CN108457806B

CN108457806B - Floating type wind-current hybrid power generation platform

Info

Publication number: CN108457806B
Application number: CN201810216905.0A
Authority: CN
Inventors: 王伟; 谢永和; 龚希武; 张吉萍; 李俊来; 王立军
Original assignee: Zhejiang Ocean University ZJOU
Current assignee: Zhejiang Ocean University ZJOU
Priority date: 2017-12-13
Filing date: 2018-03-16
Publication date: 2020-10-09
Anticipated expiration: 2038-03-16
Also published as: CN108457806A

Abstract

A floating type wind-current hybrid power generation platform comprises a rotating wheel, a third gear, a second chain, a first gear, a second gear, a wheel carrier, an infrared emission module, a retaining ring, an infrared receiving module, a controller, a retaining lug, a floating body platform, a wind sail, an anchor chain, an anchor, a first power generator, a first speed-increasing gear box, a first inertia wheel, a first one-way bearing, a rotating rod, a second power generator, a second speed-increasing gear box, a second inertia wheel, a second one-way bearing, a fifth gear, a third chain and a fourth gear, wherein the floating body platform is provided with a plurality of wind sails; the invention has the advantages that: can utilize wind energy and wave energy.

Description

Floating type wind-current hybrid power generation platform

Technical Field

The invention relates to a floating type wind-current hybrid power generation platform, and belongs to the technical field of power generation equipment.

Background

The energy stored in the ocean is utilized to generate electricity. The ocean energy includes kinetic energy of seawater including ocean current energy, wave energy and the like, energy contained in the temperature difference between surface seawater and deep seawater, energy of tide and the like, and is seen in tidal power stations and ocean energy power stations. Ocean energy generally refers to renewable energy sources stored in the ocean, and mainly comprises tidal energy, wave energy, ocean current energy, seawater temperature difference energy, seawater salt difference energy and the like. The existing ocean platform generally uses a diesel generating set, the equipment is large in size, complex in structure, consumes a large amount of non-renewable resource diesel oil, and is not environment-friendly, the market of China is located near the sea, a plurality of small islands are arranged, and wind waves between the small islands and the small islands are urgent, so that wind energy and wave energy can be utilized, and a floating type wind-current hybrid power generation platform capable of utilizing the wind energy and the wave energy needs to be developed.

Disclosure of Invention

The invention aims to provide a floating type wind-current hybrid power generation platform.

The invention aims to solve the problems that a diesel generating set commonly used on an ocean platform at present consumes huge energy and is not environment-friendly.

In order to realize the purpose of the invention, the technical scheme adopted by the invention is as follows:

a floating wind-current hybrid power generation platform comprises a rotating wheel, a third gear, a second chain, a first gear, a second gear, a wheel carrier, an infrared emission module, a retaining ring, an infrared receiving module, a controller, a retaining lug, a floating body platform, sails, anchor chains, anchors, a first generator, a first speed-increasing gear box, a first inertia wheel, a first one-way bearing, a rotating rod, a second generator, a second speed-increasing gear box, a second inertia wheel, a second one-way bearing, a fifth gear, a third chain and a fourth gear, wherein the floating body platform is provided with a plurality of sails, the anchor chains are arranged below the floating body platform, the anchors are arranged at the lower end of the anchor chains, the infrared receiving modules are respectively arranged at the left end and the right end of the rear side of the floating body platform, the two retaining lugs are arranged at the rear side of the floating body platform, the retaining ring is arranged on the retaining lug, the first chain is arranged on the first chain, the first gear is sleeved on the first gear, an infrared transmitting module is arranged at the front end of a wheel carrier, the infrared transmitting module is in signal connection with an infrared receiving module, the infrared transmitting module is matched with the infrared receiving module, the infrared receiving module is connected with a controller through a lead, the controller is arranged on a floating body platform, the wheel carrier is arranged on the shore, a shaft of a first gear is connected with a shaft of a second gear through a coupler, a shaft of the second gear is arranged on the wheel carrier, a second chain is sleeved on the second gear, the other end of the second chain is sleeved on a third gear, the right end of a rotating wheel is arranged on the shaft of the third gear, a rotating rod is arranged on the back of the rotating wheel, the rotating rod is connected with an input shaft of a first one-way bearing through a coupler, an output shaft of the first one-way bearing is connected with an input shaft of a first inertia wheel through a coupler, an output shaft of the first inertia wheel is connected with an input shaft of a first speed-increasing gear box through a coupler, and an output, the fourth gear is connected with a shaft of the third gear through a coupler, a third chain is sleeved on the fourth gear, the right end of the third chain is sleeved on the fifth gear, the shaft of the fifth gear is connected with an input shaft of the second one-way bearing through the coupler, an output shaft of the second one-way bearing is connected with an input shaft of the second inertia wheel through the coupler, an output shaft of the second inertia wheel is connected with an input shaft of the second speed-increasing gear box through the coupler, and an output shaft of the second speed-increasing gear box is connected with the second generator through the coupler.

The shaft coupling is installed on the bearing frame, and the bearing frame is installed on the bank.

The invention has the advantages that: the sail is an automatic lifting sail and has a function of rotating and facing, a lifting control device in the sail is connected with a controller, an anchor can prevent the platform from deviating from a motion range, wind energy enables the sail to drive the floating body platform to move along with wind, the retaining ring drives the first chain to move, the first gear rotates, the second chain rotates, the third gear rotates, the fourth gear rotates, the fifth gear rotates, an input shaft of the second one-way bearing rotates, the second one-way bearing has a function of preventing the input shaft of the second inertia wheel from reversing, an output shaft of the second one-way bearing only outputs a rotary motion in one direction forever, and the second inertia wheel stores mechanical energy output by the second one-way bearing, the mechanical energy is transmitted to a second speed-up gear box, and the second speed-up gear box is responsible for increasing the rotating speed to the rated rotating speed of a second generator so as to promote the second generator to generate electricity; the third gear rotates to enable the rotating wheel to rotate, the rotating rod to rotate and enable the input shaft of the first one-way bearing to rotate, the first one-way bearing has the function of preventing the input shaft of the first inertia wheel from reversing, the output shaft of the first one-way bearing only outputs one direction of rotation movement forever, the second inertia wheel stores mechanical energy output by the second one-way bearing and transmits the mechanical energy to the second speed-up gear box, and the second speed-up gear box is responsible for increasing the rotating speed to the rated rotating speed of the second generator to enable the second generator to generate electricity; the rotating motion output by the output shaft of the first one-way bearing and the rotating motion output by the output shaft of the second one-way bearing are opposite, the floating body platform moves to the front of the infrared transmitting module on the left side along with the sail, the infrared receiving module receives information, the controller enables the control device arranged in the sail to lower the sail, the floating body platform moves to the infrared transmitting module on the right side in the right direction under the drive of waves, the controller enables the control device arranged in the sail to lift the sail, the sail drives the floating body platform to move to the left, the rotation of the first gear caused by the leftward movement of the floating body platform is generated by the rotating motion output by the output shaft of the first one-way bearing, and the rotation of the first gear caused by the rightward movement of the floating body platform is generated by the rotating motion output shaft of the second one-way bearing.

Drawings

FIG. 1 is a top view of the overall structure of a floating wind-current hybrid power generation platform according to the present invention;

FIG. 2 is a front view of the turn bar mounted on the wheel;

FIG. 3 is a front view of the buoyant platform;

FIG. 4 is a front view of the second gear and the first gear mounting structure;

in the figure: 1. the device comprises a rotating wheel 2, a third gear 3, a second chain 4, a first chain 5, a first gear 6, a second gear 7, a wheel carrier 8, an infrared transmitting module 9, a retaining ring 10, an infrared receiving module 11, a controller 12, a retaining lug 13, a floating body platform 14, a sail 15, an anchor chain 16, an anchor 17, a first generator 18, a first speed-increasing gear box 19, a first inertia wheel 20, a first one-way bearing 21, a rotating rod 22, a second generator 23, a second speed-increasing gear box 24, a second inertia wheel 25, a second one-way bearing 26, a fifth gear 27, a third chain 28 and a fourth gear.

Detailed Description

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

The invention relates to a floating wind-current hybrid power generation platform, which comprises a rotating wheel 1, a third gear 2, a second chain 3, a first chain 4, a first gear 5, a second gear 6, a wheel carrier 7, an infrared emission module 8, a retaining ring 9, an infrared receiving module 10, a controller 11, a retaining lug 12, a floating body platform 13, a wind sail 14, an anchor 16 chain 15, an anchor 16, a first generator 17, a first speed-increasing gear box 18, a first inertia wheel 19, a first one-way bearing 20, a rotating rod 21, a second generator 22, a second speed-increasing gear box 23, a second inertia wheel 24, a second one-way bearing 25, a fifth gear 26, a third chain 27 and a fourth gear 28, wherein a plurality of wind sails 14 are installed on the floating body platform 13, the anchor 16 chain 15 is installed below the floating body platform 13, the anchor 16 is installed at the lower end of the anchor 16 chain 15, the infrared receiving module 10 is respectively installed at the left end and the right end of the rear side of the floating body platform 13, two retaining lugs 12 are installed at the, the buckle ring 9 is buckled on the buckle lug 12, the buckle ring 9 is installed on the first chain 4, the first chain 4 is sleeved on the first gear 5, the shaft of the first gear 5 is installed on the wheel carrier 7, the sail 14 is an automatic lifting sail 14 and has a function of rotating and facing, a lifting control device inside the sail 14 is connected with the controller 11, the anchor 16 can prevent the platform from deviating from a movement range, wind energy enables the sail 14 to drive the floating body platform 13 to move along with wind, the buckle ring 9 drives the first chain 4 to move, the first gear 5 rotates, the second gear 6 rotates, the second chain 3 rotates, the third gear 2 rotates, the infrared emitting module 8 is installed at the front end of the wheel carrier 7, the infrared emitting module 8 is in signal connection with the infrared receiving module 10, the infrared emitting module 8 is matched with the infrared receiving module 10, the infrared receiving module 10 is connected with the controller 11 through a lead, the controller 11 is installed on the floating body 13, the wheel carrier 7 is arranged on the shore, the shaft of the first gear 5 is connected with the shaft of the second gear 6 through a coupler, the shaft of the second gear 6 is arranged on the wheel carrier 7, the second chain 3 is sleeved on the second gear 6, the upper end of the second chain 3 is sleeved on the third gear 2, the shaft of the third gear 2 is arranged on a flange bearing, the rotating wheel 1 is arranged on the shaft of the third gear 2, a rotating rod 21 is arranged on the back of the rotating wheel 1, the rotating rod 21 is connected with the input shaft of the first one-way bearing 20 through the coupler, the output shaft of the first one-way bearing 20 is connected with the input shaft of the first inertia wheel 19 through the coupler, the output shaft of the first inertia wheel 19 is connected with the input shaft of the first speed-up gear box 18 through the coupler, the output shaft of the first speed-up gear box 18 is connected with the first generator 17 through the coupler, the third gear 2 rotates to rotate the rotating wheel 1 to rotate the rotating rod 21 to rotate the input shaft of the first one-way bearing 20, the first one-way bearing 20 has the function of preventing the input shaft of the first inertia wheel 19 from reversing, the output shaft of the first one-way bearing 20 only outputs the rotary motion in one direction forever, the second inertia wheel 24 stores the mechanical energy output by the second one-way bearing 25 and transmits the mechanical energy to the second speed-up gear box 23, and the second speed-up gear box 23 is responsible for increasing the rotating speed to the rated rotating speed of the second generator 22 so as to promote the second generator 22 to generate electricity; a third chain 27 is sleeved on the fourth gear 28, the right end of the third chain 27 is sleeved on the fifth gear 26, the shaft of the fifth gear 26 is connected with the input shaft of the second one-way bearing 25 through a coupler, the output shaft of the second one-way bearing 25 is connected with the input shaft of the second inertia wheel 24 through a coupler, the output shaft of the second inertia wheel 24 is connected with the input shaft of the second speed-increasing gear box 23 through a coupler, the output shaft of the second speed-increasing gear box 23 is connected with the second generator 22 through a coupler, so that the fourth gear 28 rotates to drive the fifth gear 26 to rotate, so that the input shaft of the second one-way bearing 25 rotates, the second one-way bearing 25 has the function of preventing the input shaft of the second inertia wheel 24 from reversing, the output shaft of the second one-way bearing 25 only outputs a rotary motion in one direction forever, the second inertia wheel 24 stores the mechanical energy output by the second one-way bearing 25 and transmits the mechanical energy to the second speed-increasing gear box 23, the second speed-increasing gearbox 23 is responsible for increasing the rotating speed to the rated rotating speed of the second generator 22, so as to promote the second generator 22 to generate electricity; the coupler is installed on a bearing frame which is installed on the shore, the rotating motion output by the output shaft of the first one-way bearing 20 and the rotating motion output by the output shaft of the second one-way bearing 25 are opposite, the floating body platform 13 moves to the left along with the sail 14 to the front of the infrared emission module 8 on the left side, the infrared receiving module 10 receives information, the controller 11 enables a control device which is arranged in the sail 14 to descend the sail 14, under the drive of waves, the floating body platform 13 moves to the right side, the infrared emission module 8 moves rightwards, the controller 11 enables the control device arranged in the sail 14 to lift the sail 14, the sail 14 drives the floating body platform 13 to move leftwards, the rotation of the first gear 5 caused by the leftward movement of the floating body platform 13 is output by the output shaft of the first one-way bearing 20 to generate electricity, and the rotation of the first gear 5 caused by the rightward movement of the floating body platform 13 is output by the output shaft of the second one-way bearing 25 to generate electricity.

The use method of the invention comprises the following steps: the sail 14 is an automatic lifting sail 14 with a function of rotation direction, a lifting control device in the sail 14 is connected with a controller 11, an anchor 16 can prevent the platform from deviating from a movement range, wind energy enables the sail 14 to drive the floating body platform 13 to move with wind, the buckle ring 9 drives the first chain 4 to move, the first gear 5 rotates, the second gear 6 rotates, the second chain 3 rotates, the third gear 2 rotates, the fourth gear 28 rotates to drive the fifth gear 26 to rotate, an input shaft of the second one-way bearing 25 rotates, the second one-way bearing 25 has a function of preventing the input shaft of the second inertia wheel 24 from reversing, an output shaft of the second one-way bearing 25 only outputs rotation motion in one direction forever, the second inertia wheel 24 stores mechanical energy output by the second one-way bearing 25 and transmits the mechanical energy to the second speed increasing gear box 23, the second speed increasing gear box 23 is responsible for increasing the rotation speed to the rated rotation speed of the second generator 22, causing the second generator 22 to generate electricity; the third gear 2 rotates to enable the rotating wheel 1 to rotate, the rotating rod 21 to rotate, the input shaft of the first one-way bearing 20 to rotate, the first one-way bearing 20 has the function of preventing the input shaft of the first inertia wheel 19 from reversing, the output shaft of the first one-way bearing 20 only outputs one-direction rotating motion forever, the second inertia wheel 24 stores mechanical energy output by the second one-way bearing 25 and transmits the mechanical energy to the second speed-increasing gear box 23, and the second speed-increasing gear box 23 is responsible for increasing the rotating speed to the rated rotating speed of the second generator 22 to enable the second generator 22 to generate electricity; the rotation motion output by the output shaft of the first one-way bearing 20 and the rotation motion output by the output shaft of the second one-way bearing 25 are opposite, the floating body platform 13 moves to the front of the infrared emitting module 8 on the left side along with the sail 14, the infrared receiving module 10 receives information, the controller 11 enables a control device arranged in the sail 14 to descend the sail 14, under the drive of waves, the floating body platform 13 moves to the right side, the infrared emission module 8 moves rightwards, the controller 11 enables the control device arranged in the sail 14 to lift the sail 14, the sail 14 drives the floating body platform 13 to move leftwards, the rotation of the first gear 5 caused by the leftward movement of the floating body platform 13 is output by the output shaft of the first one-way bearing 20 to generate electricity, and the rotation of the first gear 5 caused by the rightward movement of the floating body platform 13 is output by the output shaft of the second one-way bearing 25 to generate electricity.

Claims

1. The utility model provides a float formula wind-current hybrid power generation platform, including runner (1), third gear (2), second chain (3), first chain (4), first gear (5), second gear (6), wheel carrier (7), infrared emission module (8), buckle (9), infrared receiving module (10), controller (11), knot ear (12), body platform (13), sail (14), anchor (16) chain (15), anchor (16), first generator (17), first speed-increasing gear box (18), first inertia wheel (19), first one-way bearing (20), bull stick (21), second generator (22), second speed-increasing gear box (23), second inertia wheel (24), second one-way bearing (25), fifth gear (26), third chain (27) and fourth gear (28), characterized by: the wind power generation device is characterized in that a plurality of sails (14) are installed on a floating body platform (13), an anchor (16) chain (15) is installed below the floating body platform (13), an anchor (16) is installed at the lower end of the anchor (16) chain (15), infrared receiving modules (10) are installed at the left end and the right end of the rear side of the floating body platform (13), two buckling lugs (12) are installed at the rear side of the floating body platform (13), a buckling ring (9) is buckled on the buckling lugs (12), the buckling ring (9) is installed on a first chain (4), the first chain (4) is sleeved on a first gear (5), a shaft of the first gear (5) is installed on a wheel carrier (7), the sails (14) are automatic lifting type sails (14) and have a function of rotating and facing, a lifting control device inside the sails (14) is connected with a controller (11), the anchor (16) can prevent the platform from deviating from a movement range, and the floating body of the sails (14) can move along, the retaining ring (9) drives the first chain (4) to move, the first gear (5) rotates, the second gear (6) rotates, the second chain (3) rotates, the third gear (2) rotates, the front end of the wheel carrier (7) is provided with an infrared emission module (8), the infrared emission module (8) is in signal connection with an infrared receiving module (10), the infrared emission module (8) is matched with the infrared receiving module (10), the infrared receiving module (10) is connected with the controller (11) through a lead, the controller (11) is arranged on a floating body platform (13), the wheel carrier (7) is arranged on the shore, the shaft of the first gear (5) is connected with the shaft of the second gear (6) through a coupler, the shaft of the second gear (6) is arranged on the wheel carrier (7), the second chain (3) is sleeved on the second gear (6), the other end of the second chain (3) is sleeved on the third gear (2), the right end of the rotating wheel (1) is arranged on a shaft of a third gear (2), a rotating rod (21) is arranged at the back of the rotating wheel (1), the rotating rod (21) is connected with an input shaft of a first one-way bearing (20) through a coupler, an output shaft of the first one-way bearing (20) is connected with an input shaft of a first inertia wheel (19) through a coupler, an output shaft of the first inertia wheel (19) is connected with an input shaft of a first speed-increasing gear box (18) through a coupler, an output shaft of the first speed-increasing gear box (18) is connected with a first generator (17) through a coupler, a fourth gear (28) is connected with a shaft of the third gear (2) through a coupler, a third chain (27) is sleeved on the fourth gear (28), the right end of the third chain (27) is sleeved on a fifth gear (26), and a shaft of the fifth gear (26) is connected with an input shaft of a second one-way bearing (25) through a coupler, an output shaft of the second one-way bearing (25) is connected with an input shaft of the second inertia wheel (24) through a coupler, an output shaft of the second inertia wheel (24) is connected with an input shaft of the second speed-up gear box (23) through a coupler, and an output shaft of the second speed-up gear box (23) is connected with the second generator (22) through a coupler.

2. The floating wind-current hybrid power generation platform according to claim 1, wherein: the shaft coupling is installed on the bearing frame, and the bearing frame is installed on the bank.