CN117145695A - Flabellum-free wind power generation structure - Google Patents

Abstract

The invention provides a flabellum-free wind power generation structure which comprises a flabellum body and a bottom plate, wherein the bottom end of the flabellum body is connected with a mast, the bottom end of the mast is provided with a sealed round box, the bottom end of the sealed round box is connected with an upright cylinder, the upright cylinder is fixedly arranged at the top end of the bottom plate, a conductive cylinder is arranged at the center of the top end of the bottom plate and is positioned in the upright cylinder, a magnet mechanism is arranged in the sealed round box and comprises a pair of permanent magnets and a pair of magnetic damping bodies, the pair of permanent magnets are respectively arranged in the sealed round box, the pair of magnetic damping bodies are respectively sleeved on two sides of the outer wall of the conductive cylinder, the pair of permanent magnets and the pair of magnetic damping bodies are respectively positioned on the same horizontal plane, the outer wall of the conductive cylinder is provided with a cutting magnetic induction line mechanism, and the cutting magnetic induction line mechanism comprises a first coil, a second coil, a third coil and a fourth coil.

Description

Flabellum-free wind power generation structure

Technical Field

The invention relates to the technical field of wind power generation, in particular to a flabellum-free wind power generation structure.

Background

Wind is one of nuisanceless energy sources, is inexhaustible, is very suitable for locally and conveniently utilizing wind power generation for coastal islands, grassland pasture areas, mountain areas and highland areas which are lack of water, fuel and inconvenient in transportation, and can be widely regarded as one of important components of new energy sources along with the continuous development and progress of new energy source technology in recent years.

At present, the most main fan principle is that wind power is utilized to drive fan blades to rotate, and then the rotation speed is increased through a speed increaser, so that a generator is driven to generate electricity, however, the wind power generator which drives the blades to rotate needs to occupy a larger space area, and the assembly operation can be completed only by matching with a heavy crane, so that the assembly operation is more labor-consuming; second, the rotating blades may also cause injury to birds that inhabit nearby, thereby affecting the ecological environment.

Disclosure of Invention

The embodiment of the invention provides a flabellum-free wind power generation structure which is used for solving the problems set forth in the background technology.

In view of the above problems, the technical scheme provided by the invention is as follows:

the utility model provides a no flabellum wind power generation structure, includes flabellum body and bottom plate, the bottom of flabellum body is connected with the mast, the bottom of mast is equipped with sealed circle box, the bottom of sealed circle box is connected with upright section of thick bamboo, upright section of thick bamboo fixed mounting is in the top of bottom plate, the top central point of bottom plate puts and installs conductive tube, conductive tube is located the inside of upright section of thick bamboo, the inside of sealed circle box is equipped with magnet mechanism, magnet mechanism includes a pair of permanent magnet and a pair of magnetic damping body, a pair of the permanent magnet is installed respectively in the inside of sealed circle box, a pair of the magnetic damping body suit is in respectively in the outer wall both sides of conductive tube, a pair of permanent magnet and a pair of magnetic damping body are in same as the horizontal plane respectively, the outer wall of conductive tube is equipped with cutting magnetic induction line mechanism, cutting magnetic induction line mechanism includes first coil, second coil, third coil and fourth coil suit is in the outside of second coil.

In order to better realize the technical scheme of the invention, the following technical measures are adopted.

Further, the first coil and the second coil are in the same horizontal plane and form a first cutting coil, and the third coil and the fourth coil are in the same horizontal plane and form a second cutting coil.

Further, a gap is arranged between the bottom end of the first cutting coil and the top end of the second cutting coil, and the size range of the gap is 0.5-1.5 mm.

Further, the connection part of the fan blade body and the mast is provided with a swing mechanism, the swing mechanism comprises a top circular plate, a bottom circular plate, a plurality of reinforcing piles, a connecting seat and a cable, the top circular plate is connected with the bottom circular plate in a penetrating way, the connecting seat is installed at the center of the bottom end of the bottom circular plate, and the bottom end of the connecting seat is connected with the cable.

Further, the bottom end of the cable penetrates through the electric guiding torch and is connected with the top end of the bottom plate.

Further, the bottom plate includes plate body, ring channel, electric conduction groove, anti layering and screw hole, the surface of plate body sets up ring channel and electric conduction groove respectively, be equipped with the insulating layer between ring channel and the electric conduction groove, electric connection between the electric conduction groove with the electric conduction section of thick bamboo, the bottom of standing a straight section of thick bamboo extends to the inside of ring channel, the internally mounted of plate body has a plurality of anti layering, the corner of plate body sets up the screw hole respectively.

Further, the sealed round box comprises a box body, a top cover and a bottom cover, wherein the top cover is arranged at the top end of the box body, the top end of the top cover is mutually communicated with the bottom end of the mast, the bottom cover is arranged at the bottom end of the box body, and the bottom end of the bottom cover is mutually communicated with the top end of the vertical cylinder.

Furthermore, the fan blade body, the mast and the sealing round box are all made of PP plates.

Further, the fan blade body is conical, and the top end size of the fan blade body is larger than the bottom end size of the fan blade body.

A method of a flabellum-less wind power generation structure comprising the steps of:

s1, selecting a foundation: firstly, geological exploration is carried out in a region with larger airflow in a wind field, and a region with stronger geology is selected for punching and pile fixing, so that the bottom plate is ensured to be stable and the fan blade body can swing along with the airflow;

s2, building facilities: the method comprises the steps that a base plate is fixed in an area selected in the step S1 through a collision bolt, a top structure is built, a main body of the power generation structure is formed by sequentially assembling a vertical cylinder, a sealed round box, a mast and a fan blade body step by step, wherein a swing mechanism is pre-installed in the fan blade body and is inserted, so that the later integral building is facilitated, and a position of a cutting magnetic induction line mechanism, a conductive torch and a magnet mechanism is adjusted to ensure that the power generation structure forms an electromagnetic induction power generation function;

s3, wind power test: step S2, enabling the power generation structure to swing in a designated wind field, counting the stress values between the permanent magnet and the magnetic damping body by collecting power generation values of different wind power, and drawing a corresponding change curve graph, so as to judge whether the range of the power generation structure for maximally receiving wind power swing meets the specification;

s4, electric power detection: and (2) after the safety test in the step (S2), connecting the conductive cylinder to a regulating circuit to perform variable-voltage current regulation on the power of the power generation structure until the detected power meets the storage requirement, and switching on the power generation structure to a power storage device.

Compared with the prior art, the invention has the beneficial effects that:

through installing this power generation structure at natural wind, make its wind-driven flabellum body swing, and conduct the mast, make the mast produce resonance according to the wind speed, the flabellum body top can continuously produce vortex-induced vortex after the resonance, produce and continue vibrations, the mast drives cutting magnetism and feels line mechanism and vibrate together high-frequency, vibrations cutting magnetic field produces induced current, through such a mode, not only effectively saved occupation of land space, also through the mode of layer by layer construction, make this power generation structure's assembly more convenient, simultaneously, through canceling traditional rotation flabellum structure, be favorable to protecting near birds of perching, reduce the injury that causes it.

The foregoing description is only an overview of the present invention, and is intended to be implemented in accordance with the teachings of the present invention in order that the same may be more clearly understood and to make the same and other objects, features and advantages of the present invention more readily apparent.

Drawings

FIG. 1 is a perspective view of a bladeless wind power generation structure according to an embodiment of the present invention;

FIG. 2 is a cross-sectional view of a bladeless wind power generation structure according to an embodiment of the present invention;

FIG. 3 is a schematic diagram of a cutting induction line mechanism of a bladeless wind power generation structure according to an embodiment of the present invention;

FIG. 4 is a schematic diagram of a swing mechanism of a bladeless wind power generation structure according to an embodiment of the present invention;

FIG. 5 is a cross-sectional view of a base plate of a bladeless wind power generation structure according to an embodiment of the present invention;

FIG. 6 is a flow chart of a method for using the bladeless wind power generation structure disclosed in the embodiment of the invention;

fig. 7 is a graph of a force applied to a magnet of a bladeless wind power generation structure according to an embodiment of the present invention.

Reference numerals: 100. a fan blade body; 200. a bottom plate; 2001. a plate body; 2002. an annular groove; 2003. a conductive groove; 2004. anti-pressing strips; 2005. a threaded hole; 300. sealing the round box; 3001. a case body; 3002. a top cover; 3003. a bottom cover; 400. a mast; 500. an upstanding barrel; 600. a swing mechanism; 6001. a top circular plate; 6002. a bottom circular plate; 6003. reinforcing piles; 6004. a connecting seat; 6005. a cable; 700. a magnet mechanism; 7001. a permanent magnet; 7002. a magnetic damping body; 800. cutting the magnetic induction line mechanism; 8001. a first coil; 8002. a second coil; 8003. a third coil; 8004. a fourth coil; 900. and a conductive torch.

DETAILED DESCRIPTION OF EMBODIMENT (S) OF INVENTION

The following description of the embodiments of the present invention will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present invention, but not all embodiments.

Example 1

Referring to fig. 1 to 5, a bladeless wind power generation structure comprises a blade body 100 and a bottom plate 200, wherein the bottom end of the blade body 100 is connected with a mast 400, the bottom end of the mast 400 is provided with a sealed round box 300, the bottom end of the sealed round box 300 is connected with an upright barrel 500, the upright barrel 500 is fixedly installed at the top end of the bottom plate 200, a conductive barrel 900 is installed at the center position of the top end of the bottom plate 200, the conductive barrel 900 is located inside the upright barrel 500, a magnet mechanism 700 is arranged inside the sealed round box 300, the magnet mechanism 700 comprises a pair of permanent magnets 7001 and a pair of magnetic damping bodies 7002, the pair of permanent magnets 7001 are respectively installed inside the sealed round box 300, the pair of magnetic damping bodies 7002 are respectively sleeved on two sides of the outer wall of the conductive barrel 900, the pair of permanent magnets 7001 and the pair of magnetic damping bodies 7002 are respectively located on the same horizontal plane, the outer wall of the conductive barrel 900 is provided with a cutting magnetic induction mechanism 800, the cutting magnetic induction mechanism 800 comprises a first coil 8001, a second coil 8002, a third coil 8003 and a fourth coil 8004, the first coil 8001 is sleeved on the outer side of the second coil 8002, and the outer side of the first coil 8003 is sleeved on the outer side of the second coil 8003.

The embodiment of the invention is also realized by the following technical scheme.

As an example of the present invention, the first coil 8001 and the second coil 8002 are at the same level and form a first cut coil, and the third coil 8003 and the fourth coil 8004 are at the same level and form a second cut coil.

By applying the embodiment of the invention, a gap is further arranged between the bottom end of the first cutting coil and the top end of the second cutting coil, and the size range of the gap is 0.5-1.5 mm.

Further, the connection part between the blade body 100 and the mast 400 is provided with a swing mechanism 600, the swing mechanism 600 comprises a top circular plate 6001, a bottom circular plate 6002, a plurality of reinforcing piles 6003, a connecting seat 6004 and a cable 6005, the reinforcing piles 6003 are connected between the top circular plate 6001 and the bottom circular plate 6002 in a penetrating way, the connecting seat 6004 is arranged at the center of the bottom end of the bottom circular plate 6002, and the bottom end of the connecting seat 6004 is connected with the cable 6005.

Further to the embodiments of the present invention, the bottom end of cable 6005 extends through conductive torch 900 and is connected to the top end of base plate 200.

Further, the base plate 200 includes a plate body 2001, an annular groove 2002, a conductive groove 2003, compression-resistant strips 2004 and a threaded hole 2005, the surface of the plate body 2001 is respectively provided with the annular groove 2002 and the conductive groove 2003, an insulating layer is arranged between the annular groove 2002 and the conductive groove 2003, the conductive groove 2003 is electrically connected with the conductive cylinder 900, the bottom end of the upright cylinder 500 extends to the inside of the annular groove 2002, a plurality of compression-resistant strips 2004 are installed in the plate body 2001, and corners of the plate body 2001 are respectively provided with the threaded hole 2005.

Further to the embodiment of the present invention, the sealed round box 300 comprises a box body 3001, a top cover 3002 and a bottom cover 3003, wherein the top cover 3002 is mounted on the top end of the box body 3001, the top end of the top cover 3002 is communicated with the bottom end of the mast 400, the bottom cover 3003 is mounted on the bottom end of the box body 3001, and the bottom end of the bottom cover 3003 is communicated with the top end of the upright tube 500.

Further, according to the embodiment of the present invention, the fan blade body 100, the mast 400 and the sealing round box 300 are all made of PP plates.

Further, the fan blade body 100 is configured as a cone, and the top dimension of the fan blade body 100 is larger than the bottom dimension of the fan blade body 100.

Example two

Referring to fig. 6, the invention also provides a using method of the flabellum-free wind power generation structure, which comprises the following steps:

s1, selecting a foundation: firstly, geological exploration is carried out in a region with larger airflow in a wind field, and a region with stronger geology is selected for punching and pile fixing, so that the bottom plate 200 is ensured to be stable and the fan blade body 100 can swing along with the airflow;

s2, building facilities: the base plate 200 is fixed in the area selected in the step S1 by using the collision bolt, the top structure is built, the upright cylinder 500, the sealed round box 300, the mast 400 and the fan blade body 100 are assembled in sequence gradually, so that the main body of the power generation structure is formed, wherein the swing mechanism 600 is pre-installed in the fan blade body 100 and is inserted, so that the later integral building is facilitated, and the position of the cutting magnetic induction mechanism 800, the conductive torch 900 and the magnet mechanism 700 is adjusted, so that the power generation structure is ensured to form the electromagnetic induction power generation function;

s3, wind power test: step S2 is carried out to enable the power generation structure to swing in a designated wind field, and the power generation values of different wind powers are collected to enable the power generation structure to count the stress values between the permanent magnet 7001 and the magnetic damping body 7002, and corresponding change graphs are drawn, so that whether the range of the power generation structure for maximally receiving wind power swing meets the specification is judged;

s4, electric power detection: after the safety test in step S2, the conductive cylinder 900 is connected to a regulating circuit externally, so that the power of the power generation structure is subjected to variable-voltage current regulation until the detected power meets the storage requirement, and then the power generation structure is connected to a power storage device.

The utility model has the advantages of possess, under the state of natural wind, through the flabellum body 100, the conduction is to mast 400, mast 400 produces resonance according to the wind speed, the flabellum body 100 top can continuously produce vortex-induced vortex after resonance, produce continuous vibrations, mast 400 drives the cutting magnetism and feels line mechanism 800 and vibrate together high-frequency, vibrations cutting magnetic field produces induced current, and mast 400 is in the effect of magnetic damping body 7002, when the swing is close to stator magnet, produce certain repulsion, promote mast 400 to the opposite direction swing, increase promptly and last swing frequency, can play the limiting displacement again, avoid too big swing, thereby be used for protecting this power generation structure.

It will be apparent to those skilled in the art that various modifications and variations can be made to the present invention without departing from the spirit or scope of the invention. Thus, it is intended that the present invention also include such modifications and alterations insofar as they come within the scope of the appended claims or the equivalents thereof.

Claims (10)

1. The utility model provides a no flabellum wind power generation structure, its characterized in that includes flabellum body (100) and bottom plate (200), the bottom of flabellum body (100) is connected with mast (400), the bottom of mast (400) is equipped with sealed circle box (300), the bottom of sealed circle box (300) is connected with upright section of thick bamboo (500), upright section of thick bamboo (500) fixed mounting is in the top of bottom plate (200), conductive barrel (900) are located the inside of upright section of thick bamboo (500) is installed at the top central point of bottom plate (200), the inside of sealed circle box (300) is equipped with magnet mechanism (700), magnet mechanism (700) include a pair of permanent magnet (7001) and a pair of magnetic damping body (7002), a pair of permanent magnet (7001) are installed respectively in the inside of sealed circle box (300), a pair of magnetic damping body (7002) are respectively the suit in the outer wall both sides of conductive barrel (900), a pair of permanent magnet (7001) and a pair of conductive barrel (7002) are in the inside of upright section of thick bamboo (800), magnet mechanism (800) are in the same as coil (800), coil 800) is felt in a coil 800, coil 800 (800) is felt in a second coil 800, coil 800 (800) is in a parallel with coil 800, the first coil (8001) is sleeved on the outer side of the second coil (8002), and the fourth coil (8004) is sleeved on the outer side of the third coil (8003).

2. The bladeless wind power generation structure of claim 1, wherein: the first coil (8001) and the second coil (8002) are in the same horizontal plane and form a first cutting coil, and the third coil (8003) and the fourth coil (8004) are in the same horizontal plane and form a second cutting coil.

3. The bladeless wind power generation structure of claim 2, wherein: a gap is arranged between the bottom end of the first cutting coil and the top end of the second cutting coil, and the size range of the gap is 0.5-1.5 mm.

4. The bladeless wind power generation structure of claim 1, wherein: the fan blade is characterized in that a swing mechanism (600) is arranged at the joint of the fan blade body (100) and the mast (400), the swing mechanism (600) comprises a top circular plate (6001), a bottom circular plate (6002), a plurality of reinforcing piles (6003), connecting seats (6004) and a cable (6005), the top circular plate (6001) is connected with the bottom circular plate (6002) in a penetrating mode, the connecting seats (6004) are installed at the central positions of the bottom ends of the bottom circular plate (6002), and the cable (6005) is connected with the bottom ends of the connecting seats (6004).

5. The bladeless wind power generation structure of claim 4, wherein: the bottom end of the cable (6005) penetrates through the conductive torch (900) and is connected with the top end of the bottom plate (200).

6. The bladeless wind power generation structure of claim 1, wherein: bottom plate (200) include plate body (2001), ring channel (2002), conducting groove (2003), resistance to compression strip (2004) and screw hole (2005), the surface of plate body (2001) sets up ring channel (2002) and conducting groove (2003) respectively, be equipped with the insulating layer between ring channel (2002) and conducting groove (2003), conducting groove (2003) with electric connection between conductive cylinder (900), the bottom of upright section of thick bamboo (500) extends to the inside of ring channel (2002), the internally mounted of plate body (2001) has a plurality of resistance to compression strip (2004), the corner of plate body (2001) sets up screw hole (2005) respectively.

7. The bladeless wind power generation structure of claim 1, wherein: the sealed round box (300) comprises a box body (3001), a top cover (3002) and a bottom cover (3003), wherein the top cover (3002) is arranged at the top end of the box body (3001), the top end of the top cover (3002) is mutually communicated with the bottom end of the mast (400), the bottom cover (3003) is arranged at the bottom end of the box body (3001), and the bottom end of the bottom cover (3003) is mutually communicated with the top end of the upright cylinder (500).

8. The bladeless wind power generation structure of claim 1, wherein: the fan blade body (100), the mast (400) and the sealing round box (300) are all made of PP plates.

9. The bladeless wind power generation structure of claim 1, wherein: the fan blade body (100) is conical, and the top end size of the fan blade body (100) is larger than the bottom end size of the fan blade body (100).

10. A method of using a bladeless wind power generation structure according to claims 1-9, characterized by: the method comprises the following steps:

s1, selecting a foundation: firstly, geological exploration is carried out in a region with larger airflow in a wind field, and a region with stronger geology is selected for punching and pile fixing, so that the bottom plate (200) is ensured to be stable and the fan blade body (100) can swing along with the airflow;

s2, building facilities: the base plate (200) is fixed in the area selected in the step S1 by using a collision bolt, the top structure is built, the vertical cylinder (500), the sealing round box (300), the mast (400) and the fan blade body (100) are assembled in sequence gradually to form the main body of the power generation structure, the swing mechanism (600) is pre-installed in the fan blade body (100) and is inserted, so that the later integral building is facilitated, and the position of the cutting magnetic induction mechanism (800), the conductive cylinder (900) and the magnet mechanism (700) is adjusted, so that the power generation structure is ensured to form an electromagnetic induction power generation function;

s3, wind power test: step S2 is carried out to enable the power generation structure to swing in a designated wind field, and the stress values between the permanent magnet (7001) and the magnetic damping body (7002) are counted by collecting power generation values of different wind power, and corresponding change graphs are drawn, so that whether the range of the power generation structure for maximally receiving wind power swing meets the specification is judged;

s4, electric power detection: after the safety test in the step S2, the conductive cylinder (900) is externally connected to a regulating circuit, so that the power of the power generation structure is subjected to variable-voltage current regulating treatment until the detected power meets the storage requirement, and then the power generation structure is connected with a power storage device.