JP7019855B1 - Floating power generator for wind and tide - Google Patents

Abstract

PROBLEM TO BE SOLVED: In wind power generation using a conventional propeller, changing the angle of blades or using a brake is a problem because natural energy is wasted in order to prevent damage when the wind speed exceeds 25 m / s. SOLUTION: In order to prevent the rotation of the horizontal axis connected to the drive blades from exceeding a specified value due to strong wind, a start plate adjusted and equipped to start at a degree of wind speed is provided at the upper part of the wind power generator toward the front. The equipment to be installed is a control generator in which a clutch plate A adjacent to the clutch plate B connected to the side of the peripheral wall of the horizontal axis penetrating from the rear to the outside in the front of the center of the inside of the wind power generator is attached. The clutch plate A, which is linked and equipped with the starting plate and is linked by the activation of the starting plate, is in contact with the clutch plate B, and by connecting the clutch plate A, the control generator and the control generator intervene so as to brake the rotation of the horizontal axis. It is possible to obtain additional power while controlling the rotation of the horizontal axis by adding the load of the gear to be applied. [Selection diagram] Fig. 1

Description

The present invention relates to a joint power generation device in which a wind power generator is attached to the upper part of a box-shaped float and a tidal current power generator is attached to the lower part of the box-shaped float.

In a conventional floating offshore wind power generation system, a floating body is attached to a single mooring body fixed to a fixed body on the seabed, and a generator is rotatably built in the upper part of the tower above the floating body. An offshore wind power generation system that converts energy is arranged, and a tethered stabilizer that receives a sea current and generates a resistance force is arranged at one of the tethers (see, for example, Patent Document 1).

Japanese Patent Application Laid-Open No. 2020-84813

In the conventional floating offshore wind power generation system described above, the floating body attached to one mooring body cannot stop at a fixed position on the sea surface against a strong wind that changes to about 360 degrees at sea, and the tower. And, the configuration that loses energy without thinking that stable and efficient power generation can be obtained by changing the angle of the tether is a problem.

In addition, large-scale wind power generation other than the conventional offshore wind power generation system is configured to detect the wind direction with a sensor and direct the blade direction to the wind direction with a yaw drive device, and the weight of the front blade of the nacelle is the tower. There is a burden of balance on one side of the mounting part. Therefore, it is not possible to install the blade away from the tower because it causes more burden. Also, making the blade heavier is a problem in terms of life.

In addition, it is a big problem that expensive large wind turbines are damaged by strong winds, and the current countermeasures are to adjust the blade angle at a wind speed of around 25 m / s, adjust the brakes for the rotor, and adjust the brakes. Although the rotation of the blade is stopped, this control measure is also a problem because it wastes the energy of strong winds.

The present invention is intended to solve the problems of such a conventional configuration, has a problem-free response and functionality at each location, and efficiently stabilizes the energy of wind power and tidal current. The purpose is to take it in and convert it into lean electricity.

Then, in order to achieve the above object, the present invention has a drive blade attached to a rotatably protruding horizontal shaft that penetrates the center of the inside of the wind power generator to the rear or the outside of the front, and the horizontal shaft inside the inside. A transmission gear is attached to, a generator connected to the transmission gear is arranged on one side of the peripheral wall of the horizontal axis, and a clutch plate B connected to the transmission gear is provided on the other side of the peripheral wall of the horizontal axis. A starter plate adjusted to start at the degree of wind speed is attached to the upper part of the wind power generator, and an adjustment spring interlocked with the starter plate and a control generator are connected to the control generator. A clutch plate A is attached to the shaft, and the clutch plate A interlocked with the activation plate is arranged adjacent to the provided clutch plate B so as to be contactable, and each of the clutch plates A interlocked with the activation plate is connected. The equipped starter plate is provided on the upper part of the wind power generator.

Further, the action of the second problem-solving means is provided by providing a start plate and a start plate A on the upper part of the wind power generator side by side in order to cope with the strongest wind power, and the start plate A is attached on the upper part of the arm. The middle of the arm is attached to the shaft material attached to the upper plate of the upper part of the wind power generator so that the upper and lower parts of the arm move back and forth, and the middle part of the arm is attached to the shaft material, and the lower part of the arm is the wind power generator. It is attached to the trolley located inside.

Further, the adjustment spring connected to the fixed portion at the rear of the bogie with the roller is connected to the bogie, the control generator B is placed on the bogie, and the clutch plate C is attached to the shaft of the control generator B. , A starter plate A equipped so that the clutch plate C is interlocked with the starter of the starter plate A that is started by adjusting the adjustment spring that connects each is provided.

Further, the clutch plate C is contactably adjacent to the clutch plate D attached to the rear shaft of the generator connected to one side of the peripheral wall of the horizontal axis arranged in the center of the inside of the wind power generator. The clutch plate C is placed.

Further, by adjusting the adjustment spring that is connected so as to start with strong wind power, the clutch plate C that is interlocked by the activation of the activation plate A that is activated is interlocked, and by contacting and connecting with the clutch plate D, the control generator is connected. The addition to rotate the axis B is transmitted from the connected generator to the rotation of the horizontal axis, and the control is to suppress the rotation speed of the horizontal axis, while the generated power is obtained by the rotation of the axis of the control generator B. I can.

Further, in the third problem-solving means, the state of the tidal current power generator when the direction of the flow at the time of commutation due to the tidal current changes is the vertical tail wing behind the tidal current power generator and the box-shaped float with respect to the flowing direction. The rotation of the rotating suspension rod at the bottom of the material positions the front of the tidal current generator in the direction of flow, enabling normal power generation of the tidal current generator.

As described above, the floating wind power generation device for wind power and tidal current of the present invention is a combination of a wind power generator and a tidal current power generator, and when arranged in a tidal current, an ocean current, or a water current even when there is no wind, It is possible to always obtain power generation.

In addition, by equipping the upper part of the wind power generator with a starter plate that has been equipped and adjusted, and a starter plate A, the rotation speed of the horizontal axis is controlled when the rotation speed of the horizontal axis is too fast in the change from weak wind to strong wind, and the rotation is not hindered. It is possible to cope with the speed of wind power, and it is possible to provide the result of converting wind energy into electricity with less waste.

In addition, the starting plate that receives wind power and is activated by its action, and the activation plate A can be adjusted according to the wind speed by changing the size of both starting plates and the strength of the elasticity of the equipped spring. ..

In front of the wind power generator, a first element that rotates in the same direction attached to the horizontal axis and a drive blade with a support material attached to the peripheral wall of the second element are suitable for rotation by receiving wind. The drive blades of the first element and the second element, which are erected in a rectangular manner at an angle, are arranged alternately on the horizontal axis, and the plurality of drive blades are mounted on the horizontal axis. With the center of the circle as the fulcrum, the area that receives the wind is increased as the distance from the fulcrum increases, so that the rotational force of the horizontal axis has a high rate.

In addition, centering on the locking part provided in the upper center of the front and back of the tidal current power generator, the balance between the front and back is preliminarily adjusted to the third water tank part and the fourth water tank part behind the inside of the tidal current power generator. Stable by pouring water from the water supply port and equipping it in a balanced manner, connecting the locking part to the hanging plate from the rotating hanging rod at the bottom of the box-shaped floating material, and arranging the tidal current generator in the tidal current. Power generation is possible.

The part that can be attached to and removed from the floating power generator for wind power and tidal current is the cylinder provided at the lower part of the wind power generator in the shaft hole of the bearing that is fixed vertically to the upper plate and the disk. Insert the holes formed in the 2nd and 1st elements into the part that can be attached and detached by inserting the lower part of the vertical axis and the groove of the horizontal axis that protrudes in front of the wind turbine. Then, in the bolt hole formed in the center of the front of the first element part, the part that can be attached and detached with screw bolts, and the four-sided support plate of the iron tower type are attached to the bolt protruding above the box-shaped floating material. It has a part that can be attached and detached with a nut, and a hanging plate from a rotating hanging rod attached to the lower part of the box-shaped floating material, and bolts and nuts to the locking part at the top of the tidal current generator. There is a part that can be freely attached and detached, and by being able to freely attach and detach the above-mentioned part, it is possible to easily install and replace the damaged part, and it is possible to reduce the cost.

In addition, depending on the condition of the installation location, it is possible to install by removing one from the box-shaped float.

In addition, when the wind power generator is removed from the box-shaped float, it is possible to install the removed wind power generator on land to generate electricity.

The side view which shows the embodiment of this invention. The front view which shows the embodiment of this invention. FIG. 5 is a partial cross-sectional view taken along line BB in FIG. 5 showing one side surface inside the wind power generator. A plan view showing the inside of a wind turbine. FIG. 1 is a partial cross-sectional view taken along line AA in FIG. 1 showing a front portion of a wind power generator. FIG. 1 is a sectional view taken along line CC in FIG. 1 showing a cylindrical vertical side surface. Front view showing the front surface of the drive blades receiving the wind. Rear view showing the rear surface of the drive blade. FIG. 1 is a sectional view taken along line DD in FIG. 1 showing the center of a tidal current generator from a box-shaped float. FIG. 1 is a sectional view taken along line EE in FIG. 1 showing the inside of a tidal current power generator. FIG. 5 is a partial cross-sectional view taken along the line FF in FIG. 5 showing one side surface inside the wind power generator. A cross-sectional view showing a V-shaped shape in which the drive blade is cut from the middle.

Hereinafter, embodiments of the present invention will be described with reference to FIGS. 1 to 12.

Then, as shown in FIGS. 1 to 2, a plurality of rope-shaped 33s connected to the fixing material 34 fixed to the seabed 2 are attached around the box-shaped floating material 31 floating on the sea surface and fixed to the sea surface. As you can see, the box-shaped float 31 is provided.

Further, on the upper part of the box-shaped float 31, the tower type 26 has four columns 26a, and the lower end column base plate 26c assembled by the brace 26b is a bolt on the inner side of the outer plate 31b of the box-type float 31. The column base plate 26c is attached to the bolt 9 and nut 9a through the hole 9b through the top plate 32 and the column base plate 26c, and the tower type 26 is erected on the sea X.

In addition, the upper plate 27, the cylinder 29, and the disk 30 are stacked and fixedly attached to the upper part of the tower type 26.

In addition, the stacked upper plates 27 and the bearing 4 into which the tubular vertical axis 23 is inserted are vertically fixed and attached to the center of the upper surface of the disk 30.

In addition, the upper part of the tubular vertical axis 23 is fixed to the lower part of the box body 1a, which is a part of the wind power generator 1, and the lower part is vertically lowered and attached.

Further, as shown in FIG. 6, a wiring 22a for generated electric power is provided in a through hole inside the tubular vertical shaft 23, and the end of the wiring 22a protrudes from the lower tip of the tubular vertical shaft 23 and rotates. A cylindrical vertical axis 23 to which a connector type 24 is attached is provided.

Further, around the area where the tubular vertical axis 23 is vertically attached to the lower portion of the box body 1a, the upper part of the plurality of caster-shaped 25s is placed on the upper surface of the disk 30 arranged below the box body 1a. It is fixedly attached to the lower side.

Further, the lower end of the cylindrical vertical shaft 23 is inserted into the shaft hole 4a of the two bearings 4 vertically attached to the disk 30 and the upper plate 27, and the rotary connector type 24 portion penetrates from the lower surface of the upper plate 27. At the position, the cylindrical vertical shaft 23 is stopped at a position where the upper portion is thickened so as to stop, and the stop position and the plurality of caster-shaped 25s on the lower side surface of the other box body 1a form the upper surface of the disk 30. The wind power generator 1 is rotatably supported by the caster-shaped 25 around the cylindrical vertical axis 23 by being stopped together.

Further, the transmission board 28 having the contact plate 28a and the power transmission wiring 28b in contact with the contact board 24a of the rotary connector type 24 is brought into contact with the contact plate 28a, and the transmission board 28 is provided on the lower side surface of the upper plate 27. It is.

In addition, by providing this rotary connector type 24, the generated wiring 22a will be transmitted to the fixed power transmission wiring 28b so as not to interfere with the rotation of the wind power generator 1.

In addition, a vertical stabilizer 2 with a cylindrical 2a attached to the rear end including the upper part or the lower part where the rear of the box body 1a is extended is erected, and a lightning rod 2b is attached to the upper end of the cylindrical 2a.

Further, the horizontal shaft 3 has a bearing 4 and a shaft seal ring 4b parallel to the bottom surface from the rear to the front in the center of the inside of the box body 1a, and has a round bar-shaped horizontal shaft protruding outward through the front. 3 is provided so that it can rotate.

Further, a bolt hole 9b for attaching a screw bolt 9 is formed at the center of the tip of the horizontal shaft 3 so that the second element portion 6 and the first element portion 5 can be attached and detached to the horizontal shaft 3 protruding outward. A concave 3a groove is formed in parallel at two positions on the peripheral wall that bisects the circle of the horizontal axis 3 on the protruding part of the horizontal axis 3.

In addition, there is a hole that penetrates the center of the circle of the second base portion 6 of the tubular tube that is first attached to the horizontal shaft 3 having a groove from the rear 6b to the front 6a so as to match the horizontal shaft 3, and a concave shape 3a inside the hole. A protrusion of a convex 6c is formed according to the above, and the drive blade 7 has an erection angle on the peripheral wall of the second element 6 which is inserted and attached from the rear 6b of the second element 6 from the tip of the horizontal axis 3. Within 20-30 degrees, the width of the drive blade 7 at a position away from the second element 6 is widened, and the drive blade 7 to which the support member 8 is attached from the rear surface 7b of the drive blade 7 to the second element 6 shoots in a horizontal direction. A plurality of second element parts 6 erected in a shape are inserted into the horizontal axis 3 from the rear 6b and attached.

Further, a hole and a hole that can be inserted into the horizontal axis 3 by leaving the center of the circle of the first element 5 attached after the second element 6 attached to the horizontal axis 3 from the rear 5e to the front side of the front 5d. The position formed on the protrusion of the convex 6c that matches the groove of the concave 3a on the inside is located between the plurality of drive blades 7 of the second element 6 attached to the horizontal axis 3, and the first element is located. At the position where the drive blade 5a of 5 is positioned, a convex 5F is formed inside the hole, and the convex 5F is inserted into the horizontal axis 3 from the rear of the first element 5 and the central bolt hole 9b on the front side of the front 5d. Bolt 9 can be attached and removed from the inside to the screw bolt hole at the tip of the horizontal shaft 3.

Further, the configuration of this portion is such that the plurality of drive blades 7 of the second element 6 and the plurality of drive blades 5a of the first element 5 are alternately facing forward on the horizontal axis 3 and can be attached and detached side by side. It has been.

Further, the generator 12 connected to the shaft of the small speed change gear 10b meshed with the speed change gear 10 attached to one side of the peripheral wall of the horizontal shaft 3 rotatably arranged from the rear to the center of the front inside the box body 1a. And, the clutch plates D and 12a are attached to the rear shaft of the generator 12.

Further, as shown in FIG. 11, the middle of the arm 18a in which the starting plates A and 18 activated at the wind speed are attached to the upper part of the arm 18a in the forward direction on the upper part of the box body 1a is attached to the shaft member 18b of the upper plate 1b. The upper part and the lower part of the 18a are attached so as to move back and forth, and the lower part of the arm 18a is arranged inside. The adjustment spring 20 is connected to the rear part of the trolley 21, the control generators B and 19 are placed on the trolley 21, and the clutch plates C and 19b are attached to the shafts of the control generators B and 19 to attach the respective. The clutch plates C and 19b are interlocked by the activation of the start plates A and 18 equipped in connection with each other, and the clutch plates C and 19b are arranged adjacent to the clutch plates D and 12a provided so as to be contactable. 18 is provided on the upper part of the box body 1a by adjusting the adjustment spring 20.

Further, as shown in FIG. 3, clutch plates B and 11 are attached to the shaft of the small transmission gear 10c that meshes with the transmission gear 10 on the other side from the peripheral wall of the internal horizontal shaft 3.

Further, on the upper part of the box body 1a, a rope 14 connected to a start plate 13 activated by a wind force is placed on a carriage 16 with a roller 21a, which is arranged inside through a slide wheel 14a attached to the upper plate 1b. The adjustment spring 17 connected to the machine 15 and attached to the fixed portion 17a at the rear of the bogie 16 is connected to the rear part of the bogie 16, and the clutch plate A15b is attached to the shaft 15a of the control generator on the bogie 16. The auxiliary starting plate 13 equipped with the arrangement of the clutch plates A and 15b and the adjustment spring 17 adjusted so as to be in contact with the clutch plate B11 is placed forward on the upper part of the box body 1a. It is prepared.

Further, the adjustment spring 17 equipped in advance and the sizes of the start plate 13 and the start plates A and 18 are adjusted in advance so as to correspond to the desired wind speed, and the start plates 1a are arranged side by side on the upper part of the box body 1a. is needed.

In addition, the configuration described above is a configuration in which a steel tower type 26 and a wind power generator 1 are provided above the box-type floating material 31.

Further, a holding material 35 is attached to the lower side surface of the box-shaped floating material 31, a hole penetrating the bottom plate is provided in the center thereof, and a long round bar-shaped rotary suspension formed in a retaining portion is provided on the upper side through the hole. The rod 36 has a waterproof means for the bearing 4 and the seal ring 4c at a distance from the inside of the hole, and a bifurcated notch is formed from the middle of vertically descending vertically from the holding material 35 to the lower tip. A rotary suspension rod 36, in which a bolt hole 9b is formed so as to intersect with the above, is rotatably provided.

Further, a suspension plate 37 having a matching thickness is provided in the bifurcated notch of the rotary suspension rod 36, and the upper portion thereof is inserted to form a bolt hole 9b matching the bifurcated bolt hole 9b. In the lower part of the suspension plate 37, a bolt hole 9b matching the bolt hole 9b of the locking portion 40 attached to the upper part of the tidal current generator 38 arranged below is formed in the lower part of the suspension plate 37, and the suspension plate 37 is provided. ..

Further, the upper portion of the suspension plate 37 is inserted into the bifurcated notch of the rotary suspension rod 36 with a bolt 9 and a nut 9a, and the lower portion of the suspension plate 37 is aligned with the bolt hole 9b of the locking portion 40 to match the bolt 9 and the nut. By attaching with 9a, the tidal current generator 38 is rotatably connected to the lower part of the box-shaped floating material 31 around the rotary suspension rod 36.

In addition, a vertical stabilizer 39 that faces forward in the direction of ocean current is erected above the rear end of the tidal current generator 38.

Further, as shown in FIG. 10, the inside of the long tubular 39a of the current power generator 38 is a partition wall 41, which is a first space portion 42, a second space portion 43, a third water tank portion 44, and a fourth water tank portion 45. It is divided into and provided.

Further, a speed increaser 50 is arranged in the first space portion 42 inside, a generator 51 and a condenser 52 are arranged in the second space portion, and a rotary connector-like 55 is arranged at the bottom, and the upper surface plate of the third water tank portion 44 is arranged. A water supply cap 44a for supplying water is provided on the outside, and a communication hole 44b communicating with a wall 41 partitioning between the third water tank portion 44 and the fourth water tank portion 45 is provided on the bottom plate of the fourth water tank portion 45. , A drainage port 45a for draining water and a drainage cap 45b on the outside are provided.

Further, before installing the tidal current power generator 38, water is poured from the water supply port cap 44a of the third water tank 44, and the third water tank portion 44 and the third water tank portion 44 are used to balance the front and rear around the upper locking portion 40. , The 4th water tank part 45 is provided.

Further, in front of the tidal current generator 38, a speed increaser 50 arranged inside and a horizontal shaft 46 connected to the shaft of the generator 51 have a bearing 4 and a sealing ring 4c waterproof means in the front. A horizontal axis 46 that penetrates the outside of the front and protrudes long forward is rotatably provided.

Further, a hole that can be inserted into the horizontal shaft 46 formed in parallel with two concave grooves 46a in the longitudinal direction from the tip at the position of the peripheral wall so as to divide the circle of the round bar-shaped horizontal shaft 46 into two equal parts. A support member 49b is provided on the peripheral walls of the first element portion 47 and the second element portion 48 in which a convex protrusion that can be fitted into the concave shape 46a and slides is formed in the inner portion of the hole, and the drive blade 49 is provided. The configuration in which the first element portion 47 and the second element portion 48 are mounted side by side on the horizontal axis 46, which are erected in a plurality of directions, is the first on the horizontal axis 3 protruding in front of the wind power generator 1 described above. It is exactly the same as the configuration in which the 1st element 5 and the 2nd element 6 are installed side by side.

Further, the wiring connected from the generator 51 inside the tidal current generator 38 to the condenser 52 is connected to the rotary connector-shaped 55 at the bottom, and the hole 53a reaching the lower part of the rotary connector-shaped 55 is below the tidal current generator 38. It is provided in the center of the holding member 53 attached to the side.

Further, the upper end of the cylindrical 54 attached to the inside of the through hole 53a of the holding member 53 is formed to prevent the cylinder 54 from coming off, and the bearing 4 and the seal ring 4c are waterproofed between the inside of the hole 53a and the peripheral wall of the cylinder 54. With the means, the tubular 54 is rotatably attached, slightly below the lower end of the holding member 53.

Further, the end of the power transmission wiring 56 is inserted from the lower end of the hollowed-out hole inside the cylindrical 54, and the contact plate 56 is attached to the end, and the contact plate 56 is brought into contact with the rotary connector-like 55 on the inner side. The board 55a has a waterproof means such as grease between the peripheral wall of the power transmission wiring 56 in which the contact plate 56 is in contact with the through hole of the cylindrical 54, and the power transmission is fixed in close contact with the board 55a. Wiring 56 is located below the cylinder 54.

Further, by providing the rotating connector 55 with respect to the rotating tidal current power generator 38, the generated electric power can be generated in a state where the power transmission wiring 56 attached to the rotatable tubular 54 is fixed. It is transmitted and can be placed without any trouble such as twisting of the power transmission wiring 56.

In addition, the power transmission wiring 56 and the power transmission wiring 28b from the transmission board 28 are combined into one and connected to the power receiving equipment on land from the seabed Z so that the generated power can be transmitted.

1 ... Wind generator 5b ... Front 1a ... Box 5c ... Rear 1b ... Upper plate 5d ... Front 2 ... Vertical tail 5e ... Rear 2a ... Cylindrical 5F ... Convex 2b ... Lightning needle 6 ... Second element 3 ... Horizontal axis 6a ... Front 3a ... Concave 6b ... Rear 4 ... Bearing 6c ・ ・ ・ Convex 4a ・ ・ ・ Shaft hole 7 ・ ・ ・ ・ Drive blade 4b ・ ・ ・ Shaft seal 7a ・ ・ ・ Front surface 4c ・ ・ ・ Seal link 7b ・ ・ ・ Rear surface 5 ・ ・ ・ ・ First base 8 ... Support material 5a ... Drive blade 8a ... Rubber packing 9 ... Bolt 34 ... Fixed part 9a ... Nut 35 ... Holding material 9b ... Bolt Hole 35a ... Injection port cap 10 ... Speed gear 36 ... Rotating suspension rod 10a ... Shaft 37 ... Suspension plate 10b ... Small speed change gear 37a ... Bolt hole 10c ... Small speed change Gear 38 ... Power flow generator 11 ... Clutch plate B 39 ... Vertical tail wing 12 ... Generator 39a ... Cylindrical 12a ... Clutch plate D 40 ... Locking part 13・ ・ ・ Starting plate 41 ・ ・ ・ ・ Partition wall 14 ・ ・ ・ Rope 41a ・ ・ ・ Outer wall 14a ・ ・ ・ Slider 42 ・ ・ ・ ・ First space 15 ・ ・ ・ Control generator 43 ・ ・ ・ ・ Second space Part 15a ... Control generator shaft 44 ... Third water tank part 15b ... Clutch plate A 44a ... Water supply port cap 16 ... Carriage 44b ... Communication hole 17 ... Adjustment spring 45 ...・ ・ ・ 4th water tank part 17a ・ ・ Fixed part 45a ・ ・ ・ Drain port 18 ・ ・ ・ Starting plate A 45b ・ ・ ・ Drain port cap 18a ・ ・ Arm 46 ・ ・ ・ ・ Horizontal axis 18b ・ ・ Shaft material 46a ・・ ・ Concave 19 ・ ・ ・ Control generator B 47 ・ ・ ・ ・ First element 19a ・ ・ Shaft of control generator B 48 ・ ・ ・ ・ Second element 19b ・ ・ Clutch plate C 49 ・ ・ ・ ・ Drive Blade 20 ... Adjustment spring 49b ... Support material 20a ... Fixed part 50 ... Accelerator 21 ... Carter 51 ... Generator 21a ... Roller 52 ... Condenser 22 ...・ ・ Condenser 53 ・ ・ ・ ・ Holding member 22a ・ ・ Wiring 53a ・ ・ ・ Hole 23 ・ ・ ・ Cylindrical vertical axis 54 ・ ・ ・ ・ Cylindrical 24 ・ ・ ・ Rotating connector type 55 ・ ・ ・ ・ Rotating connector 24a・ ・ Contact board 55a ・ ・ ・ Contact board 25 ・ ・ ・ Caster shape 56 ・ ・ ・ ・ Transmission wiring 26 ・ ・ ・ Iron tower type 56a ・ ・ ・ Contact plate 26a ・ ・ Support 57 ・ ・ ・ ・ Sea surface 26b ・ ・ Line R: Rotation direction 26c ・・ Support base plate X ・ ・ ・ ・ ・ Top 27 ・ ・ ・ Upper plate Y ・ ・ ・ Underwater 28 ・ ・ ・ Transmission board Z ・ ・ ・ Seabed 28a ・ ・ Contact plate 28b ・ ・ Transmission wiring 29 ・ ・・ Cylinder 30 ・ ・ ・ Disk 31 ・ ・ ・ Box-shaped float 31a ・ ・ Support column 31b ・ ・ Outer plate 32 ・ ・ ・ Top plate 33 ・ ・ ・ Rope shape

Claims (5)

Drive vanes are attached to a rotatably protruding horizontal axis that penetrates the center of the interior of the wind turbine from the rear to the outside.
A transmission gear is attached to the horizontal axis inside the inside,
A generator connected to the transmission gear is arranged on one side of the peripheral wall of the horizontal axis.
A clutch plate B connected to the transmission gear is provided on the other side of the peripheral wall of the horizontal axis.
A starter plate adjusted to start at the degree of wind speed is attached to the upper part of the wind power generator.
The adjustment spring linked to the starting plate and the control generator are connected,
A clutch plate A is attached to the shaft of the control generator, and the clutch plate A is attached.
The clutch plate A interlocked with the starting plate is arranged adjacent to the provided clutch plate B so as to be in contact with the clutch plate A.
The starter plate, which is equipped by connecting each of the starter plates linked to the starter plate, is provided and provided on the upper part of the wind power generator.
A rope connected to the starting plate at the top of the wind power generator is connected to the control generator mounted on a carriage inside the wind power generator through a pulley attached to the upper plate.
The adjusting spring from the fixed portion at the rear of the dolly is connected to the dolly.
A floating power generation device for wind power and tidal current, characterized in that the starting plate of an auxiliary role equipped so as to connect and interlock the clutch plate A to the shaft of the control generator is provided. The clutch plate A and the clutch plate B are interlocked so that the start plate is started at a wind speed of 20 m / s by adjusting the adjustment spring or the like in advance so that the rotation of the horizontal axis does not exceed the specified value. The starter plate, which is controlled by the rotational addition of the transmission gear and the shaft of the control generator and is equipped to be converted into electricity, is directed forward toward the upper part of the wind power generator. The floating power generation device for wind power and tidal current according to claim 1, wherein the power generation device is provided. The drive blades have a widened width between a first element portion that can be attached and detached and a portion away from the peripheral wall of the second element portion in a portion where the horizontal axis penetrates and protrudes from the front outside of the wind power generator. The floating power generation device for wind power and tidal current according to claim 1 or 2, wherein a support member is attached to the rear surface of each of the drive blades, which are erected in a horizontal manner. It is characterized in that it is located on the upper surface of a disk fixed to the upper end of a steel tower below the wind power generator, and a caster-shaped upper portion is fixed to the lower side surface of the wind power generator, and a plurality of them are attached. The floating power generation device for wind power and tidal current according to any one of claims 1-3. A holding material is attached to the lower part of the box-shaped floating material, and the rotating suspension is provided with a waterproof means for the bearing and the seal ring between the inside of the hole through which the holding material is penetrated and the peripheral wall of the rotating suspension rod. The floating power generation device for wind power and tidal current according to any one of claims 1 to 4, wherein the rod is rotatably provided so as to protrude downward from the holding material.

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