photovoltaic shaft is positioned in the reset bevel gear cavity and is fixedly provided with a reset secondary bevel gear meshed with the reset primary bevel gear, the lower end of the photoelectric power shaft is fixedly provided with the photoelectric bevel gear, the lower end wall of the closing cavity is rotatably provided with the closing shaft which extends up and down and corresponds to the photoelectric power shaft, the upper end of the closing shaft is fixedly provided with the main closing bevel gear meshed with the photoelectric bevel gear, the closing shaft is fixedly provided with the opening and closing gear, the main wind power shaft is positioned in the closing cavity and is, the sliding rod is connected with the sliding rod cavity through a sliding rod spring, and a friction plate which can be abutted against the inner end wall of the closing gear is fixedly arranged at the end, far away from the axis, of the sliding rod.

5. A wind energy, wave energy, safe solar power plant as claimed in claim 1, wherein: wind power generation mechanism includes the wind-force axle that upwards extends that the electricity generation post upper end rotated the setting, the wind-force epaxial end is fixed to be provided with the wind-powered electricity body, the internal wind-force awl tooth chamber that is provided with of wind-force, wind-force awl tooth chamber with the fan axle that extends about the wind-powered electricity body left end wall interrotation is provided with, the fixed fan leaf that is provided with in fan axle left end, the fixed fan bevel gear that is provided with of fan axle right-hand member, wind-force main shaft upwards extends to in the wind-force awl tooth chamber, wind-force main shaft upper end fixed be provided with fan bevel gear meshing's wind.

Technical Field

The invention relates to the technical field of photovoltaic solar energy, in particular to wind energy and wave energy safe solar power generation equipment.

Background

Solar energy has become an indispensable part of people's daily lives, wave energy is a renewable green energy with abundant reserves, is applied to islands and offshore facilities, and simultaneously offshore wind energy resources are abundant, however, in remote areas or ocean islands, it is difficult to connect with continents through overhead wires or submarine cables to carry out power grid connection. However, photovoltaic power generation can only be carried out in the daytime, the wind waves on the sea surface are large, and the photovoltaic panel is easily damaged when strong wind comes, so that a wind energy and wave energy safe solar power generation device is needed to be designed to solve the problems.

Disclosure of Invention

The invention aims to provide wind energy and wave energy safe solar power generation equipment which can overcome the defects in the prior art, so that the practicability of the equipment is improved.

The technical scheme adopted by the invention for solving the technical problems is as follows: the invention relates to wind energy and wave energy safety solar power generation equipment, which comprises a machine body, wherein six supporting floating balls for floating the equipment on the water surface are fixedly arranged on the circumferential array below the machine body, an upward extending conical power generation column is fixedly arranged on the upper end wall of the machine body, six floating support rods are fixedly arranged on the circumferential array of the outer end wall of the machine body, floating supports are radially and outwards hinged on the floating support rods, a hydraulic gear cavity is arranged in the machine body, a hydraulic motor is fixedly arranged on the right side of the upper end wall of the hydraulic gear cavity, the floating supports are driven by waves to rotate in a reciprocating manner, the hydraulic motor can be driven by a wave power generation mechanism to rotate so as to carry out wave power generation, a planetary cavity is arranged below the hydraulic gear cavity in the machine body, a power generator is fixedly arranged on the right end wall of, a closed cavity is arranged below the power generation column, a reset bevel gear cavity is arranged above the closed cavity in the power generation column, a wind power main shaft which extends up and down and penetrates through the hydraulic gear cavity, the closed cavity and the reset bevel gear cavity is rotatably arranged between the upper end wall of the power generation column and the planetary cavity, a planetary mechanism which combines the wind power main shaft and the hydraulic motor into a generator shaft to generate power is arranged in the planetary cavity, three groups of four worm gear cavities which are circumferentially arranged in an up-and-down array mode and are provided with outward openings are arranged on the power generation column, a photovoltaic shaft which extends up and down is rotatably arranged between the worm gear cavities, a photoelectric power shaft which extends up and down and is coaxial with the photovoltaic shaft is rotatably arranged on the upper end wall of the closed cavity, the photoelectric power shaft and the photovoltaic shaft are connected by using a safety clutch, and a worm is fixedly arranged in the worm gear cavity, the solar photovoltaic power generation device is characterized in that a worm gear shaft extending tangentially is rotatably arranged in the worm gear and worm cavity, a worm gear meshed with the worm is fixedly arranged on the worm gear shaft close to the axis end, a photovoltaic plate extending outwards is hinged to the side, away from the axis end, of the worm gear shaft, a concave mirror extending outwards is fixedly arranged on the worm gear shaft, the concave mirror is connected with the photovoltaic plate through a spreading spring to enable the included angle of the concave mirror to be kept at fifty-five degrees during working, a solar opening and closing mechanism for controlling the opening and closing of the photovoltaic plate is arranged in the reset conical tooth cavity and the closing cavity, a wind power generation mechanism for driving the wind power main shaft to rotate is rotatably arranged at the upper end of the power generation column, storage batteries are fixedly arranged in the machine body in a bilateral symmetry mode, an.

Furthermore, the wave power generation mechanism comprises hydraulic cylinders which are fixedly arranged on the upper end wall of the machine body in a circumferential array and correspond to the floating support rods, radially extending piston rods are arranged in the hydraulic cylinders in a sliding manner, floating ball grooves are fixedly arranged on the piston rods far away from the axle center, tangentially extending floating ball pins are fixedly arranged on the upper end wall of the floating frame near to the axle center, the floating ball pins can freely slide in the floating ball grooves, floating ball shafts are rotatably arranged on the floating frame far away from the axle center, floating balls are fixedly arranged on the floating ball shafts, downward extending pipelines are arranged on the left side and the right side of the hydraulic cylinders, one-way valves which are communicated in a downward one-way are symmetrically communicated on the two pipelines, oil inlet pipelines of the two check valves on the upper side are communicated and connected to the bottom of the oil tank, oil outlets of the two check valves on the lower, the oil outlet of the hydraulic motor is communicated with the oil tank.

Furthermore, the planetary mechanism comprises a hydraulic shaft which is arranged between the hydraulic gear cavity and the planetary cavity in a rotating way and is coaxial with the wind power main shaft, the hydraulic motor is fixedly provided with a hydraulic driving gear under downward power, the upper end of the hydraulic shaft is fixedly provided with a hydraulic driven gear engaged with the hydraulic driving gear, a hydraulic input bevel gear is fixedly arranged at the lower end of the hydraulic shaft, a planetary shaft which extends up and down is rotatably arranged on the hydraulic shaft in the planetary cavity, an output bevel gear is fixedly arranged on the planet shaft, a planet carrier extending downwards and rightwards is fixedly arranged on the planet shaft, a planetary bevel gear shaft extending in the radial direction of the wind power main shaft is rotatably arranged on the planet carrier, a planetary bevel gear meshed with the hydraulic input bevel gear is fixedly arranged on the planetary bevel gear shaft close to the axis, and a wind power input bevel gear used for meshing the planetary bevel gears is fixedly arranged at the lower end of the wind power main shaft.

Furthermore, the solar energy opening and closing mechanism comprises a main reset bevel gear, a secondary reset bevel gear, a photoelectric bevel gear, a closing shaft, a main closing bevel gear, an opening and closing gear, a sliding rod cavity and a sliding rod, wherein the main wind shaft is positioned in the reset bevel gear cavity and is connected and arranged through a low-speed coupler, the photovoltaic shaft is positioned in the reset bevel gear cavity and is fixedly provided with a reset secondary bevel gear meshed with the reset primary bevel gear, the lower end of the photoelectric power shaft is fixedly provided with the photoelectric bevel gear, the lower end wall of the closing cavity is rotatably provided with the closing shaft which extends up and down and corresponds to the photoelectric power shaft, the upper end of the closing shaft is fixedly provided with the main closing bevel gear meshed with the photoelectric bevel gear, the closing shaft is fixedly provided with the opening and closing gear, the main wind shaft is positioned in the closing cavity and is rotatably provided with the closing gear, the sliding rod is connected with the sliding rod cavity through a sliding rod spring, and a friction plate which can be abutted against the inner end wall of the closing gear is fixedly arranged at the end, far away from the axis, of the sliding rod.

Furthermore, the wind power generation mechanism comprises a wind power shaft which is arranged at the upper end of the power generation column in a rotating mode and extends upwards, a wind power body is fixedly arranged at the upper end of the wind power shaft, a wind power bevel gear cavity is arranged in the wind power body, a fan shaft which extends left and right is rotatably arranged between the wind power bevel gear cavity and the left end wall of the wind power body, a fan blade is fixedly arranged at the left end of the fan shaft, a fan bevel gear is fixedly arranged at the right end of the fan shaft, the wind power main shaft extends upwards into the wind power bevel gear cavity, and a wind power bevel gear meshed with the fan bevel gear is fixedly arranged at the upper end of the wind power.

The invention has the beneficial effects that: according to the wind energy and wave energy safe solar power generation equipment, the wind energy and wave energy safe solar power generation equipment can be converted into electric energy through the photovoltaic panel in sunny days; in stormy weather, the photovoltaic panel is automatically closed, and the sea water fluctuates to form larger height drop, so that the power generation efficiency is higher; wind power generation can be operated efficiently no matter what weather, and when the light saturation point is not reached, the concave mirror reflects sunlight to carry out secondary utilization and utilization rate for the photovoltaic panel, which far exceeds the traditional photovoltaic power generation device.

Drawings

In order to more clearly illustrate the embodiments of the invention 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, and it is obvious that the drawings in the following description are only some embodiments of the invention, and it is obvious for those skilled in the art that other drawings can be obtained based on these drawings without creative efforts.

The invention is further illustrated with reference to the following figures and examples.

Fig. 1 is a schematic structural diagram of the whole wind energy and wave energy safety solar power generation equipment.

Fig. 2 is a schematic diagram of a hydraulic system of the wind energy, wave energy, safety solar power generation equipment.

Fig. 3 is an enlarged schematic view of a in fig. 1.

FIG. 4 is a schematic diagram of B-B in FIG. 1.

Detailed Description

The invention will now be described in detail with reference to fig. 1-4, wherein for ease of description the orientations described hereinafter are now defined as follows: the up, down, left, right, and front-back directions described below correspond to the up, down, left, right, and front-back directions in the projection relationship of fig. 1 itself.

The wind energy and wave energy safe solar power generation equipment described in the attached drawings 1-4 comprises a machine body 10, six supporting floating balls 11 which enable the equipment to float on the water surface are fixedly arranged on the lower portion of the machine body 10 in a circumferential array mode, an upward extending conical power generation column 61 is fixedly arranged on the upper end wall of the machine body 10, six floating support rods 19 are fixedly arranged on the outer end wall of the machine body 10 in a circumferential array mode, floating supports 20 are hinged to the floating support rods 19 in a radially outward mode, a hydraulic gear cavity 55 is arranged in the machine body 10, a hydraulic motor 52 is fixedly arranged on the right side of the upper end wall of the hydraulic gear cavity 55, the floating supports 20 are driven by waves to rotate in a reciprocating mode to drive the hydraulic motor 52 to rotate to generate wave power through a wave power generation mechanism 100, a planetary cavity 15 is arranged below the hydraulic gear cavity 55 in the machine body 10, and a power generator 13 is fixedly, the generator 13 is provided with a generator shaft 14 for left power, a closed cavity 51 is arranged below the generator column 61, a reset bevel gear cavity 17 is arranged above the closed cavity 51 in the generator column 61, a wind power main shaft 57 which extends up and down and penetrates through the hydraulic gear cavity 55, the closed cavity 51 and the reset bevel gear cavity 17 is arranged between the upper end wall of the generator column 61 and the planet cavity 15 in a rotating manner, a planet mechanism 200 which combines the wind power main shaft 57 and the hydraulic motor 52 in a rotating manner into the generator shaft 14 is arranged in the planet cavity 15 for generating power, three groups of four worm gear cavities 36 which are arranged in a circumferential array and are provided with openings outwards are arranged in an upper-lower array on the generator column 61, a photovoltaic shaft 35 which extends up and down is arranged between the worm gear cavities 36 in a rotating manner, a photovoltaic power shaft 48 which extends up and down and is coaxial with the photovoltaic shaft 35 is arranged on the upper end wall of the closed cavity 51 in a rotating manner, the photovoltaic power shaft 48 and the photovoltaic shaft 35 are connected by a safety clutch 47, the photovoltaic shaft 35 is positioned in the worm gear cavity 36 and fixedly provided with a worm 37, the worm gear cavity 36 is rotatably provided with a tangentially extending worm gear shaft 45, the worm gear shaft 45 is fixedly provided with a worm wheel 46 engaged with the worm 37 near the axis, the side of the worm gear shaft 45 away from the axis is hinged with an outward extending photovoltaic panel 31, the worm gear shaft 45 is fixedly provided with an outward extending concave mirror 34, the concave mirror 34 and the photovoltaic panel 31 are connected by an unfolding spring 33 to keep the included angle of the photovoltaic panel 31 at fifty-five degrees during working, the reset conical tooth cavity 17 and the closing cavity 51 are internally provided with a solar opening and closing mechanism 300 for controlling the opening and closing of the photovoltaic panel 31, the upper end of the power generation column 61 is rotatably provided with a wind power generation mechanism 400 for driving the wind power main shaft 57 to rotate, the portable air conditioner is characterized in that storage batteries 12 are fixedly arranged in the machine body 10 in a bilateral symmetry mode, oil tanks 16 are fixedly arranged in the machine body 10, and the oil tanks 16 are communicated with external air.

Beneficially, the wave power generating mechanism 100 includes hydraulic cylinders 26 fixedly arranged on the circumferential array of the upper end wall of the machine body 10 and corresponding to the floating support rod 19, radially extending piston rods 25 are arranged in the hydraulic cylinders 26 in a sliding manner, floating ball grooves 24 are fixedly arranged on the piston rods 25 away from the axial end, tangentially extending floating ball pins 23 are fixedly arranged on the upper end wall of the floating frame 20 close to the axial end, the floating ball pins 23 can freely slide in the floating ball grooves 24, floating ball shafts 21 are rotatably arranged on the floating frame 20 away from the axial end, floating balls 22 are fixedly arranged on the floating ball shafts 21, downwardly extending pipelines are arranged on the left side and the right side of the hydraulic cylinders 26, downward one-way conducting check valves 56 are symmetrically communicated on the upper side and the lower side of the two pipelines, oil inlet pipelines of the two check valves 56 on the upper side are communicated with each other and connected to the bottom of the oil tank 16, oil outlet of the two check valves 56 on the, the oil outlet of the hydraulic motor 52 is communicated with the oil tank 16.

Advantageously, the planetary mechanism 200 includes a hydraulic shaft 58 coaxially disposed with the wind power main shaft 57 and rotatably disposed between the hydraulic gear chamber 55 and the planetary chamber 15, the hydraulic motor 52 is provided with a hydraulic driving gear 54 in a downward power fixing manner, the hydraulic driven gear 53 engaged with the hydraulic driving gear 54 is fixedly disposed at the upper end of the hydraulic shaft 58, a hydraulic input bevel gear 64 is fixedly disposed at the lower end of the hydraulic shaft 58, a planetary shaft 59 extending upward and downward is rotatably disposed on the hydraulic shaft 58 in the planetary chamber 15, an output bevel gear 60 is fixedly disposed on the planetary shaft 59, a planetary carrier 67 extending rightward and downward is fixedly disposed on the planetary shaft 59, a planetary bevel gear shaft 66 extending radially relative to the wind power main shaft 57 is rotatably disposed on the planetary carrier 67, and a planetary bevel gear 65 engaged with the hydraulic input bevel gear 64 is fixedly disposed near the axial center of the planetary bevel gear shaft 66, the lower end of the wind power main shaft 57 is fixedly provided with a wind power input bevel gear 63 which is used for meshing the planetary bevel gear 65.

Advantageously, the solar energy opening and closing mechanism 300 comprises a reset main bevel gear 32 in which the wind power main shaft 57 is located in the reset bevel gear cavity 17 and is connectively arranged through a low-speed coupling, a reset secondary bevel gear 18 engaged with the reset main bevel gear 32 is fixedly arranged in the reset bevel gear cavity 17 of the photovoltaic shaft 35, a photoelectric bevel gear 49 is fixedly arranged at the lower end of the photoelectric power shaft 48, a closing shaft 29 extending up and down corresponding to the photoelectric power shaft 48 is rotatably arranged on the circumferential array of the lower end wall of the closing cavity 51, a closing main bevel gear 30 engaged with the photoelectric bevel gear 49 is fixedly arranged at the upper end of the closing shaft 29, an opening and closing gear 28 is fixedly arranged on the closing shaft 29, a closing gear 50 is rotatably arranged in the closing cavity 51 of the wind power main shaft 57, a slide rod cavity 70 with an outward opening is arranged on the circumferential array of the closing cavity 51 of the wind power main shaft 57, a sliding rod 72 is arranged in the sliding rod cavity 70 in a sliding manner, a sliding rod spring 71 is used for connecting the sliding rod 72 and the sliding rod cavity 70, and a friction plate 69 which can be abutted against the inner end wall of the closing gear 50 is fixedly arranged at the end, far away from the axis, of the sliding rod 72.

Advantageously, the wind power generation mechanism 400 includes an upwardly extending wind shaft 38 rotatably disposed at the upper end of the power generation column 61, a wind power body 44 is fixedly disposed at the upper end of the wind shaft 38, a wind power bevel gear cavity 41 is disposed in the wind power body 44, a fan shaft 40 extending left and right is rotatably disposed between the wind power bevel gear cavity 41 and the left end wall of the wind power body 44, a fan blade 39 is fixedly disposed at the left end of the fan shaft 40, a fan bevel gear 42 is fixedly disposed at the right end of the fan shaft 40, the wind power main shaft 57 extends upwardly into the wind power bevel gear cavity 41, and a wind power bevel gear 43 engaged with the fan bevel gear 42 is fixedly disposed at the upper end of the wind power main shaft 57.

The fixing and connecting method in this embodiment includes, but is not limited to, bolting, welding, and the like.

As shown in fig. 1-4, the sequence of mechanical actions of the entire device of the invention:

the working process is as follows: the floating ball 22 is driven by the wave to float up and down to drive the floating frame 20 to rotate up and down reciprocally around the floating support rod 19, so as to drive the piston rod 25 to slide radially and reciprocally, thereby driving the hydraulic motor 52 to rotate, thereby driving the hydraulic driving gear 54 to rotate, thereby driving the hydraulic input bevel gear 64 to rotate, the fan blade 39 is driven by the wind to rotate the fan shaft 40, thereby driving the fan bevel gear 42 to rotate, thereby driving the wind bevel gear 43 to rotate, thereby driving the wind input bevel gear 63 to rotate in the same direction as the hydraulic input bevel gear 64, thereby driving the planet carrier 67 to rotate, thereby driving the output bevel gear 60 to rotate, thereby driving the power generation bevel gear 68 to rotate to generate power to be stored in the storage battery 12.

Solar energy switching process: when the wind force on the sea surface is too high, the rotating speed of the wind power main shaft 57 is increased, and at this time, the reset main bevel gear 32 is disconnected from the wind power main shaft 57, so as to drive the slide rod 72 to slide outwards, thereby driving the friction plate 69 to abut against the closing gear 50 and driving the closing gear 50 to rotate, thereby driving the opening and closing gear 28 to rotate, thereby driving the closing main bevel gear 30 to rotate, thereby driving the photoelectric bevel gear 49 to rotate, thereby driving the worm 37 to rotate, thereby driving the worm wheel 46 to rotate, thereby driving the concave mirror 34 to rotate to press down the photovoltaic panel 31 until the concave mirror 34 is parallel to the power generation post 61, and then the photovoltaic shaft 35 stops rotating under the action of the safety clutch 47, when the wind power is reduced to a safety value, the wind power main shaft 57 is engaged with the reset main bevel gear 32 and drives the reset main bevel gear 32 to rotate, thereby drive concave mirror 34 rotates and will photovoltaic board 31 expandes, concave mirror 34 is parallel with incident ray to when being fifty five degrees with the photovoltaic board, the last reflection ray of concave mirror reflects back photovoltaic board 31, in order to realize the reinforcing utilization to light energy in the unit area.

The above embodiments are merely illustrative of the technical ideas and features of the present invention, and the purpose thereof is to enable those skilled in the art to understand the contents of the present invention and implement the present invention, and not to limit the protection scope of the present invention. All equivalent changes and modifications made according to the spirit of the present invention should be covered within the protection scope of the present invention.