KR20050052723A - Air volume control method of windmill for power generation adjustable according to air connecting structure of the windmill - Google Patents

Abstract

The present invention relates to a windmill for generating wind power using the wind to convert the power into electrical energy,

A separate wind guider having a plurality of guide plates is formed at the periphery of a conventional rotary blade, and the rotary blade is equipped with a plurality of spring-tight opening and closing plates, and a rotary blade according to the strength of the wind by a hinge shaft and a spring device. By rotating or folding

When the wind is blowing, the wind guide guides the surrounding wind to the rotor blade side, so that the wind power is blown by the wind power, while the wind turbine is open or rotated or folded depending on the strength of the wind. In case of blowing, the wind power will be stable and the wind power control method of wind power generation windmill for variable operation according to the wind volume is very effective because it can guarantee a variety of design because it can build a relatively wide and powerful rotary wing. It is about the combined structure of the windmills.

Description

Air volume control method of windmill for variable power operation according to the wind volume and the combined structure of the windmill for wind power generation {Air volume control method of windmill for power generation adjustable according to air connecting structure of the windmill}

The present invention relates to a windmill for generating wind power by using the wind to convert the power into electrical energy to use the wind, in particular, the wind power of the windmill by allowing the rotor blades of the windmill to be partially opened, rotated, or folded Wind resistance can be prevented from overturning or tilting due to the resistance of wind gusts, but a separate wind guider is installed at the periphery of the rotor blades to collect winds from the surroundings and guide them to the rotor blades for more efficient wind power generation. The present invention relates to a wind volume control method of windmills and a combined structure of windmills.

Windmills for wind power generation can convert the rotating power obtained from the wind-driven rotor blades into electrical energy and use it to obtain safe natural energy at a relatively low installation cost. It is installed in place.

Propeller-type windmills installed and used in recent years are equipped with a power transmission unit 101 at the tip of a vertically-mounted prop 100 as shown in FIG. 1, and a plurality of propeller-type windmills are provided at one side of the power transmission unit 101. Rotating blade 102 of the, so that when the rotary blade 102 is rotated by the wind is to convert the rotating power of the rotary blade 102 to electrical energy to be used.

However, wind turbines for wind power generation as described above are large in size to obtain a large amount of electrical energy, and are manufactured considering the mechanical strength and design stability as they are enlarged as described above, but are strong like typhoons. If the wind blows or a momentary gust occurs, the resistance to the rotor blades and props is greatly increased, causing the whole windmill to roll over or tilt, and in some cases the rotor blades are broken or bent. .

In addition, in order to overcome the problems described above, the rotor blade is designed to deform the propeller type or to reduce the width of the wing, but in the case as described above, the rotational force is greatly reduced due to the general resistance to the wind, If the breeze is blowing because the rotary blades are not rotated, there is a problem that the power generation performance is reduced.

The present invention has been made to eliminate the problems described above, and forms a separate wind guide having a plurality of guide plates on the periphery of a conventional rotary blade, the rotary blade is equipped with a plurality of spring-tight opening and closing plate By rotating or folding the rotor blades according to the wind force by the hinge shaft and the spring device,

When the wind is blowing, the wind guide guides the surrounding wind to the rotor blade side, so that the wind power is blown by the wind power, while the wind turbine is open or rotated or folded depending on the strength of the wind. In case of blowing, the wind power will be stable and the wind power control method of wind power generation windmill for variable operation according to the wind volume is very effective because it can guarantee a variety of design because it can build a relatively wide and powerful rotary wing. It is an object of the present invention to provide a combined structure of the windmill for wind power generation.

Hereinafter, preferred embodiments of the present invention will be described.

Figure 2 is an overall perspective view of a windmill for wind power generation according to the invention, Figure 3 is a side cross-sectional view of the windmill for wind power generation according to the present invention.

First, looking at the air volume control method of the windmill for wind power generation according to the present invention,

A breeze adjustment step of concentrating the wind around the rotor blades on the rotor blade side while varying the inclination angle of the radial guide plate formed obliquely around the rotor blades;

A first step of controlling wind power to open and open a plurality of opening and closing plates formed on the rotary blades when a weak wind is provided to generate a load by the wind on the rotary blades;

A second step of controlling the wind when the wind turbine is provided with a heavy wind such that a load caused by the wind is generated in the first stage of the wind regulation;

If the strong wind is provided to the degree of wind load on the rotary blade in the second stage of wind control, the rotary blade is divided into the third stage of the wind control folded in the direction of the wind,

When the wind is weakened in each of the wind control step is to rotate the rotor blades to return to the previous step sequentially.

The windmill for achieving the adjustment method as described above,

The rotary shaft 3 coupled with the plurality of rotary blades 2, 2 'is coupled to the tip of the vertically placed support pillar 1, and the rotating power of the rotary shaft 3 is a bevel gear 4, 4'. In the known wind turbine for wind power that is transmitted to the power generation unit 50 by a plurality of connecting shafts (5) (5 ') having a),

To the periphery of the rotary blades (2) (2 '), a plurality of guide plate 11 is coupled to the breeze control port (a) is hinged radially,

A plurality of vent holes 20, 20 'is formed on the main surface of the rotary blades 2, 2', and separate opening and closing plates 21, 21 'are formed on the vent holes 20, 20'. Combining the weak wind control (b) equipped with,

On the coupling end of the rotary blades (2) (2 ') is formed a mid-air control (c) is hinged rotatably coupled to the rotary blades (2) (2') in the longitudinal direction,

In the coupling portion of the rotary blades (2) (2 ') and the rotary shaft (3) is to form a strong wind control mechanism (d) in which the rotary blades (2) (2') are folded to one side.

In addition, the above-mentioned breeze control unit (a) is equipped with a cylindrical guider 10 on the periphery of the rotary blades (2) (2 '), one end of the guider 10, the end is hinged fixed induction The plate 11 is formed radially, and the guide plate 11 is connected to the guider 10 and the spring 12 so as to be elastically fixed to the rotary blades 2 and 2 'side.

The weak wind controller (b) forms a plurality of vent holes (20, 20 ') in the rotary blade (2) (2'), and one end of the vent holes (20, 20 ') The hinged fixed opening and closing plates 21 and 21 'are mounted, and the opening and closing plates 21 and 21' are supported by the rotary blades 2 and 2 'and the spring 22, and the rotary blades 2 are supported. It is formed to be in close contact with the (2 ') side,

The breeze control device (c), the coupling end of the rotary blade (2) (2 ') is formed to be divided, one side of the groove to form a longitudinal groove (30), the other side is inserted into the groove (30) Corresponding to each other by forming a separate rotary sphere (31),

The split rotor blades 2 and 2 'are coupled to each other by a separate spring 32, and one end of the spring 32 is coupled to a bracket 33 formed at one split end,

An additional support 35 is formed at the divided end of the rotating shaft 3 side to protrude toward the rotary blade 2, 2 ', and a stopper 34 is provided at the divided end of the rotary blade 2, 2'. Protruding to form, the rotary blade (2) (2 ') is elastically rotatably supported in the longitudinal direction,

The strong wind adjusting device (d) has an insertion hole (40) protruding from the engaging end of the rotary blade (2) (2 ') and the rotating shaft (3) at the engaging portion of the rotary blade (2) (2') and the rotating shaft (3). Is inserted into the groove portion 41 formed on the coupling side of the (3), and the insertion hole 40 is foldable from the groove portion 41 by a separate hinge pin 42, the separate spring 43 Is coupled between the rotary blade (2) (2 ') and the rotary shaft (3), thereby forming the rotary wing (2) (2') to be elastically supportable.

It is possible to produce battery energy by connecting the connecting shaft 5, 5 'of the present invention having such a configuration with a separate power generation unit 50, the power generation unit 50 is by the applicant of the present invention As proposed and registered Patent No. 398491, when the rotary blades 2, 2 'are rotated, the compressor 51 is rotated by the rotation of the connecting shafts 5 and 5' coupled to the rotary shaft 3. When the compressed air is driven, the compressed air is produced. When the compressed air is supplied at a constant pressure by the pressure control unit 54 having the air cylinder 52 and the air cylinder 53, the compressed air is a cylinder 55. By operating the electricity will be obtained through the generator (56).

If described in more detail by the accompanying drawings the operation of the present invention as follows.

Wind turbine for wind power of the present invention is a wind blowing control unit (a) and weak wind control unit (b), the mid-wind control unit (c), the strong wind control unit (d) in step by step according to the strength of the wind Proposed to prevent falling or tilting by the resistance,

First, if the breeze is blowing in the past, the strength of the wind was weak, so that the rotor blades (2) (2 ') could not be rotated, there was a problem that the power supply and supply depending on the constraints of the installation location and seasons, but the separate breeze control sphere By installing (a) at the periphery of the rotary blades (2) and (2 '), even if a breeze blows to the extent that the rotary blades (2) and (2') cannot be rotated, the wind around them is rotated (2) (2). ') Side is concentrated so that the air volume is increased, the rotary blades (2) (2') is rotated.

That is, as shown in FIG. 4, when the wind does not blow, the guide plate 11 inside the guider 10 is radially lowered from the inner wall of the guider 10, and as the wind is supplied, the guide plate 11 is radially exposed by the wind resistance. The guide plate 11 is pushed outward to concentrate the wind in a more extended range by the inclined guide plate 11 toward the rotary blades 2, 2 '.

In this state, if the wind strength is further increased, the guide plate 11 becomes unnecessary, and thus the guide plate 11 is completely rotated to the inner wall side of the guider 10 by the wind resistance, thereby minimizing the wind resistance. It is to pass all but the wind enough to rotate the rotary blades (2) (2 ').

Therefore, by rotating the guide plate 11 in accordance with the strength of the wind to automatically reduce the amount of air concentrated on the rotor blades (2) (2 ') side, even when the wind blowing weakly, the rotary blade (2) (2 ') is rotated.

In addition, when the wind is stronger than the above-mentioned breeze is relatively strong resistance is generated in the rotary blades (2) (2 '), in order to avoid such a resistance in the past, the elongated streamlined wing shape was produced, but the As the elongated streamlined wing as described above has been pointed out as a problem that the rotational reaction force is lowered because the resistance is relatively reduced,

In the present invention, as shown in FIG. 5, the above-mentioned rotary blades 2, 2 'are formed to be wider, but the resistive force acting on the rotary blades 2, 2' of a large area is the rotary blades 2, 2 '. By passing through the vents 20, 20 'formed in the intact, when more than the required wind is supplied to the excess air is discharged through the vents 20, 20'.

That is, as illustrated in FIG. 6, the opening and closing plates 21 and 21 ′ are hinged and fixed to the vent holes 20 and 20 ′ by separate springs 22. The opening / closing plates 21 and 21 'are held in close contact with the rotary blades 2 and 2' by the spring 22 force, and the rotary blades 2 and 2 'are subjected to the load. When the strength reaches the opening and closing plate (21) (21 ') is rotated by the wind to pass a certain amount of wind, so the wind resistance acting on the rotary blade (2) (2') is relatively reduced, Regardless of whether the opening / closing plate 21 or 21 'is operated, the rotary blades 2 and 2' are continuously rotated to allow stable power production while still providing the rotary blades 2 and 2 'to the rotary blades 2 and 2'. It is to prevent excessive load.

In addition, when the wind stronger than the weak wind blows, that is, even when the opening and closing plate (21) (21 ') is completely open, if the wind resistance is greatly applied to the rotary blade (2) (2') Figure 8a As shown in Figure 2 of the rotary blade (2) (2 ') is rotated in the longitudinal direction to change the forming angle of the rotary blade (2) (2') to reduce the resistance of the wind,

Since the lower end of the rotary blade (2) (2 ') is coupled by the mid-air control (c), the rotary blade (2) (2') is rotated above a certain wind power, the rotary blade ( 2) by separating the lower end of the (2 ') protruding to form a rotary ball 31 on one side and the other groove 30 on the other side by combining them with each other by the spring (32), said weak air control (b) When the wind is supplied beyond the range of) the rotor blades (2) (2 ') is rotated by the breeze control device (c), the forming angle of the direction of receiving less wind resistance, that is, the rotor blades (2) A large area of 2 'lies down in the direction of the wind, reducing its resistance.

In particular, by forming the coupling end of the rotary blade (2) (2 ') is divided, and the groove 30 and the rotary ball 31 is formed on each corresponding cross-section and combined with each other, one side rotary ball 31 is formed On the split side, a separate support 35 is formed to protrude, and on the split side on which the other groove 30 is formed, a separate stopper 34 is formed so that the rotary blades 2 and 2 'are not reversed. Of course, since the reverse power is always generated by the spring 32 is to act as a role of suppressing the reverse power.

In addition, when the strong wind blowing beyond the range of the above-described middle wind control opening (c), as shown in Figure 8b by adopting the strong wind control opening (d) to fold the rotary blade (2) (2 ') to the rear side , The time point of the strong wind control (d) as described above is to operate only when the wind is blown enough to blow the windmill by a very large wind or gusts, to ensure the safety of the windmill rather than the production of electrical energy To this end, a plurality of rotary blades (2) (2 ') is folded to the rear side to extremely reduce the resistance of the wind to greatly reduce the wind resistance received by the windmill to prevent the windmill from falling or tilting.

The strong wind adjusting device (d) is formed to protrude the insertion hole 40 at the end of the rotary blades (2) (2 '), the groove 41 on the rotary shaft (3) facing the insertion hole 40, respectively Correspondingly formed, hinged to each other by a separate hinge pin 42 in a state in which the insertion hole 40 and the recess 41 are engaged, and these rotary blades (2) (2 ') and the rotating shaft (3) spring By resilient support by means of 43, when the rotary blades 2, 2 'are folded, the spring 43 forces are overcome and the rotary blades 2, 2' are folded, and the strong wind is released. Rotating blades (2) (2 ') that are folded by the restoring force of the spring 43 is restored to the original position to perform a normal power generation action.

Therefore, each of the breeze control (a) and weak wind control (b), the mid-wind control (c), strong wind control (d) as described above in order to undergo a sequential step-by-step operation process, respectively Spring 12, 22, 32, 43 mounted on the control of the control is used to have a strong resilience sequentially, but in the state that the spring 12 of the guider 10 operates the spring of the other control ( 22) (32) (43) is not affected and affects the spring (22) of the weak wind controller (b) when reaching the limit point of the spring (12), and gradually the midwind controller (c) ) And the springs 32, 43 of the strong wind control (d) is gradually affected and can add or subtract wind power acting on the rotary blades (2) (2 ').

Such a wind turbine for wind power of the present invention has a plurality of bevel gears (4) (4 ') having the rotational power of the rotating shaft (3) in conjunction with this by the rotation of the rotary blades (2) (2') as shown in FIG. By using the connecting shaft (5) (5 ') of the present invention is to be delivered by the applicant of the present invention to the power generation unit 50 of the registered patent No. 398491 and to produce electrical energy,

When the compressed air is generated by the compressor 51 rotating by receiving power from the connecting shafts 5 and 5 ', the power generation unit 50 is provided with the air cylinder 52 and the air cylinder ( It is converted into a constant pressure through the pressure control unit 54 having 53) and is supplied to the cylinder (55).

Therefore, since the cylinder 55 reciprocates back and forth and converts it into a rotational motion to drive a separate generator 56, electrical energy is produced from the generator 56.

Such a wind turbine for the present invention can be installed near the coastline where the wind moves and the wind is relatively rich, as shown in FIG. 10, to maximize its efficiency. Likewise, by installing the power generator using the wave power and the windmill for wind power generation according to the present invention at the same time, it is very economical because it can produce abundant electric energy by converting complex kinetic energy into electric energy.

Wind turbine for variable operation according to the present invention as described above is variable wind power, when the wind is blowing, the wind is guided by gathering the surrounding wind to the rotor blade side, even if the wind is blowing, effective wind power generation is achieved As the rotor blades are opened, rotated and folded according to the strength of the wind, stable wind power generation can be achieved even in strong winds or gusts. will be.

1 is an overall view of a conventional windmill for wind power generation

Figure 2 is an overall perspective view of a windmill for wind power generation according to the present invention

Figure 3 is a side sectional view of a windmill for wind power generation according to the present invention

Figure 4 is a side view of the operation of the wind guider of the wind turbine for wind power generation according to the present invention

Figure 5 is a rear perspective view of the rotary blade of the windmill for wind power generation according to the present invention

Figure 6 is a view explaining the operation of the rotary wing opening and closing plate of the windmill for wind power generation according to the present invention

Figure 7 is an enlarged perspective view of the main portion of the rotary wing of the windmill for wind power generation according to the present invention

8a and 8b is a view of the operation of the rotary wing of the windmill for wind power generation according to the present invention,

8A is an explanatory view of the rotary operation of the rotary blade

8B is an explanatory view of the folding operation of the rotary blade.

9 is a configuration of a wind power generation system using a windmill for wind power generation according to the present invention

Figure 10 is an installation state of the present invention using a windmill for both the wind power generation and wave power generation of the present invention

Explanation of symbols on main parts of drawing

1: support pillar 2,2 ': rotor blade

3: axis of rotation 4,4 ': bevel gear

5,5 ': connecting shaft

10: guider 11: guide plate

12: spring

20,20 ': Aeration 21,21': Opening and closing board

22: spring

30: groove 31: rotary ball

32: spring 33: bracket

34: stopper 35: support

40: insertion hole 41: groove

42: hinge pin 43: spring

a: breeze control b: weak air control

c: heavy air regulator d: strong wind regulator

Claims (6)

A breeze adjustment step of concentrating the wind around the rotor blades on the rotor blade side while varying the inclination angle of the radial guide plate formed obliquely around the rotor blades; A first step of controlling wind power to open and open a plurality of opening and closing plates formed on the rotary blades when a weak wind is provided to generate a load caused by the wind on the rotary blades; A second step of controlling the wind when the wind turbine is provided with a heavy wind such that a load caused by the wind is generated in the first stage of the wind regulation; If the strong wind is provided to the degree of wind load on the rotary blade in the second stage of wind control, the rotary blade is divided into the third stage of the wind control folded in the direction of the wind, If the wind is weakened in each of the wind control step, the wind turbine wind volume control method for variable operation according to the wind volume, characterized in that to rotate sequentially return to the previous step. The rotary shaft 3 coupled with the plurality of rotary blades 2, 2 'is coupled to the tip of the vertically placed support pillar 1, and the rotating power of the rotary shaft 3 is a bevel gear 4, 4'. In the known wind turbine for wind power that is transmitted to the power generation unit 50 by a plurality of connecting shafts (5) (5 ') having a), To the periphery of the rotary blades (2) (2 '), a plurality of guide plate 11 is coupled to the breeze control port (a) is hinged radially, A plurality of vent holes 20, 20 'is formed on the main surface of the rotary blades 2, 2', and separate opening and closing plates 21, 21 'are formed on the vent holes 20, 20'. Combining the weakly mounted wind control (b), On the coupling end of the rotary blades (2) (2 '), the rotary blades (2) (2') forms a mid-air regulating tool (c) coupled to the hinge hinge to rotate in the longitudinal direction, In the coupling portion of the rotary blades (2) (2 ') and the rotary shaft (3) is characterized in that the strong wind control mechanism (d) is formed so that the rotary blades (2) (2') elastically folded to one side Combined structure of windmills for variable power generation depending on wind volume. The method of claim 2, The breeze adjustment mechanism (a) is equipped with a cylindrical guider (10) at the periphery of the rotary blades (2) (2 '), one end of the guide plate 10 is fixed to one inner peripheral surface of the guider (10) And the guide plate 11 is connected to the guider 10 and the spring 12 so as to be inclined elastically fixed to the rotary blades 2 and 2 '. Combined structure of windmills for wind power generation. The method of claim 2, The weak wind controller (b) forms a plurality of vent holes (20, 20 ') in the rotary blade (2) (2'), and one end of the vent holes (20, 20 ') The hinged fixed opening and closing plates 21 and 21 'are mounted, and the opening and closing plates 21 and 21' are supported by the rotary blades 2 and 2 'and the spring 22, and the rotary blades 2 are supported. (2 ') Combination structure of windmill for variable power generation, which is operated in accordance with the amount of wind, characterized in that formed in close contact with the outer peripheral surface. The method of claim 2, The breeze control device (c), the coupling end of the rotary blade (2) (2 ') is formed to be divided, one side of the groove to form a longitudinal groove (30), the other side is inserted into the groove (30) To form a separate rotary sphere 31 corresponding to each other, The split rotor blades 2 and 2 'are coupled to each other by a separate spring 32, and one end of the spring 32 is coupled to a bracket 33 formed at one split end, An additional support 35 is formed at the divided end of the rotating shaft 3 side to protrude toward the rotary blade 2, 2 ', and a stopper 34 is provided at the divided end of the rotary blade 2, 2'. Combination structure of the wind turbine for wind power generation variablely operated according to the amount of wind, characterized in that the rotor blade (2) (2 ') is formed to be elastically rotatably supported in the longitudinal direction. The method of claim 2, The strong wind adjusting device (d) has an insertion hole (40) protruding from the engaging end of the rotary blade (2) (2 ') and the rotating shaft (3) at the engaging portion of the rotary blade (2) (2') and the rotating shaft (3). Is inserted into the groove portion 41 formed on the coupling side of the (3), and the insertion hole 40 is foldable from the groove portion 41 by a separate hinge pin 42, the separate spring 43 Is coupled between the rotary blades (2) (2 ') and the rotary shaft (3), thereby allowing the rotary blades (2) (2') to be foldable and elastically supported to form a variable operation according to the amount of wind Combined structure of windmills for power generation.