KR20020054262A - Construction of Variable Wings for Human Windmills and Exhaust Method of Propeller Using It - Google Patents

Abstract

PURPOSE: A variable wing structure for a windmill and method for mounting a propeller using the same are provided to increase the energy production at the same wind velocity condition and reduce the manufacture cost. CONSTITUTION: In manufacturing variable wings(A), a contact wing(2) is engaged with a plurality of hinges(3) to vary the outside of a wing for a propeller. Elastic stems(5,5') or springs are installed between the hinges(3). In manufacturing airfoils for the propeller, 2-airfoils, 3-airfoils, 4-airfoils, and 5-airfoils are manufactured with the variable wings to be a propeller contact rotating mechanism. Thus, the transformed energy production is increased at the same wind velocity condition.

Description

Construction of Variable Wings for Human Windmills and Method of Exhaust of Propeller Using It

The present invention is to produce the necessary power energy by increasing the rotation rate in the weak wind or strong wind by making the configuration of the wing with variable wing in the rotor blades by rotating the wind to produce a variable blade in various ways to increase the rotation rate in the weak wind or strong wind The present invention relates to the construction of a variable wing for a human windmill and a method of excretion of a propeller using the same.

The conventional propeller has only been able to have a simple type of propeller without a variable wing, it is a situation that has been used by binding only one propeller to the horizontal axis of rotation for windmills.

In light of this point, the present invention has been newly developed in the form of a variable wing blade to rotate the wing while changing the angle of wind according to the wind speed, and in forming such a wing on the horizontal rotating shaft It was installed in various ways to accommodate both strong winds and weak winds to obtain the required energy.

1 is a perspective view of a variable wing

2 is a perspective view of the variable wing

3rd wing arrangement

4th wing arrangement

5th Turning Wing Arrangement

6th Turning Wing Arrangement

7th Wing Arrangement

8th Wing Arrangement

Explanation of symbols on the main parts of the drawings

A: Adjustable wing P: Propeller

1,1 ': Wings 2,2 ^-1 : Wings 3,3 ^-1 : Hinge

4,4 ', 4 ", 4'": Elastic Iron Inserts 5,5 ': Elastic Iron Sheet

6,6'6 "6 '": Spring fastener 7,7': Spring

8,8 ¹ , 8 ² , 8 ³ , 8 ⁴ , 8 ⁵ : Horizontal shaft shaft 9,9 ¹ , 9 ² , 9 ³ , 9 ⁴ , 9 ⁵ : Support pipe

10,10 ¹ , 10 ² , 10 ³ , 10 ⁴ , 10 ⁵ : support shaft 11,11 ¹ , 11 ² , 11 ³ : propeller

12,12 ¹ , 12 ² : Propellers 13,13 ¹ , 13 ² , 13 ³ : Propellers

14,14 ¹ , 14 ² , 14 ³ : Propellers 15,15 ¹ , 15 ² : Propellers

16,16 ¹ : Propeller

1. In the configuration of the variable wing (A) to bind the wings (2) that can be variable on the outer side of the propeller blade (1) to bind with a number of hinges (3) Between the hinge and the hinge a plurality of reinforcing piece inserts (4) (4 ') (4 ") (4'") in a certain portion of the wing (1) and the flap (2) is attached to the elastic piece (5) (5 ') is inserted and the elastic iron pieces (5', 5 ') inserted in the wing side (4') (4 ") inserted on the wing side are joined to each other by the strength of the blowing wind. When the wings 2 are bent, the elastic iron pieces 5, 5 'are bent together with the blades, so that they can be pushed in and out of the elastic piece inserts 4 and 4' fixed to the blades 2. And

2 in constituting the variable wing (A) got by binding the folded wing (2 ') that can be on the outside of the variable furo feller blades ^(1-1) for a plurality of hinges ^(3-1) in the zoom to give foldable connection between the hinge and the hinge, the blade ^(1-1) in contact with the blades ^(2-1) jeopseol multiple spring engagement opening (6) (6 ') (6 ") (6"") in a certain region of the The springs 7 and 7 'are extended together with the wings 2' when the wings 2 'are bent by the strength of the blowing wind. Again, the wings (2) (2 ') to be retracted to fit the angle in place again.

3. Propelled wing type setting with adjustable wing

In setting up the airfoil's airfoil, the variable wing (A) composed of two wing type, 3 wing type, 4 wing type and 5 blade type is used to produce the propeller.

4. Conical Type Propeller Feller

In constructing the power conversion windmill with the produced propeller P, the front of the support shaft 10 is provided in parallel with the propeller P on a horizontal rotation shaft 8 connected to the support shaft 10. The two rotary propellers (11) and (11 ') are arranged in parallel with each other at a predetermined interval in the order of the size of the propeller on the horizontal rotary shaft shown in the figure, and the horizontal rotary shaft that extends to the rear of the support rotary shaft (10) The two propellers (11 ² ) (11 ³ ) are arranged in parallel with the flow of air at regular intervals,

5. Composed of 3 parallel type propeller rotating type mechanism.

In the installation of the propeller on the horizontal rotation shaft 8 'connected to the support rotation shaft 10', the propeller is placed on the horizontal rotation shaft extending forward of the support rotation shaft 10 '. 2 'propellers (12 ¹ ) (12 ² ) in parallel to the horizontal axis of rotation (10') in the order of the size of the wings, in accordance with the wind flow,

6. Dual-parallel type propeller rotating mechanism.

Two furo repeller (13) (13 ') a furo feller to a horizontal axis of rotation ⁽⁸²⁾ that is connected to the support rotation axis (10 ²⁾ to the horizontal axis of rotation that is listed in the forward direction of the supporting axis of rotation (10 ²⁾ in gyeolseol sikyeojum It is provided by juxtaposition according to the wind at predetermined intervals and juxtaposed to the wind by the two propellers (13 ² ) (13 ³ ) at a predetermined interval on the horizontal rotation shaft that extends to the rear of the support rotation shaft (10 ² ),

7. 4-Parallel Type Propeller

The supporting rotary shaft (10, ³⁾ and two furo repeller 14 and 14 'on the horizontal axis of rotation shown as the front of the horizontal rotation shaft supported by gyeolseol the furo feller in the zoom axis of rotation (8 ³⁾ (10 ³⁾ in connection as to give to the juxtaposed according to yupung at regular intervals supported by the two furo feller (14 ²⁾ juxtaposed according to yupung in a fixed (14 ³⁾ the distance on the horizontal axis of rotation given to the rear of the rotating shaft (10 ³⁾ giving

8. Combustion Large Rear Parallel Type Propeller Feller

Supporting the rotating shaft (10 ⁴⁾ and the two furo repeller (15) (15 ') on the horizontal axis of rotation shown as the front of it the support rotation axis (10 ⁴⁾ furo feller to gyeolseol sikyeojum to the horizontal axis of rotation ⁽⁸⁴⁾ which is connected By juxtaposed to the wind at predetermined intervals, and by installing the propeller (15 ² ) on the horizontal rotating shaft that extends behind the supporting rotating shaft (10 ⁴ ).

9. Combustion and rear wing dual-row parallel type propeller push-up rotary mechanism.

A small propeller 16 is formed at the front side of the horizontal rotating shaft 8 ⁵ connected to the supporting rotating shaft 10 ⁵ , and a large propeller 16 'is disposed at the rear side of the horizontal rotating shaft 8 ⁵ to the wind. It was made in conjunction with it.

The present invention, which has been manufactured and constructed in this way, has a wind speed effect that can be converted into an effective wind even if a wind speed of less than 3 metres per second can be brought to an effect of a wind speed control function during a strong wind, and the amount of energy converted at the same wind speed. It is the construction of variable wing for human-type windmills, which makes it possible to expect this increasing effect and the low investment effect of production equipment, and the method of excretion of the propeller using the same.

Claims (10)

The present invention in the manufacture of the variable wing (A) in the binding of the wing blade (2) (2 ') that can be variable on the outside of the wing for propeller (1) (1') Variable wings (A) made of a plurality of hinges (3) (3 ') and a hinge (5) (5') or a spring (7) (7 ') between the hinge and the hinge Manufacture configuration and angle of the propeller (P) in the set-up production of the variable blade (A) with the two blades, three blades, four blades and five blades set and produced and produced by the propeller (P) The configuration of a variable wing for human windmills made of a mechanism (3rd) (4th) (5th) (6th) (7th) (8th) and a FU using the same Feller excretion method 2. A plurality of hinges (3) according to claim 1, in which a hinge (2) that can be variable on the outside of the propeller blade (1) in the construction of the variable wing (A) is attached. The hinges and a plurality of resilient iron inserts (4) (4 ') (4 ") (4'") are placed between the hinges and the hinges at predetermined portions of the wings (1) and the wings (2). The wind is inserted by inserting the elastic iron pieces (5) (5 ') and joining with the coal iron pieces (5) (5') inserted in the elastic iron insert slot (4 ') (4 ") which is attached to the wing side. When the flap (2) is bent by strength, the elastic piece (5) (5 ') bends with the flap and enters and exits from the resilient piece insert (4) (4' ") which is fastened to the flap (2). The configuration of the variable wing for the human-type windmill that made it possible and the excavation method of the propeller using the same. According to claim 1, wherein the variable I by binding the folded wing (2 ') that can be on the outside of the variable furo feller blades ^(1-1) for in constituting the wings (A) a number of hinges in the zoom (3 ^42-1) to give the fold hinge connection with a hinge, the blade ^(1-1) in contact with a plurality of engagement spring, obtain the predetermined portion of the wings ^(2-1) (6) (6 ') (6 ") (6'") And the spring (7) (7 ') to the spring (7) (7') when the wing (2 ') bent by the intensity of the blowing wind spring (7) (7') is the wing (2 ' ) The configuration of the variable wing for the human-type windmill that allows the wing (2) (2 ') to be retracted to the angle of the seat again and the method of excretion of the propeller using the same. The method according to claim 1, wherein the variable wing (A) configured in setting the airfoil of the propeller is set to a two-wing, three-wing, four-wing and five-wing type to produce a propeller (P) for a human-type windmill The configuration of the variable wing and the excretion method of the propeller using it. The method according to claim 1, wherein in the construction of the wind power conversion windmill using the produced propeller P, the propeller P is placed in parallel with the horizontal rotation shaft 8 connected to the support rotation shaft 10. The two rotary propellers 11 and 11 'are arranged in parallel to the horizontal flow shaft in the order of the size of the propeller in the order of the size of the propeller in front of the rotary shaft 10, and come out to the rear of the supporting rotary shaft 10. Two propellers (11 ² ) (11 ³ ) are installed on the horizontal rotating shaft at regular intervals in order of size, and the configuration of the variable wing for the human windmill and the method of discharging the propeller using the same . According to claim 1, Propelled in the horizontal rotating shaft (8 ') connected to the support shaft (10') in the purge of the propeller (P) to the horizontal rotating shaft extending forward of the support shaft (10 '). Variable for human-type windmills, which are installed in parallel with two propellers (12 ¹ ) (12 ² ) in the order of wing size on the horizontal rotating shaft that extends behind the supporting shaft (10 '). The configuration of the wing and the method of excretion of the propeller using it. According to claim 1, wherein the support rotation axis (10 ²⁾ and the two furo Feller (13 to the horizontal axis of rotation shown as the front of the horizontal rotation shaft's supporting the rotating shaft of furo feller to gyeolseol sikyeojum to ⁽⁸²⁾ (10 ²⁾ connected to the ) And 13 'are installed in accordance with the wind at fixed intervals, and the two propellers (13 ² ) (13 ³ ) are installed in the horizontal rotation shaft at the rear of the support shaft 10 ² at the specified interval. The configuration of the variable wing for human-type windmills and the method of excretion of the propeller using the same. The method of claim 1 wherein the support rotation axis (10 ³⁾ to give gyeolseol the furo feller that is connected to the horizontal rotation shaft ⁽⁸³⁾ two furo feller to a horizontal axis of rotation that is listed in the forward direction of the supporting axis of rotation (8 ³⁾ in the zoom ( 14) (14 ') are installed in accordance with the flow at regular intervals, and the two propellers (14 ² ) (14 ³ ) are aligned with the flow at the predetermined intervals on the horizontal rotation shaft that extends behind the supporting rotation shaft (10 ³ ). The configuration of the variable wing for the human-type windmill, and the method of excretion of the propeller using the same. According to claim 1, wherein the support axis of rotation (10 ⁴⁾ and the horizontal axis of rotation ⁽⁸⁴⁾ furo feller the gyeolseol two furo Feller (15 to the horizontal axis of rotation shown as the front of it the support rotation axis (10 ⁴⁾ in sikyeojum in that connected to the (15 ') in accordance with the wind at regular intervals, and attached to the propeller (15 ² ) on the horizontal rotating shaft that extends to the rear of the support shaft (10 ⁴ ) configuration of a variable wing for a human-type windmill And the method of excretion of the propeller using the same The small propeller 16 is formed on the front side of the horizontal rotating shaft 8 ⁵ connected to the supporting rotating shaft 10 ⁵ , and the large propeller is formed on the rear side of the horizontal rotating shaft 8 ⁵ . The structure of the variable wing for human windmills, which is formed by combining 16 ') with the wind, and the method of excavation of the propeller using the same.