CN110792559A

CN110792559A - Amphibious wind power generation device

Info

Publication number: CN110792559A
Application number: CN201911032303.0A
Authority: CN
Inventors: 刘子豪
Original assignee: Individual
Current assignee: Individual
Priority date: 2019-10-28
Filing date: 2019-10-28
Publication date: 2020-02-14

Abstract

The invention discloses an amphibious wind power generation device, which comprises a shell, a generator and a first fan wheel, wherein the shell is provided with a first fan wheel; the first fan wheel comprises a plurality of fan blades, a reinforcing ring and a fan shaft, wherein the fan blades are in a semicircular sheet structure, the fan blades are all fixed on the fan shaft, the fan blades are arranged around the axis of the fan shaft in an annular array mode, each fan blade extends along the radial direction of the fan shaft, and the reinforcing ring is fixed on the position, located between each fan blade and the shell, on the fan shaft; the casing is internally provided with a hollow accommodating cavity, the generator is arranged in the accommodating cavity, a rotating shaft of the generator is in transmission connection with a fan shaft of the first fan wheel, the reinforcing ring is in rotation connection with the casing, and the axis of the fan shaft is perpendicular to the horizontal plane. Aims to solve the problems of low efficiency, complex structure and single function of wind power generation devices in the prior art. The effect is as follows: through the plurality of semicircular fan blades, the wind power collection efficiency is improved, so that the power generation efficiency is improved; through setting up the beaded finish, improved the mechanical strength and the life of fan wheel.

Description

Amphibious wind power generation device

Technical Field

The embodiment of the invention relates to the technical field of power generation devices, in particular to an amphibious wind power generation device.

Background

The wind power generation device in the prior art is large in structural size, low in power generation efficiency and relatively fixed in use occasion, the fan wheel of the existing wind power generator occupies a large space and can be driven to rotate by large wind power, and the land power generator and the water power generation connection structure are poor in universality, so that the wind power generation device which is small in structural size and high in conversion efficiency and the wind power generation device for amphibious use are lacked.

Disclosure of Invention

Therefore, the embodiment of the invention provides an amphibious wind power generation device, which aims to solve the problems of low efficiency, complex structure and single function of a wind power generation device in the prior art.

In order to achieve the above object, the embodiments of the present invention provide the following technical solutions:

according to a first aspect of an embodiment of the present invention, an amphibious wind power plant comprises a hull, a generator and a first impeller; the first fan wheel comprises a plurality of fan blades, a reinforcing ring and a fan shaft, wherein the fan blades are in a semicircular sheet structure, the fan blades are all fixed on the fan shaft, the fan blades are arranged around the axis of the fan shaft in an annular array mode, each fan blade extends along the radial direction of the fan shaft, and the reinforcing ring is fixed on the position, located between each fan blade and the shell, on the fan shaft; the casing is internally provided with a hollow accommodating cavity, the generator is arranged in the accommodating cavity, a rotating shaft of the generator is in transmission connection with a fan shaft of the first fan wheel, the reinforcing ring is in rotation connection with the casing, and the axis of the fan shaft is perpendicular to the horizontal plane.

Furthermore, the first fan wheel further comprises a plurality of reinforcing ribs, one end of each reinforcing rib is fixed to the fan shaft, the other end of each reinforcing rib is fixed to the inner side face of the reinforcing ring, the extending direction of each reinforcing rib is the radial direction of the fan shaft, and the plurality of reinforcing ribs are arranged around the fan shaft in an even annular array mode.

Furthermore, the fan wheel bearing further comprises a fan wheel bearing, an inner ring of the fan wheel bearing is fixedly connected with the outer peripheral side of the reinforcing ring, and an outer ring of the fan wheel bearing is fixedly connected with the shell.

Further, the fan comprises a plurality of propellers, each propeller is rotatably connected to the vertical outer side wall of the shell, the axis of the rotating shaft of each propeller is perpendicular to the axis of the fan shaft, and the propellers are uniformly arrayed on the outer peripheral side of the shell.

Further, the device also comprises a controller, a wind vane, a rotary encoder and a position switch; the wind vane consists of a vane and a wind wheel, the vane is used for indicating the wind direction, and the wind wheel is used for detecting the wind speed; a position switch is arranged on the driving motor of each propeller, and the vane is used for triggering the position switch; the rotating shaft of the wind wheel is connected with the rotating shaft of the rotary encoder, and the position switch, the rotary encoder and the driving motor of the propeller are electrically connected with the controller.

The structure of the second fan wheel is the same as that of the first fan wheel, a fan shaft of the second fan wheel is in transmission connection with a rotating shaft of the generator, and a reinforcing ring of the second fan wheel is in rotary connection with the shell; the second impeller and the first impeller are symmetrically disposed about a horizontal plane of symmetry of the housing.

The reversing input shaft is in transmission connection with a rotating shaft of the generator, one reversing output shaft of the gear reverser is in transmission connection with a fan shaft of the first fan wheel, and the other reversing output shaft of the gear reverser is in transmission connection with a fan shaft of the second fan wheel.

Further, the screw propeller is located the downside of the central symmetry plane of casing vertical direction, and first impeller is located the central symmetry plane upside of casing vertical direction, and the second impeller is located the downside of screw propeller.

Furthermore, the first fan wheels are multiple, the vane is located in the center of the shell, and the first fan wheels are arranged around the vane in an even array mode.

Further, the buoyancy generated in the water by the accommodating chamber in the housing is greater than the total gravity of all the components mounted on the housing.

The invention has the following advantages: through the plurality of semicircular fan blades, the wind power collection efficiency is improved, so that the power generation efficiency is improved; by arranging the reinforcing ring, the mechanical strength and the service life of the fan wheel are improved, and the application of the device in various occasions is realized; the first fan wheel and the second fan wheel which are symmetrical to each other are arranged, amphibious power generation is achieved, and the propeller is arranged, so that the device is prevented from being blown away by wind in water.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below. It should be apparent that the drawings in the following description are merely exemplary, and that other embodiments can be derived from the drawings provided by those of ordinary skill in the art without inventive effort.

The structures, ratios, sizes, and the like shown in the present specification are only used for matching with the contents disclosed in the specification, so as to be understood and read by those skilled in the art, and are not used to limit the conditions that the present invention can be implemented, so that the present invention has no technical significance, and any structural modifications, changes in the ratio relationship, or adjustments of the sizes, without affecting the effects and the achievable by the present invention, should still fall within the range that the technical contents disclosed in the present invention can cover.

Fig. 1 is a cross-sectional structural view of an amphibious wind power generation apparatus according to some embodiments of the present invention.

Fig. 2 is a perspective structural view of the amphibious wind power generation device provided in fig. 1.

Fig. 3 is a structural diagram of a first fan wheel or a second fan wheel of an amphibious wind power generation device according to some embodiments of the present invention.

Fig. 4 is a cross-sectional structural view of an amphibious wind power generation device according to another embodiment of the present invention.

Fig. 5 is a top view of the amphibious wind power generation device provided in fig. 4.

Fig. 6 is a perspective view of an amphibious wind power generation device provided in fig. 4.

Fig. 7 is a cross-sectional structural view of an amphibious wind power generation apparatus according to still further embodiments of the present invention.

Fig. 8 is a top view of an amphibious wind power plant provided in fig. 7.

In the figure: 1. the wind power generation device comprises a generator, 2, a first fan wheel, 3, fan blades, 4, a reinforcing ring, 5, a fan shaft, 6, a fan wheel bearing, 7, a shell, 8, a propeller, 9, reinforcing ribs, 10, a gear commutator, 11, a vane, 12 and a wind wheel.

Detailed Description

The present invention is described in terms of particular embodiments, other advantages and features of the invention will become apparent to those skilled in the art from the following disclosure, and it is to be understood that the described embodiments are merely exemplary of the invention and that it is not intended to limit the invention to the particular embodiments disclosed. 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.

The invention relates to a spherical-appearance power generation device, wherein a power storage device is arranged at the bottom or the middle part of the power generation device, a light and thin fan sheet 3 can accelerate to run, the power generation device is placed on the sea level and floats on the water surface like a buoy, a fan can be run by slight sea wind, and a fan can be placed below the water surface at the same time, so that the power generation device can run by the fluctuation of water, the power generation device can be reduced and placed on the position, close to a neon lamp, of a wall of a building, so that high buildings can be bright and colorful at night after being continuously stored for twenty-four hours a day, the power generation device can be placed on the sea edge along the sea in an enlarged manner, and the power storage cannot be blown off no matter how powerful the typhoon is, in addition, the part of electrical energy can be used for garbage incineration and seawater electrolysis to produce hydrogen, and the power generation device can also be placed on the top of the high buildings in; after the device is reduced, the device can be placed on a balcony, an eave and a glass guardrail at home so as to supply household electricity, and offshore electricity storage can be used for special equipment such as an offshore oil field, a ship and the like.

Example 1

As shown in fig. 1 to 3, an amphibious wind power generation apparatus in the present embodiment includes a hull 7, a generator 1, and a first fan wheel 2; the first fan wheel 2 comprises a plurality of fan blades 3, a reinforcing ring 4 and a fan shaft 5, wherein the fan blades 3 are in a semicircular sheet structure, the fan blades 3 are all fixed on the fan shaft 5, the fan blades 3 are arranged around the axis of the fan shaft 5 in an annular array mode, each fan blade 3 extends along the radial direction of the fan shaft 5, and the reinforcing ring 4 is fixed on the fan shaft 5 and located between the fan blades 3 and the shell 7; be provided with hollow chamber that holds in the casing 7, generator 1 sets up and is holding the intracavity, the pivot of generator 1 is connected with the transmission between the fan shaft 5 of first fan wheel 2, beaded finish 4 rotates with casing 7 to be connected, the axis perpendicular to horizontal plane of fan shaft 5, preferably, the inside chamber that holds of casing 7 in this embodiment is seal structure, when placing the device of this embodiment in aqueous, realize that it floats on water, when fan piece 3 is the metal material, a plurality of fan piece 3 welds on fan shaft 5, beaded finish 4 and a plurality of fan piece 3 between the welding.

In a specific embodiment, as shown in fig. 2, the housing 7 is a hexahedral hollow structure, four first fan wheels 2 are arranged on the upper surface of the housing 7, each first fan wheel 2 is connected with the generator 1, a sealing ring is arranged at the joint of the reinforcing ring 4 of the first fan wheel 2 and the housing 7, and the axis of the fan shaft 5 is perpendicular to the upper surface of the housing 7.

The technical effect that this embodiment reaches does: through the plurality of semicircular fan blades 3, the wind power collection efficiency is improved, so that the power generation efficiency is improved; by arranging the reinforcing ring 4, the mechanical strength and the service life of the fan wheel are improved, and the application of the device in various occasions is realized.

Example 2

As shown in fig. 1 to 8, the amphibious wind power generation device in this embodiment includes all the technical features of embodiment 1, in addition, the first fan wheel 2 further includes a plurality of reinforcing ribs 9, one end of each reinforcing rib 9 is fixed on the fan shaft 5, the other end of each reinforcing rib 9 is fixed on the inner side surface of the reinforcing ring 4, the extending direction of each reinforcing rib 9 is the radial direction of the fan shaft 5, and the plurality of reinforcing ribs 9 are uniformly and annularly arranged around the fan shaft 5; the fan-shaped blade bearing further comprises a fan-shaped wheel bearing 6, an inner ring of the fan-shaped wheel bearing 6 is fixedly connected with the outer peripheral side of the reinforcing ring 4, an outer ring of the fan-shaped wheel bearing 6 is fixedly connected with the shell 7, for example, as shown in fig. 3, the reinforcing ribs 9 are of a rectangular plate-shaped structure, one ends of the reinforcing ribs 9 are welded on the outer peripheral side of the fan shaft 5, the other ends of the reinforcing ribs 9 are welded on the inner side wall of the reinforcing ring 4, the width of the reinforcing ribs 9 is smaller than the thickness of the reinforcing ring 4, the number of the reinforcing ribs 9 is the same as that of the fan blades 3, an included angle between every two adjacent reinforcing ribs 9 is the same as that between every two.

The beneficial effects in this embodiment are: by arranging the reinforcing ribs 9, the mechanical strength of the reinforcing ring 4 is enhanced, and the service life of the reinforcing ring 4 is obviously prolonged; the connection strength between the fan sheets 3 and the fan shaft 5 is enhanced by setting the included angle between the adjacent reinforcing ribs 9 and the included angle between the adjacent fan sheets 3 to be the same.

Example 3

As shown in fig. 4 to 8, an amphibious wind power generation device in this embodiment includes all the technical features of embodiment 2, and in addition, includes a plurality of propellers 8, each propeller 8 is rotatably connected to a vertical outer side wall of the hull 7, an axis of a rotating shaft of each propeller 8 is perpendicular to an axis of the fan shaft 5, the plurality of propellers 8 are uniformly arrayed on an outer peripheral side of the hull 7, the propeller 8 in this embodiment has a plurality of helical blades, in some alternative embodiments, when the hull 7 is a hexahedron, the propellers 8 are respectively arranged on the periphery of the hull 7, wherein one propeller 8 is installed on each surface of the hull 7; the wind vane type wind power generation device also comprises a controller, a wind vane, a rotary encoder and a position switch; the controller is a single chip microcomputer or a PLC (programmable logic controller), the vane consists of vanes 11 and wind wheels 12, the vanes 11 are rotatably connected to the shell 7, the wind wheels 12 are of a spoon-shaped structure with a plurality of hemispherical shells, the wind wheels 12 are rotatably connected to rotating shafts of the vanes 11, the vanes 11 are used for indicating wind directions, and the wind wheels 12 are used for detecting wind speeds; a position switch is arranged on a driving motor of each propeller 8, and a vane 11 is used for triggering the position switch; the rotating shaft of the wind wheel 12 is connected with the rotating shaft of the rotary encoder, and the position switch, the rotary encoder and the driving motor of the propeller 8 are electrically connected with the controller.

The theory of operation of this embodiment does, when power generation facility is in aqueous, when wind blows, vane 11 rotates the switch that triggers the ascending screw 8 of wind direction, screw 8 rotates, screw 8 promotes casing 7 towards the opposite direction of wind direction, and simultaneously, the rotation of wind wheel 12 drives rotary encoder rotatory, rotary encoder is with rotational speed signal transmission to controller, the controller sends out the rotational speed of instruction control screw 8, along with the increase of wind-force, the rotational speed of the screw 8 that corresponds increases, equally, along with the reduction of wind-force, the rotational speed of the screw 8 that corresponds reduces.

The beneficial effects in this embodiment are: by arranging the propeller 8, the shell 7 can move in a specified range, the power generation device is prevented from floating to a place which cannot be found along with wave flow by flow, and the maintenance difficulty is reduced; through setting up the controller, realized 8 rotational speeds of screw and the intelligent control of opening time, realized power generation facility activity in appointed scope automatically.

Example 4

As shown in fig. 7 and 8, the amphibious wind power generation device in this embodiment includes all the technical features of embodiment 3, and in addition, includes a second fan wheel, the structure of the second fan wheel is the same as that of the first fan wheel 2, a fan shaft 5 of the second fan wheel is in transmission connection with a rotating shaft of the generator 1, and a reinforcing ring 4 of the second fan wheel is in rotational connection with a housing 7; the second impeller and the first impeller 2 are arranged symmetrically with respect to the horizontal symmetry plane of the casing 7; the gear reverser 10 is further included, for example, the gear reverser 10 is a bevel gear reverser, the gear reverser 10 has a reversing input shaft and two reversing output shafts, the two reversing output shafts are coaxially arranged, the axes of the two reversing output shafts are perpendicular to the axis of the reversing input shaft, the reversing input shaft is in transmission connection with a rotating shaft of the generator 1, one reversing output shaft of the gear reverser 10 is in transmission connection with the sector shaft 5 of the first sector wheel 2, and the other reversing output shaft of the gear reverser 10 is in transmission connection with the sector shaft 5 of the second sector wheel; the propeller 8 is located on the lower side of the central symmetry plane in the vertical direction of the housing 7, the first fan wheel 2 is located on the upper side of the central symmetry plane in the vertical direction of the housing 7, and the second fan wheel is located on the lower side of the propeller 8.

The beneficial effects in this embodiment are: through setting up first impeller 2 and the second impeller of mutual symmetry, realized that amphibious's electricity generation is used, through setting up the second impeller, the reasonable dark current that has utilized the aquatic generates electricity, is showing and is improving power generation facility's generating efficiency, through setting up screw 8, has avoided this device to be blown away by wind in the aquatic.

Example 5

As shown in fig. 1 to 8, the amphibious wind power generation device in this embodiment includes all the technical features of embodiment 4, in addition, the number of the first fan wheels 2 is multiple, correspondingly, each first fan wheel 2 is connected with one generator 1, the wind vane is located at the center position of the housing 7, and the multiple first fan wheels 2 are uniformly arranged around the wind vane in an array; the buoyancy generated by the accommodating cavity in the shell 7 in water is larger than the total weight of all components mounted on the shell 7, in addition, a storage battery is also arranged in the shell 7 and used for storing electric energy, a GPS positioning module is also arranged on the upper surface of the shell 7, and the storage battery supplies power for the GPS positioning module; in addition, a plurality of guide grooves which are inclined downwards outwards from the middle of the upper surface of the shell 7 are arranged on the upper surface of the shell 7, so that the water accumulation on the upper surface of the shell 7 is avoided.

The beneficial effects in this embodiment are: by arranging the first fan wheels 2, the power generation efficiency of the power generation device is improved; through setting up the battery, realized the storage to the generating electricity, through setting up the GPS module, realized the pursuit when marine use to power generation facility, avoided the emergence that power generation facility lost the condition.

Although the invention has been described in detail above with reference to a general description and specific examples, it will be apparent to one skilled in the art that modifications or improvements may be made thereto based on the invention. Accordingly, such modifications and improvements are intended to be within the scope of the invention as claimed.

In the present specification, the terms "upper", "lower", "left", "right", "middle", and the like are used for clarity of description, and are not intended to limit the scope of the present invention, and changes or modifications in the relative relationship may be made without substantial changes in the technical content.

Claims

1. An amphibious wind power generation device is characterized by comprising a shell (7), a generator (1) and a first fan wheel (2); the first fan wheel (2) comprises a plurality of fan blades (3), a reinforcing ring (4) and a fan shaft (5), the fan blades (3) are of a semicircular sheet structure, the fan blades (3) are all fixed on the fan shaft (5), the fan blades (3) are arranged around the axis of the fan shaft (5) in an annular array mode, each fan blade (3) extends along the radial direction of the fan shaft (5), and the reinforcing ring (4) is fixed on the fan shaft (5) and located between the fan blades (3) and the shell (7); the fan is characterized in that a hollow accommodating cavity is formed in the shell (7), the generator (1) is arranged in the accommodating cavity, a rotating shaft of the generator (1) is in transmission connection with the fan shaft (5) of the first fan wheel (2), the reinforcing ring (4) is in rotation connection with the shell (7), and the axis of the fan shaft (5) is perpendicular to the horizontal plane.

2. An amphibious wind power plant according to claim 1, characterised in that said first wheel (2) further comprises a plurality of stiffeners (9), one end of each stiffener (9) is fixed to said fan shaft (5), the other end of each stiffener (9) is fixed to the inner side of said stiffening ring (4), the extension direction of each stiffener (9) is the radial direction of said fan shaft (5), and a plurality of stiffeners (9) are arranged in a uniform annular array around said fan shaft (5).

3. An amphibious wind power plant according to claim 1, characterised in that it further comprises a fan bearing (6), the inner ring of the fan bearing (6) being fixedly connected to the outer peripheral side of the reinforcement ring (4), and the outer ring of the fan bearing (6) being fixedly connected to the hull (7).

4. An amphibious wind power plant according to claim 1, further comprising a plurality of propellers (8), each propeller (8) being rotatably connected to a vertical outer side wall of said hull (7), the axis of rotation shaft of each propeller (8) being perpendicular to the axis of said fan shaft (5), a plurality of said propellers (8) being evenly arrayed on the outer peripheral side of said hull (7).

5. An amphibious wind power plant according to claim 4, further comprising a controller, a wind vane, a rotary encoder and a position switch; the wind vane consists of a wind vane (11) and a wind wheel (12), wherein the wind vane (11) is used for indicating the wind direction, and the wind wheel (12) is used for detecting the wind speed; the position switch is arranged on the driving motor of each propeller (8), and the vane (11) is used for triggering the position switch; the rotating shaft of the wind wheel (12) is connected with the rotating shaft of the rotary encoder, and the position switch, the rotary encoder and the driving motor of the propeller (8) are electrically connected with the controller.

6. An amphibious wind power plant according to claim 5, characterised in that it further comprises a second fan wheel, the structure of which is the same as that of the first fan wheel (2), the fan shaft (5) of which is in driving connection with the rotation shaft of the generator (1), and the stiffening ring (4) of which is in rotational connection with the hull (7); the second impeller and the first impeller (2) are arranged symmetrically with respect to a horizontal plane of symmetry of the housing (7).

7. An amphibious wind power plant according to claim 6, further comprising a gear reverser (10), said gear reverser 10 having a reversing input shaft and two reversing output shafts, both of said reversing output shafts being coaxially arranged and perpendicular to the axis of said reversing input shaft, said reversing input shaft being in driving connection with the rotating shaft of said generator (1), one reversing output shaft of said gear reverser 10 being in driving connection with the sector shaft (5) of said first sector wheel (2), the other reversing output shaft of said gear reverser 10 being in driving connection with the sector shaft (5) of said second sector wheel.

8. An amphibious wind power plant according to claim 6, where said propeller (8) is located at the lower side of the central symmetry plane in the vertical direction of said hull (7), said first fan wheel (2) is located at the upper side of the central symmetry plane in the vertical direction of said hull (7), and said second fan wheel is located at the lower side of said propeller (8).

9. An amphibious wind power plant according to claim 5, characterised in that said first plurality of wheels (2) is arranged in a number, that said vane is located in a central position of said hull (7), and that said first plurality of wheels (2) is arranged in a uniform array around said vane.

10. An amphibious wind power plant according to claim 1, characterised in that the buoyancy generated in the water by the accommodation chamber in the hull (7) is larger than the total gravity of all components mounted on the hull (7).