CN215521124U - Integrated high-efficiency ocean wind power station - Google Patents

Abstract

The utility model relates to an integrated high-efficiency ocean wind power station, which comprises a wind collecting device, a power generation device, a floating device and a bracket (11); the power generation device is arranged in the wind collecting device; the bracket (11) is stably arranged above the floating device; the wind collecting device is arranged in the bracket body of the bracket (11), and is fixedly connected with the floating device through the bracket (11); the wind collecting device comprises a wind collecting shell (1) and a tower barrel (3). The method has the advantages of simple construction, short period, low manufacturing cost, low risk, capability of adapting to deep and distant sea areas and the like, breaks through Betz limit control, and has higher application and popularization values.

Description

Integrated high-efficiency ocean wind power station

Technical Field

The utility model belongs to the technical field of wind power generation, and particularly belongs to the technical field of integrated high-efficiency ocean wind power stations.

Background

Wind power generation is the fastest-developing green energy technology in the world, and people have noticed some limitations on land wind energy utilization, such as large occupied area, noise pollution and the like, while land wind power plant construction is rapidly developed. Due to the abundant wind energy resources at sea and the feasibility of the current technology, the sea becomes a rapidly-developing wind power market. The offshore wind farm in Europe and America is in the beginning of large-scale development, the coastal sea area in China is wide, wind power generation resources can be developed by about billions of kilowatts, the developable resources in deep open sea are more huge, the distance from a power load center (a developed power tight shortage area of coastal economy) is very close, and with the mature development of offshore wind farm technology, wind power can certainly become an important energy source for sustainable development of coastal areas in China.

At present, the offshore power generation adopts an original land generator set, as shown in fig. 10, the following five problems mainly exist: 1) the wind turbine foundation exploration needs special equipment, such as an exploration ship and the like; 2) the construction difficulty of the fan foundation is very high, and the cost is high; 3) the hoisting of the fan needs large hoisting equipment, so that the period is long, the cost is high, and the risk is high; 4) the land wind power generation is only suitable for hoisting the offshore shallow sea beach; 5) the power generation efficiency of the land three-blade fan is controlled by the Betz limit, and the actual power generation efficiency is only about 50%.

The traditional offshore wind power generation technology has the defects of high construction difficulty, long period, high cost, high risk, low power generation efficiency, incapability of adapting to deep and offshore areas and the like, and in order to obtain deep and offshore wind energy, a floating power generation mode has been proposed abroad, but is still limited to the adoption of a traditional land fan, and the innovation degree is not generated, as shown in fig. 11 and 12.

In conclusion, a new set of ocean wind power station needs to be developed to meet the development requirement both at home and abroad.

Disclosure of Invention

The utility model aims to solve the defects and provides an integrated high-efficiency ocean wind power station aiming at the defects of the existing offshore wind power generation technology. The wind power station has the advantages of simple construction, short period, low manufacturing cost, low risk, capability of adapting to deep and distant sea areas and the like, breaks through Betz limit control, and has higher application and popularization values.

The utility model is realized by adopting the following technical scheme.

The utility model discloses an integrated high-efficiency ocean wind power station, which comprises a wind collecting device, a power generating device, a floating device and a bracket 11;

the power generation device is arranged in the wind collecting device;

the bracket 11 is stably arranged on the floating device;

the wind collecting device is arranged in the bracket body of the bracket 11 and is fixedly connected with the floating device through the bracket 11;

the wind collecting device comprises a wind collecting shell 1 and a tower barrel 3;

the wind collecting shell 1 is arranged into a cylindrical hollow cavity; a tower barrel 3 is fixedly connected to the bottom of the wind collecting shell 1, and the tower barrel 3 penetrates or extends to the central position of the cavity of the wind collecting shell 1 [ the central position of the cavity of the wind collecting shell 1 refers to the central line position when the wind collecting shell 1 is vertically placed ];

the power generation device; the central shaft is fixedly arranged on the wind collecting shell 1 and is fixedly arranged on the tower barrel 3; the power generation device comprises a fan blade 4; the fan blades 4 are fixedly arranged inside the wind collecting shell 1;

the flotation device comprises a flotation platform 7.

Further, the air collecting shell 1 of the utility model sequentially comprises an air inlet 1.1, a gradually enlarged section 1.2, an amplification section 1.3, a gradually flat section 1.4, a horizontal section 1.5 and an air outlet 1.6; the inner diameters of the gradually enlarging section 1.2, the amplifying section 1.3, the gradually flattening section 1.4 and the horizontal section 1.5 are sequentially increased.

Further, the wind collecting shell 1 is horizontally arranged; a fan blade 4 in the power generation device is arranged at a horizontal section 1.5 of the wind collecting shell 1; the wind collecting device also comprises an opening support frame 12, wherein the opening support frame 12 is arranged at the position of the wind inlet 1.1 or at the positions of the wind inlet 1.1 and the wind outlet 1.6 respectively.

Furthermore, the opening support frame 12 is composed of a plurality of support pieces 13, the support pieces 13 are in a fish shape, the fish heads of the support pieces are fixed at one position in a concentrated manner, and the fish tails of the support pieces are respectively fixed on the inner wall of the wind collecting shell 1.

Further, the wind collecting device also comprises a wind collecting shell stiffening ring 2; the number of the wind collecting shell stiffening rings 2 is set to be a plurality of, and the wind collecting shell stiffening rings are respectively and fixedly arranged on the air inlet 1.1, the gradually enlarged section 1.2, the amplification section 1.3, the gradually flat section 1.4, the horizontal section 1.5 and the air outlet 1.6.

Further, the tower drum 3 is vertically arranged; when the wind collecting shell 1 is horizontally arranged, the gravity line of the wind collecting shell 1 is inosculated with the tower barrel 3 which is vertically arranged.

Furthermore, the power generation device also comprises a power generator 5, a wind generating set component 8, wires, cables and an accommodating bin body; the wind generating set components 8 include conventional existing components such as control components;

the accommodating bin body is in a shuttle shape; the generator 5 and the wind generating set part 8 are arranged in the shuttle-shaped accommodating bin body; the fan blades 4 are fixedly arranged at the tail end of the shuttle-shaped containing bin body, the fan blades 4 rotate around the tail end of the containing bin body as the circle center, and the number of the fan blades 4 is 5-6; the fan blade 4 is connected with the generator 5 through an electric wire; the generator 5 is connected with the wind generating set component 8 through an electric wire; the wind generating set component 8 outputs power through a cable; the cable sets up and links out after arranging in the barrel of a tower section of thick bamboo 3.

Furthermore, the power generation device also comprises a solar photovoltaic panel 6, a first supporting rod 14.1 and a second supporting rod 14.2; the solar photovoltaic panel 6, the first supporting rod 14.1 and the second supporting rod 14.2 are all fixedly arranged at the top of the floating platform 7 or/and the bracket 11; the length of the first strut 14.1 is shorter than that of the second strut 14.2; the first supporting rod 14.1 is fixedly arranged in the middle of the solar photovoltaic panel 6; the second supporting rod 14.2 is fixedly arranged at the end part of the solar photovoltaic panel 6; the other end of the solar photovoltaic panel 6 is contacted with the floating platform 7 or/and the top of the bracket 11; the inclined plane formed by the solar photovoltaic panel 6 and the horizontal plane faces the sun.

Further, the floating device of the utility model also comprises a buoy 9 and a balance buoy 10; the buoy 9 is of an oval cavity structure, the edge of the buoy is smooth, and the buoy is uniformly fixed and symmetrically arranged at the bottom of the floating platform 7; the balance buoy 10 is arranged to be a cubic hollow cavity or a cylindrical hollow cavity, and is fixedly, uniformly and symmetrically arranged at the side edge position of the bottom of the floating platform 7.

Further, the wind power plant of the utility model also comprises a fixing device; the fixing device comprises a rope and an anchor; one end of the rope is fixedly connected with the floating device; the other end of the rope is fixedly connected with an anchor; the anchor is arranged at the water bottom.

The utility model has the beneficial effects that the innovation and value are as follows:

1) the integrated high-efficiency ocean wind power station adopts a floating platform and does not need a special foundation, so that the application range can be expanded to deep and open sea;

2) the wind collecting shell is arranged, the power generation efficiency of the wind generator is improved by 60% by adopting multiple blades (five to six blades) and reaches more than 80%, in addition, the requirement of minimum spacing of land wind driven fans can be broken through, compact stacking arrangement can be realized, and a large number of cables are saved;

3) the method can be manufactured on the shore land, so that the construction risk is greatly reduced, and the construction period is shortened. After the construction is finished, hauling or self-navigating to a designated sea area for production and power generation;

4) because the floating platform has larger plane size, the solar cell panel can be further utilized and laid, and necessary conditions are created for realizing wind and light one-set power generation;

5) the operation, maintenance and management are convenient, and the cost is lower than that of the conventional offshore wind power generation scheme.

The utility model is further explained below with reference to the drawings and the detailed description.

Drawings

FIG. 1 is a three-dimensional view of a single high efficiency marine wind turbine of the present invention.

FIG. 2 is a side (vertical wind direction) view of a single high efficiency marine wind generator of the present invention.

FIG. 3 is a rear (upwind) view of a single high efficiency marine wind generator of the present invention.

Fig. 4 is a three-dimensional view of the present invention.

Fig. 5 is a top view of the present invention.

Fig. 6 is a side (vertical wind direction) view of the present invention.

Fig. 7 is a front (downwind) view of the present invention.

Fig. 8 is a rear (upwind) view of the present invention.

Fig. 9 is a bottom view of the present invention.

FIG. 10 is a schematic view of components of a conventional offshore wind turbine assembly.

Fig. 11 is a schematic diagram of a floating offshore wind power generation mode proposed abroad.

Fig. 12 is a schematic diagram of another floating power generation mode proposed abroad.

The components in the figure are marked as: the wind collection shell comprises a wind collection shell (1), an air inlet (1.1), a gradually-enlarged section (1.2), an expansion section (1.3), a gradually-leveled section (1.4), a horizontal section (1.5), an air outlet (1.6), a wind collection shell stiffening ring (2), a tower cylinder (3), a fan blade (4), a generator (5), a solar photovoltaic panel (6), a floating platform (7), a wind generating set component (8), a floating cylinder (9), a balance floating cylinder (10), a support (11), an opening support frame (12), a support piece (13), a first support rod (14.1) and a first support rod (14.2). The arrows indicate the direction of the wind.

Detailed Description

See fig. 1, fig. 2, fig. 3, fig. 4, fig. 5, fig. 6, fig. 7, fig. 8, fig. 9.

The utility model discloses an integrated high-efficiency ocean wind power station, which comprises a wind collecting device, a power generating device, a floating device and a bracket 11;

the power generation device is arranged in the wind collecting device;

the bracket 11 is stably arranged on the floating device;

the wind collecting device is arranged in the bracket body of the bracket 11 and is fixedly connected with the floating device through the bracket 11;

the wind collecting device comprises a wind collecting shell 1 and a tower barrel 3;

the wind collecting shell 1 is arranged into a cylindrical hollow cavity; a tower barrel 3 is fixedly connected to the bottom of the wind collecting shell 1, and the tower barrel 3 penetrates or extends to the central position of the cavity of the wind collecting shell 1 [ the central position of the cavity of the wind collecting shell 1 refers to the central line position when the wind collecting shell 1 is vertically placed ];

the power generation device; the central shaft is fixedly arranged on the wind collecting shell 1 and is fixedly arranged on the tower barrel 3; the power generation device comprises a fan blade 4; the fan blades 4 are fixedly arranged inside the wind collecting shell 1;

the flotation device comprises a flotation platform 7.

Further, the air collecting shell 1 of the utility model sequentially comprises an air inlet 1.1, a gradually enlarged section 1.2, an amplification section 1.3, a gradually flat section 1.4, a horizontal section 1.5 and an air outlet 1.6; the inner diameters of the gradually enlarging section 1.2, the amplifying section 1.3, the gradually flattening section 1.4 and the horizontal section 1.5 are sequentially increased.

Further, the wind collecting shell 1 is horizontally arranged; a fan blade 4 in the power generation device is arranged at a horizontal section 1.5 of the wind collecting shell 1; the wind collecting device also comprises an opening support frame 12, wherein the opening support frame 12 is arranged at the position of the wind inlet 1.1 or at the positions of the wind inlet 1.1 and the wind outlet 1.6 respectively.

Furthermore, the opening support frame 12 is composed of a plurality of support pieces 13, the support pieces 13 are in a fish shape, the fish heads of the support pieces are fixed at one position in a concentrated manner, and the fish tails of the support pieces are respectively fixed on the inner wall of the wind collecting shell 1.

Further, the wind collecting device also comprises a wind collecting shell stiffening ring 2; the number of the wind collecting shell stiffening rings 2 is set to be a plurality of, and the wind collecting shell stiffening rings are respectively and fixedly arranged on the air inlet 1.1, the gradually enlarged section 1.2, the amplification section 1.3, the gradually flat section 1.4, the horizontal section 1.5 and the air outlet 1.6.

Further, the tower drum 3 is vertically arranged; when the wind collecting shell 1 is horizontally arranged, the gravity line of the wind collecting shell 1 is inosculated with the tower barrel 3 which is vertically arranged.

Furthermore, the power generation device also comprises a power generator 5, a wind generating set component 8, wires, cables and an accommodating bin body;

the accommodating bin body is in a shuttle shape; the generator 5 and the wind generating set part 8 are arranged in the shuttle-shaped accommodating bin body; the fan blades 4 are fixedly arranged at the tail end of the shuttle-shaped containing bin body, the fan blades 4 rotate around the tail end of the containing bin body as the circle center, and the number of the fan blades 4 is 5-6; the fan blade 4 is connected with the generator 5 through an electric wire; the generator 5 is connected with the wind generating set component 8 through an electric wire; the wind generating set component 8 outputs power through a cable; the cable sets up and links out after arranging in the barrel of a tower section of thick bamboo 3.

Furthermore, the power generation device also comprises a solar photovoltaic panel 6, a first supporting rod 14.1 and a second supporting rod 14.2; the solar photovoltaic panel 6, the first supporting rod 14.1 and the second supporting rod 14.2 are all fixedly arranged at the top of the floating platform 7 or/and the bracket 11; the length of the first strut 14.1 is shorter than that of the second strut 14.2; the first supporting rod 14.1 is fixedly arranged in the middle of the solar photovoltaic panel 6; the second supporting rod 14.2 is fixedly arranged at the end part of the solar photovoltaic panel 6; the other end of the solar photovoltaic panel 6 is contacted with the floating platform 7 or/and the top of the bracket 11; the inclined plane formed by the solar photovoltaic panel 6 and the horizontal plane faces the sun.

Further, the floating device of the utility model also comprises a buoy 9 and a balance buoy 10; the buoy 9 is of an oval cavity structure, the edge of the buoy is smooth, and the buoy is uniformly fixed and symmetrically arranged at the bottom of the floating platform 7; the balance buoy 10 is arranged to be a cubic hollow cavity or a cylindrical hollow cavity, and is fixedly, uniformly and symmetrically arranged at the side edge position of the bottom of the floating platform 7.

Further, the wind power plant of the utility model also comprises a fixing device; the fixing device comprises a rope and an anchor; one end of the rope is fixedly connected with the floating device; the other end of the rope is fixedly connected with an anchor; the anchor is arranged at the water bottom.

In the engineering design and construction process, the utility model fully considers various conditions and possible factors, and finally integrates the conditions and the possible factors into a whole to form the integrated high-efficiency ocean wind power station. The method specifically comprises the following steps: 1) the wind driven generator is provided with the wind collecting cover, the number of the blades is changed from a three-blade mode to a multi-blade mode (five to six blades), the wind collecting cover is helpful, and the generating efficiency of the wind driven generator can break through Betz limit control, is improved by 60 percent and reaches more than 80 percent.

2) In order to further reduce the construction cost, the integral structure of the floating platform can be composed of light steel trusses, and the buoyancy of the floating platform is provided by the floating barrels.

3) The wind-collecting cover is installed in a split mode, the consideration of comprehensive practicability, feasibility and economy is achieved, and glass fiber reinforced plastics can be selected as manufacturing materials of the wind-collecting cover.

4) In order to enable the wind power station to adapt to wind in different wind directions, a power propulsion device can be arranged on the tutoring platform.

5) Other supporting equipment for wind power generation and photovoltaic power generation can be conventional equipment.

6) In order to ensure the stability of the whole power station platform, balance buoys are respectively arranged at the head part and the tail part, the balance buoys at the front end in the downwind direction are filled with water, and the balance buoys at the tail end in the downwind direction are filled with air to provide anti-overturning balance moment when a fan works;

7) in order to fully utilize the plane space of the floating platform, a solar cell panel can be laid on the platform, and wind and light integrated power generation is realized;

8) in order to reduce the construction risk and shorten the construction period, the wind power station can be hauled or self-navigated to a designated sea area to put into production and generate electricity after the construction is finished;

9) the integrated high-efficiency ocean wind power station is not only suitable for offshore sea areas, but also suitable for deep and open sea;

10) in order to shorten the construction period and facilitate the overhaul and maintenance, the whole floating platform can be constructed in an assembly type mode.

The above description is only a specific embodiment of the present invention, and the common general knowledge of the known specific structures and characteristics in the schemes is not described herein too much. It should be noted that, for those skilled in the art, without departing from the structure of the present invention, several changes and modifications can be made, which should also be regarded as the protection scope of the present invention, and these will not affect the effect of the implementation of the present invention and the practicability of the patent. The scope of the claims of the present application shall be determined by the contents of the claims, and the description of the embodiments and the like in the specification shall be used to explain the contents of the claims.

Claims (10)

1. Integrated high efficiency marine wind power plant, characterised in that it comprises wind collecting means, power generating means, floating means and a support (11); the power generation device is arranged in the wind collecting device; the bracket (11) is stably arranged above the floating device; the wind collecting device is arranged in the bracket body of the bracket (11), and is fixedly connected with the floating device through the bracket (11); the wind collecting device comprises a wind collecting shell (1) and a tower barrel (3); the wind collecting shell (1) is arranged into a cylindrical hollow cavity; the lower bottom of the wind collecting shell (1) is fixedly connected with a tower drum (3), and the tower drum (3) penetrates or extends to the center of the cavity of the wind collecting shell (1); the power generation device; the central shaft is fixedly arranged on the wind collecting shell (1) and is fixedly arranged on the tower barrel (3); the power generation device comprises a fan blade (4); the fan blades (4) are fixedly arranged inside the wind collecting shell (1); the floating device comprises a floating platform (7).

2. The integrated high-efficiency marine wind power plant according to claim 1, wherein the wind-collecting housing (1) comprises an air inlet (1.1), an enlarged section (1.2), an enlarged section (1.3), a flat section (1.4), a horizontal section (1.5) and an air outlet (1.6) in sequence; the inner diameters of the gradually enlarging section (1.2), the amplifying section (1.3), the gradually flattening section (1.4) and the horizontal section (1.5) are sequentially increased.

3. An integrated high efficiency marine wind power plant according to claim 2, wherein the wind-collecting housing (1) is horizontally arranged; a fan blade (4) in the power generation device is arranged on a horizontal section (1.5) of the wind collecting shell (1); the wind collecting device also comprises an opening support frame (12), wherein the opening support frame (12) is arranged at the position of the wind inlet (1.1) or at the positions of the wind inlet (1.1) and the wind outlet (1.6) respectively.

4. The integrated high-efficiency marine wind power plant according to claim 3, characterized in that the opening support frame (12) is composed of a plurality of support pieces (13), the support pieces (13) are shaped like fish, the fish heads of the support pieces are fixed at one position in a concentrated manner, and the fish tails of the support pieces are respectively fixed on the inner wall of the wind collecting shell (1).

5. An integrated high efficiency marine wind power plant according to claim 2 or 3, wherein said wind collecting means further comprises a wind collecting shell stiffening ring (2); the number of the wind collecting shell stiffening rings (2) is set to be a plurality of, and the wind collecting shell stiffening rings are respectively and fixedly arranged on the air inlet (1.1), the gradually enlarged section (1.2), the amplification section (1.3), the gradually flat section (1.4), the horizontal section (1.5) and the air outlet (1.6).

6. An integrated high efficiency marine wind power plant according to claim 3, characterized in that the tower (3) is arranged vertically; when the wind collecting shell (1) is horizontally arranged, the gravity center line of the wind collecting shell (1) is inosculated with the tower barrel (3) which is vertically arranged.

7. The integrated high efficiency marine wind power plant according to claim 1 wherein said power plant further comprises a generator (5), wind turbine components (8), wires, cables and containment silos;

the accommodating bin body is in a shuttle shape; the generator (5) and the wind generating set component (8) are arranged in the shuttle-shaped accommodating cabin body; the fan blades (4) are fixedly arranged at the tail end of the shuttle-shaped containing bin body, the fan blades (4) rotate around the tail end of the containing bin body, and the number of the fan blades (4) is 5-6; the fan blade (4) is connected with the generator (5) through a wire; the generator (5) is connected with the wind generating set component (8) through an electric wire; the wind generating set component (8) outputs power through a cable; the cable is arranged in the cylinder body of the tower cylinder (3) and then connected out.

8. The integrated high efficiency marine wind power plant according to claim 1, wherein the power plant further comprises a solar photovoltaic panel (6), a first strut (14.1), a second strut (14.2); the solar photovoltaic panel (6), the first supporting rod (14.1) and the second supporting rod (14.2) are fixedly arranged at the tops of the floating platform (7) or/and the bracket (11); the length of the first strut (14.1) is shorter than that of the second strut (14.2); the first supporting rod (14.1) is fixedly arranged in the middle of the solar photovoltaic panel (6); the second supporting rod (14.2) is fixedly arranged at the end part of the solar photovoltaic panel (6); the other end of the solar photovoltaic panel (6) is contacted with the floating platform (7) or/and the top of the bracket (11); the inclined plane formed by the solar photovoltaic panel (6) and the horizontal plane faces the sun.

9. An integrated high efficiency marine wind power plant according to claim 1 wherein the flotation means further comprises a buoy (9) and a balance buoy (10); the buoy (9) is of an oval cavity structure, the edge of the buoy is smooth, and the buoy is uniformly fixed and symmetrically arranged at the bottom of the floating platform (7); the balance buoy (10) is arranged to be a cubic hollow cavity or a cylindrical hollow cavity, and is fixedly, uniformly and symmetrically arranged at the side edge position of the bottom of the floating platform (7).

10. An integrated high efficiency marine wind power plant according to claim 1, characterised in that the wind power plant further comprises a fixture; the fixing device comprises a rope and an anchor; one end of the rope is fixedly connected with the floating device; the other end of the rope is fixedly connected with an anchor; the anchor is arranged at the water bottom.

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