CN113623124B - Floating type offshore power generation equipment - Google Patents

Abstract

The invention provides a floating type offshore power generation device, which relates to the technical field of offshore power generation and comprises a power generation device mounting plate, wherein two float rotating plates for mounting float mounting seats are fixedly mounted at one end of the upper surface of the power generation device mounting plate; this scheme is through rotating the cursory mount pad of installation and the cursory subassembly on it between two cursory rotor plates on power generating equipment mounting panel upper end surface, set up helping hand board at helping hand board fixing base internal rotation, the current conversion hole rivers that pass through both sides flow, promote helping hand board to both sides slope to increase cursory subassembly's inclination through the balancing weight, increase the conversion efficiency of potential energy, in order to avoid main cursory because buoyancy rotates certain angle after, unable dive, influence conversion efficiency.

Description

Floating type offshore power generation equipment

Technical Field

The invention relates to the technical field of offshore power generation, in particular to floating offshore power generation equipment.

Background

The traditional energy is gradually exhausted, the problem of environmental pollution is worsened, and the development of new energy is imminent. With the development of low-power consumption wireless sensors, environmental clean renewable energy sources such as solar energy, wind energy and wave energy are used for generating electricity to form a micro power supply to provide electric energy for sensor nodes, and the micro power supply is increasingly and widely concerned by various fields. Compared with wind energy and solar energy technologies, the wave energy power generation technology lags behind for more than ten years. However, the wave energy has the unique advantages that the energy density of the wave energy is high and is 4-30 times of that of wind energy, and compared with solar energy, the wave energy is not influenced by weather. The wave power generation power supply is a power supply manufactured by utilizing wave power generation.

However, in the existing wave and tide power generation, the waves are close to the middle and far sea areas, although the waves look larger in the far sea area, the horizontal potential energy of the waves is the largest when arriving at the offshore shore, the impact force is not enough, the potential energy collection of the power generation equipment to the waves is not centralized and complete, the potential energy is always lost, and the power generation efficiency is not high.

Disclosure of Invention

Technical problem to be solved

Aiming at the defects of the prior art, the invention provides a floating type offshore power generation device, which solves the problems that the impact force is the largest when the horizontal potential energy of the sea wave is far from the offshore shore, the potential energy is not centralized and completely collected by the existing power generation device, the potential energy is always lost, and the power generation efficiency is not high.

(II) technical scheme

In order to achieve the purpose, the invention is realized by the following technical scheme: a floating type offshore power generation device comprises a power generation device mounting plate, wherein two floating rotary plates for mounting a floating mounting seat are fixedly mounted at one end of the upper surface of the power generation device mounting plate, a floating mounting seat is rotatably mounted between the two floating rotary plates, a floating assembly is fixedly mounted at the upper end of the floating mounting seat, a plurality of balance floats are fixedly mounted on the side surface of the upper end of the floating assembly, the lower end of the floating mounting seat is fixedly connected with a limiting steel cable and is fixedly connected with the upper surface of the power generation device mounting plate, two ends of a rotary shaft of the floating mounting seat are fixedly connected with floating connecting plates, two hydraulic cylinder rotary shafts are fixedly connected with the outer side surface of the upper end of the two floating connecting plates, two hydraulic cylinders are respectively rotatably mounted on the two hydraulic cylinder rotary shafts, and are respectively rotatably mounted on the two side surfaces of a hydraulic converter through two hydraulic cylinder rotary angle irons, the hydraulic converter is fixedly installed on the surface above the power generation equipment installation plate and located on one side of the floating rotation plate, and a rotating magnetic induction assembly is fixedly installed on one side, away from the floating rotation plate, of the hydraulic converter.

Preferably, the float assembly comprises: rocking cylinder shell, trades discharge orifice, main cursory, warning light controller, helping hand board fixing base, helping hand board and balancing weight, rocking cylinder shell fixed mounting is on cursory mount pad upper end surface, rocking cylinder shell upper end integration fixedly connected with main cursory, a plurality of discharge orifices have been seted up respectively to rocking cylinder shell side both ends, be provided with confined space in the main cursory.

Preferably, a warning lamp controller is fixedly mounted at the upper end inside the main buoy, a plurality of warning lamps are electrically mounted on the warning lamp controller, the top of each warning lamp controller extends out of the main buoy, a booster plate fixing seat is fixedly mounted on the surface of the upper end of the inner wall of the bottom end of the rocking cylinder shell, a booster plate is rotatably mounted at the upper end of the booster plate fixing seat, a balancing weight is fixedly mounted in the middle of the booster plate, and the booster plate fixing seat is perpendicular to the connecting line of the converter holes on the two sides.

Preferably, the hydraulic cylinder includes: hydraulic pressure section of thick bamboo shell, induction tube, hydraulic pressure connecting rod, slip oil blanket and hydraulic piston, hydraulic pressure section of thick bamboo shell rear end one side fixed connection hydraulic pressure section of thick bamboo rotates the angle bar, hydraulic pressure section of thick bamboo shell head end fixed mounting has the slip oil blanket, it has hydraulic pressure connecting rod and to the inside hydraulic pressure section of thick bamboo shell to slide to alternate in the slip oil blanket, the fixed intercommunication in hydraulic pressure section of thick bamboo shell upper end has the induction tube, the flexible pipe of induction tube rear end fixedly connected with, the hydraulic pressure connecting rod is located the inside one end fixedly connected with hydraulic piston of hydraulic pressure section of thick bamboo shell, just hydraulic pressure piston and hydraulic pressure section of thick bamboo shell in close contact with, the hydraulic pressure connecting rod other end rotates and installs on the hydraulic pressure section of thick bamboo rotation axis.

Preferably, the hydraulic converter includes: the converter comprises a converter shell, telescopic pipe connecting holes, a transfer passage, a transfer cabin, a driving cabin connecting hole, a driving cabin, a driving rod and a driving rod piston, wherein the upper end of the converter shell is provided with two telescopic pipe connecting holes which are respectively communicated with telescopic pipes, and the lower ends of the two telescopic pipe connecting holes are communicated with the transfer passage.

Preferably, the rear ends of the two transfer channels are respectively communicated with a transfer cabin, the inner walls of the front ends of the two transfer cabins are respectively communicated with a driving cabin through a driving cabin connecting hole, a driving rod piston is closely and slidably mounted in the driving cabin, and a driving rod is fixedly connected to one side, away from the driving cabin connecting hole, of the driving rod piston.

Preferably, the rotary magnetic induction assembly includes: rotatory magnetic induction subassembly shell, subassembly back plate, wire tie point, carousel, No. two carousels, driving belt, drive tooth's socket, drive rack, strong magnet, copper pole rotation axis, electrically conductive copper pole, response bar copper, brush rotation axis and electrically conductive brush, rotatory magnetic induction subassembly shell rear end integration fixedly connected with subassembly back plate.

Preferably, the assembly rear plate is respectively rotatably provided with a first rotary plate and a second rotary plate, the first rotary plate and the second rotary plate are rotatably connected through a transmission belt, a driving tooth groove is formed in the middle end of a shaft body of the second rotary plate, the lower end of the driving tooth groove is meshed with a driving rack, and one end of the driving rack is fixed and is fixedly connected with the driving rod.

Preferably, the coaxial integration fixedly connected with copper pole rotation axis in carousel rear end, the front end fixedly connected with of copper pole rotation axis electrically conducts the copper pole, electrically conducts the copper pole and keeps away from two response bar copper of a side surface both ends difference fixedly connected with of copper pole rotation axis, two the response bar copper rotates and sets up between two strong magnets, two equal fixed mounting of strong magnet is on rotatory magnetism and feels subassembly shell both ends inner wall.

Preferably, the front ends of the two induction copper bars are fixedly connected with a conductive copper rod, an electric brush rotating shaft is fixedly connected in the middle of the front side surface of the conductive copper rod, two conductive electric brushes are fixedly connected to two sides of the electric brush rotating shaft respectively, a wire connecting point is arranged at the rear ends of the two conductive electric brushes, the wire connecting point is electrically connected with a transmission wire, and the two conductive electric brushes are in sliding contact with the surface of one side of the wire connecting point.

(III) advantageous effects

The invention provides floating offshore power generation equipment. The method has the following beneficial effects:

according to the scheme, the buoy installation seat and the buoy assembly on the buoy installation seat are rotatably installed between the two buoy rotation plates on the upper end surface of the power generation equipment installation plate, the potential energy impacted by a wave tide is converted through the main buoy in the buoy installation seat to be converted into the rotating power of the main buoy rotating through the rotating shaft of the buoy installation seat, the two hydraulic cylinders are pushed to synchronously rotate through the buoy connection plate, the equipment is installed offshore, ships have a large number of people and are provided with warning lamps to warn people and ships to prevent accidental touch and damage the equipment, the booster plate is rotatably arranged in the booster plate fixing seat, water flows through the converter holes on the two sides to push the booster plate to incline towards the two sides, the inclination angle of the buoy assembly is increased through the balancing weight, and the conversion efficiency of the potential energy is improved, the problem that the main buoy cannot submerge after rotating to a certain angle due to buoyancy and the conversion efficiency is influenced is solved;

then, a hydraulic piston is pushed through a hydraulic connecting rod in the hydraulic cylinder, hydraulic liquid in the hydraulic piston flows in an inlet pipe, potential energy is converted into a hydraulic converter through a hydraulic principle, the potential energy is converted into driving cabin through a transfer passage, a transfer cabin and a driving cabin connecting hole again, the potential energy is converted into power for horizontally and stably traversing a driving rod, and a driving rack in a rotary magnetic induction assembly is driven to be meshed with a driving tooth groove to rotate, so that the first rotary disk can be driven to rotate through a transmission belt and a copper rod rotating shaft at the rear end is driven to rotate.

Drawings

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

FIG. 2 is a schematic structural view of the float assembly of the present invention;

FIG. 3 is a schematic front view of the float assembly of the present invention;

FIG. 4 is a schematic cross-sectional view taken along line a-a of FIG. 3 according to the present invention;

FIG. 5 is a schematic diagram of a hydraulic cylinder according to the present invention;

FIG. 6 is a schematic side view of a hydraulic cylinder according to the present invention;

FIG. 7 is a cross-sectional view taken along line b-b of FIG. 6 according to the present invention;

FIG. 8 is a schematic diagram of a hydraulic converter according to the present invention;

FIG. 9 is a schematic diagram of a front view of a hydraulic converter according to the present invention;

FIG. 10 is a cross-sectional view taken along line c-c of FIG. 9 according to the present invention;

FIG. 11 is a cross-sectional view taken along line d-d of FIG. 9 according to the present invention;

FIG. 12 is a schematic view of the overall structure of the rotary magnetic induction assembly according to the present invention;

FIG. 13 is a schematic view of a rotary magnetic induction assembly of the present invention;

FIG. 14 is a side view of the rotary magnetic sensor assembly of the present invention;

FIG. 15 is a schematic cross-sectional view taken along line e-e of FIG. 14 according to the present invention.

Wherein, 1, a power generating equipment mounting plate; 2. a floating rotating plate; 3. a float mounting seat; 4. a float assembly; 401. a swing drum housing; 402. an air exchange hole; 403. a main buoy; 404. a warning light; 405. a warning light controller; 406. a power assisting plate fixing seat; 407. a booster plate; 408. a balancing weight; 5. a hydraulic cylinder rotating shaft; 6. a hydraulic cylinder; 601. a hydraulic cylinder housing; 602. an introducing pipe; 603. a hydraulic link; 604. sliding oil seal; 605. a hydraulic piston; 7. a hydraulic converter; 701. a converter housing; 702. the extension tube is connected with the hole; 703. a transfer lane; 704. a transfer chamber; 705. a drive compartment connection hole; 706. a drive bay; 707. a drive rod; 708. a drive rod piston; 8. a rotating magnetic induction assembly; 801. a rotating magnetic induction assembly housing; 802. a module back plate; 803. a wire connection point; 804. a first turntable; 805. a second turntable; 806. a drive belt; 807. a drive gullet; 808. a drive rack; 809. a strong magnet; 810. a copper rod rotating shaft; 811. a conductive copper rod; 812. sensing a copper bar; 813. an electric brush rotating shaft; 814. a conductive brush; 9. a limiting steel cable; 10. a floating connecting plate; 11. a telescopic pipe; 12. rotating angle iron of the hydraulic cylinder; 13. balancing and floating; 14. an electrical power transmission conductor.

Detailed Description

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

Example (b):

as shown in FIGS. 1-15, the embodiment of the invention provides a floating type offshore power generation device, which comprises a power generation device mounting plate 1, wherein one end of the upper surface of the power generation device mounting plate 1 is fixedly provided with two float rotating plates 2 for mounting a float mounting seat 3, a float mounting seat 3 is rotatably mounted between the two float rotating plates 2, a float assembly 4 is fixedly mounted at the upper end of the float mounting seat 3, the side surface of the upper end of the float assembly is fixedly provided with a plurality of balance floats 13, the lower end of the float mounting seat 3 is fixedly connected with a limiting steel cable 9 and is fixedly connected with the upper surface of the power generation device mounting plate 1, two ends of a rotating shaft of the float mounting seat 3 are fixedly connected with float connecting plates 10, the outer side surfaces of the upper ends of the two float connecting plates 10 are fixedly connected with two hydraulic cylinder rotating shafts 5, and two hydraulic cylinders 6 are rotatably mounted on the two hydraulic cylinder rotating shafts 5 respectively, two hydraulic pressure section of thick bamboo 6 rotates through two hydraulic pressure section of thick bamboo rotation angle bar 12 respectively and installs at hydraulic pressure converter 7 both sides surface, hydraulic pressure converter 7 fixed mounting just is located one side of cursory rotor plate 2 in power generation facility mounting panel 1 top surface, one side fixed mounting that hydraulic pressure converter 7 kept away from cursory rotor plate 2 has rotatory magnetic induction subassembly 8.

Through the technical scheme, the buoy installation seat 3 and the buoy component 4 on the buoy installation seat are rotatably installed between the two buoy rotation plates 2 on the upper end surface of the power generation equipment installation plate 1, the potential energy impacted by the wave tide is converted through the main buoy 403 in the buoy installation seat to be converted into the rotary power of the main buoy 403 rotating through the rotating shaft of the buoy installation seat 3, the two hydraulic cylinders 6 are pushed to synchronously rotate through the buoy connection plate 10, wherein the equipment is installed offshore, the number of people is large, the warning lamp 404 is arranged to warn people and ships to prevent accidental touch and damage the equipment, the power assisting plate 407 is rotatably arranged in the power assisting plate fixing seat 406, the power assisting plate 407 is pushed to incline towards two sides through the current conversion holes 402 on the two sides, the inclination angle of the buoy component 4 is increased through the counterweight 408, the conversion efficiency 403 of the potential energy is increased, and after the main buoy rotates to a certain angle due to the buoyancy, the diving can not be performed, and the conversion efficiency is influenced; then, the hydraulic piston 605 is pushed by the hydraulic link 603 in the hydraulic cylinder 6, the hydraulic liquid in the hydraulic piston flows in the lead-in pipe 602, the potential energy is converted into the hydraulic converter 7 by the hydraulic principle, wherein potential energy is converted into a driving cabin 706 again through a transfer passage 703, a transfer cabin 704 and a driving cabin connecting hole 705, the potential energy is converted into power for driving a driving rod 707 to horizontally and stably traverse, and drives the driving rack 808 in the rotary magnetic induction component 8 to engage with the driving tooth groove 807 to rotate, so that the second turntable 805 can rotate, the first turntable 804 is driven to rotate through the transmission belt 806, the copper rod rotating shaft 810 at the rear end is driven to rotate, by making the diameter of the first turntable 804 different from that of the second turntable 805, the number of rotation of the rear induction copper rod 812 is faster, therefore, the magnetic induction line frequency emitted by the strong magnets 809 at the two cutting sides is higher, and the power generation efficiency is increased.

Wherein the float assembly 4 comprises: the device comprises a rocking cylinder shell 401, commutation holes 402, a main buoy 403, a warning lamp 404, a warning lamp controller 405, a power-assisted plate fixing seat 406, a power-assisted plate 407 and a balancing weight 408, wherein the rocking cylinder shell 401 is fixedly arranged on the surface of the upper end of a buoy mounting seat 3, the main buoy 403 is integrally and fixedly connected to the upper end of the rocking cylinder shell 401, a plurality of commutation holes 402 are respectively formed in two ends of the side surface of the rocking cylinder shell 401, and a sealed space is formed in the main buoy 403; the inside upper end fixed mounting of main cursory 403 has warning light controller 405, it installs outside main cursory 403 to go up the electrical property on warning light controller 405 a plurality of warning lights 404 and the top, sway a section of thick bamboo shell 401 bottom inner wall upper end fixed surface installation helping hand board fixing base 406, helping hand board fixing base 406 upper end rotation installation helping hand board 407, fixed mounting has balancing weight 408 in the middle of the helping hand board 407, just helping hand board fixing base 406 is perpendicular with both sides switching hole 402 line, sets up helping hand board 407 through the rotation of helping hand board fixing base 406, and through the switching hole 402 rivers flow of both sides, promote helping hand board 407 to incline to both sides to increase the inclination of cursory subassembly 4 through balancing weight 408, the conversion efficiency that increases the potential energy to main cursory 403 is because buoyancy rotates after certain angle, can't dive, influences conversion efficiency.

It should be noted that the hydraulic cylinder 6 includes: the hydraulic cylinder comprises a hydraulic cylinder shell 601, an inlet pipe 602, a hydraulic connecting rod 603, a sliding oil seal 604 and a hydraulic piston 605, wherein one side of the rear end of the hydraulic cylinder shell 601 is fixedly connected with a hydraulic cylinder rotating angle iron 12, the head end of the hydraulic cylinder shell 601 is fixedly provided with the sliding oil seal 604, the sliding oil seal 604 is internally inserted with the hydraulic connecting rod 603 in a sliding way and extends into the hydraulic cylinder shell 601, the upper end of the hydraulic cylinder shell 601 is fixedly communicated with the inlet pipe 602, the rear end of the inlet pipe 602 is fixedly connected with a telescopic pipe 11, one end of the hydraulic connecting rod 603 positioned in the hydraulic cylinder shell 601 is fixedly connected with the hydraulic piston 605, the hydraulic piston 605 is tightly contacted with the hydraulic cylinder shell 601, the other end of the hydraulic connecting rod 603 is rotatably arranged on a hydraulic cylinder rotating shaft 5, and the hydraulic piston 605 is pushed by the hydraulic connecting rod 603 in the hydraulic cylinder 6 to enable hydraulic fluid in the inlet pipe 602 to flow, potential energy is converted into the hydraulic converter 7 by the hydraulic principle.

In this embodiment, the hydraulic converter 7 includes: the telescopic tube type automatic feeding device comprises a converter outer shell 701, telescopic tube connecting holes 702, a transfer passage 703, a transfer cabin 704, a driving cabin connecting hole 705, a driving cabin 706, a driving rod 707 and a driving rod piston 708, wherein two telescopic tube connecting holes 702 are formed in the upper end of the converter outer shell 701, the two telescopic tube connecting holes 702 are respectively communicated with telescopic tubes 11, and the transfer passage 703 is communicated with the lower ends of the two telescopic tube connecting holes 702; the rear ends of the two transfer channels 703 are respectively communicated with a transfer cabin 704, the inner walls of the front ends of the two transfer cabins 704 are respectively communicated with a driving cabin 706 through driving cabin connecting holes 705, driving rod pistons 708 are closely and slidably mounted in the driving cabins 706, one sides, far away from the driving cabin connecting holes 705, of the driving rod pistons 708 are fixedly connected with driving rods 707, potential energy is converted into the driving cabins 706 again through the transfer channels 703, the transfer cabins 704 and the driving cabin connecting holes 705, and the potential energy is converted into power for horizontally and stably moving the driving rods 707.

Wherein, the rotary magnetic induction component 8 comprises: the magnetic induction assembly comprises a rotary magnetic induction assembly shell 801, an assembly rear plate 802, a wire connecting point 803, a first turntable 804, a second turntable 805, a transmission belt 806, a driving tooth groove 807, a driving rack 808, a strong magnet 809, a copper rod rotating shaft 810, a conductive copper rod 811, an induction copper rod 812, an electric brush rotating shaft 813 and a conductive electric brush 814, wherein the assembly rear plate 802 is fixedly connected to the rear end of the rotary magnetic induction assembly shell 801 in an integrated manner; the assembly rear plate 802 is respectively provided with a first rotating disc 804 and a second rotating disc 805 in a rotating manner, the first rotating disc 804 and the second rotating disc 805 are rotatably connected through a transmission belt 806, the middle end of the shaft body of the second rotating disc 805 is provided with a driving tooth groove 807, the lower end of the driving tooth groove 807 is connected with a driving rack 808 in a meshing manner, and one fixed end of the driving rack 808 is fixedly connected with a driving rod 707; the rear end of the first turntable 804 is coaxially and integrally fixedly connected with a copper rod rotating shaft 810, the front end of the copper rod rotating shaft 810 is fixedly connected with a conductive copper rod 811, two ends of the surface of one side, far away from the copper rod rotating shaft 810, of the conductive copper rod 811 are respectively and fixedly connected with two induction copper rods 812, the two induction copper rods 812 are rotatably arranged between two strong magnets 809, and the two strong magnets 809 are both fixedly arranged on the inner walls of two ends of a shell 801 of a rotary magnetic induction assembly; the front ends of the two induction copper bars 812 are fixedly connected with a conductive copper rod 811, the middle of the front side surface of the conductive copper rod 811 is fixedly connected with a brush rotating shaft 813, two sides of the brush rotating shaft 813 are respectively and fixedly connected with two conductive brushes 814, the rear ends of the two conductive brushes 814 are provided with a lead connecting point 803, the lead connecting point 803 is electrically connected with a power transmission lead 14, the two conductive brushes 814 are in sliding contact with the surface of one side of the lead connecting point 803, and are meshed with a driving tooth space 807 to rotate through a driving rack 808, so that the first rotating disc 804 can be driven to rotate through a driving belt 806, and the copper rod rotating shaft 810 at the rear end is driven to rotate, the rotating number of the rear end induction copper bars 812 is faster through the different diameters of the first rotating disc 804 and the second rotating disc 805, and the magnetic induction lines generated by the strong magnets 809 at two cutting sides of the first rotating disc 804 are higher in frequency, the power generation efficiency is increased.

The working principle is as follows:

the buoy installation base 3 and the buoy component 4 on the buoy installation base 3 are rotatably installed between the two buoy rotation plates 2 on the upper end surface of the power generation equipment installation plate 1, the potential energy impacted by a wave and tide is converted into the rotary power of the main buoy 403 rotating by the rotating shaft of the buoy installation base 3 through the main buoy 403 in the buoy installation base, the main buoy 403 synchronously rotates through the buoy connection plate 10 to push the two hydraulic cylinders 6, wherein the equipment is installed offshore and ships have more crowds, warning lamps 404 are arranged to warn crowds and ships to prevent accidental touch and damage the equipment, the booster plate 407 is rotatably arranged in the booster plate fixing base 406, water flows through the converter holes 402 on the two sides to push the booster plate 407 to incline towards the two sides, the inclination angle of the buoy component 4 is increased through the counterweight 408 to increase the conversion efficiency of the potential energy so as to prevent the main buoy 403 from rotating to a certain angle due to the buoyancy, the diving can not be performed, and the conversion efficiency is influenced; then, the hydraulic piston 605 is pushed by the hydraulic link 603 in the hydraulic cylinder 6, the hydraulic liquid in the hydraulic piston flows in the lead-in pipe 602, the potential energy is converted into the hydraulic converter 7 by the hydraulic principle, wherein potential energy is converted into a driving cabin 706 again through a transfer passage 703, a transfer cabin 704 and a driving cabin connecting hole 705, the potential energy is converted into power for driving a driving rod 707 to horizontally and stably traverse, and drives the driving rack 808 in the rotary magnetic induction component 8 to engage with the driving tooth groove 807 to rotate, so that the second turntable 805 can rotate, the first turntable 804 is driven to rotate through the transmission belt 806, the copper rod rotating shaft 810 at the rear end is driven to rotate, by making the diameter of the first turntable 804 different from that of the second turntable 805, the number of rotation of the rear induction copper rod 812 is faster, therefore, the magnetic induction line frequency emitted by the strong magnets 809 at the two cutting sides is higher, and the power generation efficiency is increased.

It is noted that, herein, relational terms such as first and second, and the like may be used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus. Without further limitation, an element defined by the phrase "comprising a reference structure" does not exclude the presence of other identical elements in a process, method, article, or apparatus that comprises the element.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims (8)

1. A floating offshore power generation device comprising a power generation device mounting plate (1), characterized in that: the power generation device is characterized in that one end of the upper surface of the power generation device mounting plate (1) is fixedly provided with two float rotating plates (2) for mounting a float mounting seat (3), the float mounting seat (3) is rotatably mounted between the two float rotating plates (2), the upper end of the float mounting seat (3) is fixedly provided with a float assembly (4), the side surface of the upper end of the float assembly is fixedly provided with a plurality of balance floats (13), the lower end of the float mounting seat (3) is fixedly connected with a limiting steel cable (9) and is fixedly connected with the surface of the upper end of the power generation device mounting plate (1), two ends of a rotating shaft of the float mounting seat (3) are fixedly connected with float connecting plates (10), the outer side surfaces of the upper ends of the two float connecting plates (10) are fixedly connected with two hydraulic cylinder rotating shafts (5), and the two hydraulic cylinders (6) are respectively rotatably mounted on the two hydraulic cylinder rotating shafts (5), two hydraulic pressure section of thick bamboo (6) are rotated angle bar (12) through two hydraulic pressure section of thick bamboos respectively and are rotated and install at hydraulic pressure converter (7) both sides surface, hydraulic pressure converter (7) fixed mounting is in one side of power generating equipment mounting panel (1) top surface and lie in cursory rotor plate (2), one side fixed mounting that cursory rotor plate (2) was kept away from in hydraulic pressure converter (7) has rotatory magnetism to feel subassembly (8), cursory subassembly (4) include: the device comprises a rocking cylinder shell (401), commutation holes (402), a main buoy (403), warning lamps (404), a warning lamp controller (405), a power-assisted plate fixing seat (406), a power-assisted plate (407) and a balancing weight (408), wherein the rocking cylinder shell (401) is fixedly arranged on the surface of the upper end of a buoy mounting seat (3), the upper end of the rocking cylinder shell (401) is integrally and fixedly connected with the main buoy (403), two ends of the side surface of the rocking cylinder shell (401) are respectively provided with the plurality of commutation holes (402), a sealed space is arranged in the main buoy (403), the upper end in the main buoy (403) is fixedly provided with the warning lamp controller (405), the warning lamp controller (405) is electrically provided with the warning lamps (404), the top of the warning lamp controller extends out of the main buoy (403), the surface of the upper end of the inner wall of the bottom end of the rocking cylinder shell (401) is fixedly provided with the power-assisted plate fixing seat (406), helping hand board (407) is installed in helping hand board fixing base (406) upper end rotation, fixed mounting has balancing weight (408) in the middle of helping hand board (407), just helping hand board fixing base (406) is perpendicular with both sides change orifice (402) line.

2. A floating offshore power generation unit according to claim 1, wherein: the hydraulic cylinder (6) comprises: a hydraulic cylinder shell (601), an introducing pipe (602), a hydraulic connecting rod (603), a sliding oil seal (604) and a hydraulic piston (605), one side of the rear end of the hydraulic cylinder shell (601) is fixedly connected with a hydraulic cylinder rotating angle iron (12), the head end of the hydraulic cylinder shell (601) is fixedly provided with a sliding oil seal (604), a hydraulic connecting rod (603) is inserted in the sliding oil seal (604) in a sliding way and extends into the hydraulic cylinder shell (601), the upper end of the hydraulic cylinder shell (601) is fixedly communicated with an introduction pipe (602), the rear end of the introduction pipe (602) is fixedly connected with a telescopic pipe (11), one end of the hydraulic connecting rod (603) positioned in the hydraulic cylinder shell (601) is fixedly connected with a hydraulic piston (605), and the hydraulic piston (605) is tightly contacted with the hydraulic cylinder shell (601), and the other end of the hydraulic connecting rod (603) is rotatably arranged on the hydraulic cylinder rotating shaft (5).

3. A floating offshore power generation unit according to claim 2, wherein: the hydraulic converter (7) comprises: the device comprises a converter outer shell (701), telescopic pipe connecting holes (702), a transfer passage (703), a transfer cabin (704), a driving cabin connecting hole (705), a driving cabin (706), a driving rod (707) and a driving rod piston (708), wherein the upper end of the converter outer shell (701) is provided with two telescopic pipe connecting holes (702), the two telescopic pipe connecting holes (702) are respectively communicated with telescopic pipes (11), and the lower ends of the two telescopic pipe connecting holes (702) are communicated with the transfer passage (703).

4. A floating offshore power generation unit according to claim 3, wherein: the rear ends of the two transfer channels (703) are respectively communicated with transfer cabins (704), the inner walls of the front ends of the two transfer cabins (704) are respectively communicated with driving cabins (706) through driving cabin connecting holes (705), driving rod pistons (708) are tightly installed in the driving cabins (706) in a sliding mode, and one sides, far away from the driving cabin connecting holes (705), of the driving rod pistons (708) are fixedly connected with driving rods (707).

5. A floating offshore power generation unit according to claim 4, characterized in that: the rotary magnetic induction assembly (8) comprises: rotatory magnetic induction subassembly shell (801), subassembly back plate (802), wire connection point (803), carousel (804), No. two carousels (805), driving belt (806), drive tooth's socket (807), drive rack (808), strong magnet (809), copper bar rotation axis (810), electrically conductive copper pole (811), response bar copper (812), brush rotation axis (813) and electrically conductive brush (814), rotatory magnetic induction subassembly shell (801) rear end integration fixedly connected with subassembly back plate (802).

6. A floating offshore power generation unit according to claim 5, wherein: the assembly rear plate (802) is respectively rotatably provided with a first rotating disc (804) and a second rotating disc (805), the first rotating disc (804) and the second rotating disc (805) are rotatably connected through a transmission belt (806), a driving tooth groove (807) is formed in the middle end of the shaft body of the second rotating disc (805), the lower end of the driving tooth groove (807) is meshed with a driving rack (808), and one end of the driving rack (808) is fixed and is fixedly connected with the driving rod (707).

7. A floating offshore power generation unit according to claim 6, wherein: no. one carousel (804) coaxial integration fixedly connected with copper pole rotation axis (810) in rear end, the front end fixedly connected with of copper pole rotation axis (810) electrically conducts copper pole (811), electrically conducts copper pole (811) keep away from two response bar copper (812) of a side surface both ends difference fixedly connected with of copper pole rotation axis (810), two response bar copper (812) rotate and set up between two strong magnets (809), two equal fixed mounting of strong magnet (809) is on rotatory magnetism feels subassembly shell (801) both ends inner wall.

8. A floating offshore power generation unit according to claim 7, wherein: two the front end fixed connection of response bar copper (812) still has a conductive copper pole (811), should fixedly connected with brush rotation axis (813) in the middle of the front side surface of conductive copper pole (811), two conducting brush (814) of fixedly connected with respectively in the both sides of brush rotation axis (813), two conducting brush (814) rear end is provided with wire tie point (803), wire tie point (803) electric connection has transmission of electricity wire (14), and two conducting brush (814) sliding contact wire tie point (803) side surface.

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