TWM487360U - Blade structure of wind power generation - Google Patents

Description

Wind power fan blade structure

The present invention relates to a wind power fan blade structure, and more particularly to a wind power fan blade structure by which a slidable arc deflector can protect a fan blade.

Human beings are gradually facing a crisis of energy depletion, and the concept of sustainable energy and environmental protection is increasingly showing its importance. As early as the twentieth century, there were devices that used renewable energy to replace existing energy-consuming energy sources. The renewable energy sources generally include solar power generation schemes, wind power generation schemes, tidal power generation schemes, and geothermal power generation schemes. The power generation solution can meet 200 times the world's energy needs.

The principle of wind power generation is to use the natural wind to drive the mechanical energy generated by the rotation of the blade, and then convert it into usable electric energy by the principle of the current magnetic effect of the generator rotor. Generally speaking, wind turbines are generally divided into two types: horizontal wind turbines and vertical wind turbines. The horizontal wind turbines refer to the horizontal axis of the rotating shaft, and the steering gear is required to be equipped with a 360 degree steering wind. The advantage of the horizontal wind turbine is that the power generation efficiency is higher than that of the vertical wind turbine. The vertical wind turbine refers to the rotation axis perpendicular to the wind direction. The advantages of the vertical wind turbine are the advantages of simple structure, non-directionality and low noise. .

Conventional vertical wind turbines tend to be too fast because the wind speed is too high, so that the bearing shaft can not be loaded and damaged, or its power generation efficiency is not ideal, so how to design its structure to make it not easy to damage has become today The problem that the industry wants to solve.

In view of the above, an object of the present invention is to provide a wind power fan blade structure that can accommodate a curved air deflector to protect a fan blade.

To achieve the above objective, the present invention provides a wind power fan blade structure that can be coupled to a generator to convert the received wind power into usable or stored power. The wind power fan blade structure includes And a wind guide bracket pivotally disposed on the generator, and a wind guide bracket disposed on an outer peripheral side of the blade structure, the blade structure includes an upper fixing member, a lower fixing member, and a fixed on the upper fixed portion a plurality of fan blades between the piece and the lower fixing member, the air guiding bracket comprises one or a plurality of positioning mechanisms disposed on an outer circumference of the fan blade, and a plurality of curved wind guides pivotally disposed on the positioning mechanism And the arc-shaped wind deflector includes a storage state that is shielded from the outer circumference of the fan blade by pivoting.

Further, the positioning mechanism includes an upper positioning bracket and a lower positioning bracket respectively sandwiching the curved air guiding sheets from the two sides, and a plurality of the positioning brackets respectively disposed between the upper positioning bracket and the lower positioning bracket respectively corresponding to the positioning brackets respectively To the curved wind deflector for the abutment against which the curved air deflector abuts.

Further, the inner side of the fan blade has a fixed spacing between the other of the fan blades for airflow.

Further, the fan blade is four pieces.

Further, the plurality of curved air guiding sheets are equidistantly disposed on the outer circumference of the fan blade.

Further, the curved wind guide is 4 pieces.

Further, the openings between the two curved wind deflectors are substantially corresponding to the southeast, southwest, northeast, and northwest directions.

Therefore, several embodiments of the present invention have the following beneficial technical effects compared to the prior art:

1. The creation system provides a wind power fan blade structure with a curved wind deflector to improve power generation efficiency.

2. This creation relies on the storage of curved wind deflectors to avoid damage to the fan blades caused by excessive wind.

3. This creation can improve the power generation efficiency by the structural improvement of the fan blades.

100‧‧‧Wind power fan blade structure

10‧‧‧Fan leaf structure

11‧‧‧Upper fixture

12‧‧‧ Lower fixtures

13‧‧‧fan blades

20‧‧‧wind guide

21‧‧‧ Positioning agency

211‧‧‧ positioning bracket

212‧‧‧ positioning bracket

213‧‧‧Right

22‧‧‧Arc-shaped wind deflector

30‧‧‧Generator

40‧‧‧Solar power module

50‧‧‧fish

Fig. 1 is a schematic view showing the appearance of a wind turbine blade structure.

Figure 2 is a schematic exploded view of the structure of the wind turbine blade.

Fig. 3 is a schematic view showing the open state of the wind turbine blade structure.

FIG. 4 is a schematic view showing the storage state of the wind turbine blade structure.

Figure 5 is a schematic diagram of the wind turbine blade structure with solar panels.

The detailed description and technical content of this creation are described below with reference to the drawings. Furthermore, the drawings in this creation are for convenience of description, and the proportions thereof are not necessarily drawn to actual scales, and in the case of exaggeration, the drawings and their proportions are not intended to limit the scope of the present invention.

The present invention provides a wind power fan blade structure, wherein the arc-shaped wind deflector forms a storage state by adjusting an opening angle of an arc-shaped wind guide that surrounds the outer circumference of the fan blade. And by the wind blocking surface formed when closing, the strong wind is prevented from damaging the fan blade. The wind power fan blade structure can improve the rotation efficiency of the fan blade by the shaftless design of the blade, thereby improving the efficiency.

The following is a more detailed description of the detailed structure of the wind turbine blade structure. Please refer to Figure 1 and Figure 2 for a detailed view of the wind turbine blade structure and its structural decomposition. The wind power fan blade structure 100 can be configured to be coupled to the generator 30 to convert the received wind power into usable or stored power. The wind power fan blade structure 100 mainly includes a The fan blade structure 10 is pivoted on the generator 30, and a wind guide bracket 20 is disposed on the outer peripheral side of the blade structure 10.

The blade structure 10 includes an upper fixing member 11, a lower fixing member 12, and a plurality of fan blades 13 fixed between the upper fixing member 11 and the lower fixing member 12. The air guide bracket 20 includes one or more components disposed on the fan A positioning mechanism 21 of the outer periphery of the blade 13 and a plurality of one end pivotally disposed on the arcuate air guiding piece 22 on the positioning mechanism 21. The positioning mechanism 21 includes an upper positioning bracket 211 and a lower positioning bracket 212 respectively sandwiching the curved air guiding plate 22 from two sides, and a plurality of the positioning brackets 211 and the lower positioning bracket 212 respectively disposed between the positioning brackets 211 and the lower positioning brackets 212 And corresponding to the curved wind deflector 22 for the abutting rod 213 against which the curved air guiding sheet 22 abuts.

The generator 30 includes a transmission component and a motor, such as DC generators, Asynchronous (Induction) Generators, and Synchronous Generators or the like. The device for generating electricity does not limit its kind in this creation. In the present creation, the fan blade 13 is rotated to drive the transmission element to work, and the motor is converted into power available for use or storage (none of which is not shown above).

Please refer to "Figure 3" and "Figure 4" together. This is a schematic diagram of the open state of the wind turbine blade structure and a schematic view of the storage state. As shown in the figure, the curved wind deflector 22 has its side. A bearing pivotally disposed on the positioning mechanism 21, and an arc length of the curved wind deflector 22 corresponds to a length of an outer circumference of the fan blade 13. In operation, the arcuate air deflector 22 is pivotable by the bearing as an axis, thereby being adjusted to a desired wind receiving area, and the arcuate air deflector 22 is disposed in an open state. During the storage, the arc-shaped air deflector 22 can be pivoted against the abutting bar 213 by the bearing as an axis, so that the arc-shaped air deflector 22 can be shielded from the outer periphery of the fan blade 13 . At this time, the curved wind guide 22 is placed in the storage state.

In a preferred embodiment of the present invention, the fan blade 13 is looped The equidistant arrangement is such that there is a fixed distance between the two blades 26 of the blades. Thereby, the arc-shaped air guiding piece 22 is disposed on the outer circumference of the fan blade 13 in four directions, and the opening systems of the curved air guiding piece 22 respectively correspond to the southeast and the west respectively. The direction of the south, northeast, and northwest can be adjusted to enhance the air guiding effect.

Please refer to FIG. 5 for a schematic view of the use of the wind power fan blade structure 100. As shown in the figure, in a preferred embodiment, the creation system can be combined with the solar power module 40 and set. Used in the fishing rod 50, it provides the electricity needed to raise the fish gills 50 by solar energy and wind power. At noon, the solar power module 40 continues to supply power to the energy storage equipment to reserve the electricity collected at noon. At night or on cloudy days, power is supplied to the energy storage device by the wind power generation equipment associated with the wind power fan blade structure 100, thereby improving power generation efficiency. The stored electrical energy can be supplied to "microparticle filter", "large central system protein defoaming machine", "dissolved oxygen machine", "ultraviolet sterilizer", "solar circulation heating system", "central filtration circulation system" Etc. (all not shown above), supply the power required to raise the fish gills 50. In addition, the wind power fan blade structure 100 described above can also be used as a hydroelectric power generating device at high tide.

In summary, the present invention surrounds the outer peripheral edge of the fan blade by means of a slidable curved wind deflector to protect the inner fan blade from excessive wind damage. Secondly, the creation can be increased by the wind blade by designing the fan blades so that the wind has a flow outlet to prevent the reflected wind from colliding with the incident wind. Furthermore, the creation is set by the openings of the four curved wind guides corresponding to the southeast, southwest, northeast, and northwest, respectively, by appropriately controlling the curved wind guides. The number of electricity to increase the efficiency of power generation.

The above description has been made in detail, but the above is only a preferred embodiment of the present invention, and it is not possible to limit the scope of the creation of the creation, that is, the equality of the patent application scope according to the present creation. Changes and modifications are still covered by the patents of this creation.

100‧‧‧Wind power fan blade structure

11‧‧‧Upper fixture

12‧‧‧ Lower fixtures

13‧‧‧fan blades

211‧‧‧ positioning bracket

212‧‧‧ positioning bracket

213‧‧‧Right

22‧‧‧Arc-shaped wind deflector

Claims (7)

A wind power fan blade structure is configured to be coupled to a generator to convert the received wind power into usable or stored power. The wind power fan blade structure comprises: a blade structure The fan blade structure includes an upper fixing member, a lower fixing member, and a plurality of fan blades fixed between the upper fixing member and the lower fixing member; and an air guiding bracket, the ring is disposed on the fan blade An outer peripheral side of the blade structure, the air guide bracket includes one or more positioning mechanisms disposed opposite to an outer circumference of the fan blade, and a plurality of arcuate air guiding plates pivotally disposed on the positioning mechanism, the arc The air guiding piece includes a receiving state that is shielded from the outer circumference of the fan blade by pivoting. The wind power fan blade structure according to claim 1, wherein the positioning mechanism comprises an upper positioning bracket and a lower positioning bracket respectively sandwiching the curved air guiding piece from both sides, and a plurality of separately arranged Between the upper positioning bracket and the lower positioning frame, and corresponding to the curved air guiding piece for the abutting rod of the curved air guiding piece. The wind power fan blade structure according to claim 1, wherein the inner side of the fan blade has a fixed spacing between the fan blades for airflow. The wind power fan blade structure according to claim 2, wherein the fan blade is four. The wind power fan blade structure of claim 1, wherein the plurality of arcuate air deflectors are disposed equidistantly on the outer circumference of the fan blade. The wind power fan blade structure according to claim 4, wherein the arc-shaped wind deflector is four. The wind power fan blade structure according to claim 5, wherein the openings between the two arcuate wind guides are substantially corresponding to the southeast, the southwest, the northeast, and the northwest.