FI89973B - Wind wheel - Google Patents

Description

89973

wind Wheel

Vindhjul 5

The invention relates to a ruminant wind turbine provided coaxially with a cylindrical tube arranged on the axis of rotation of the wind turbine, having a circular end at each end of the cylindrical tube). is limitedly pivotally mounted on pivot axes arranged parallel to the axis of rotation of the wind turbine near the outer edge of each end disc.

DE-OS 27 18 608 discloses a wind motor provided with a cylinder, two end discs at both ends of the cylinder and a plurality of cylindrical segment-shaped surfaces. These segment -20 surfaces, i.e. the wings, are mounted in the vicinity of the edge of the end discs on moving axes arranged in parallel with the axis of rotation of the wind motor. In this case, the segment surfaces can move about a movable axis parallel to the axis of rotation of the wind motor, which is asymmetrical with respect to the center of the surfaces, and the wider part of the segment surface can be pivoted freely outwards around an adjustable limited angle. In the folded-out state, a larger part of the surface width protrudes from the outline of the wind motor, while a narrower part advances inwards. When the horizontal wind flow impinges on an upright wind motor, the segment surface is displaced, the movable axis of which is located in the wind direction when viewed behind the wind direction from the cylindrical contour of the wind motor. The flow pressure acting on this surface uses the entire cylindrical system, causing the next segment surface to flow and move away. On the side opposite the displacement position of the system, the flow contacts the segment surfaces so that the movable axis is located in front.

This known wind motor rotates in the direction of the tails of the segment surfaces.

2 89 973 It follows that these segment surfaces act like wings, whereby the entire wind motor has the effect of impellers. It further follows that the rotational speed of this known wind motor corresponds to the wind speed. The rotational speed and thus the efficiency are strongly dependent on the prevailing wind speed.

In a vertical shaft rotor known from DE-GM 82 28 078, which is provided with two discs extending across the rotor axis and paraxial rotor blades arranged between the discs, these rotor blades are freely rotatably mounted about a swinging axis parallel to the rotor shaft. Each rotor blade is further provided with a stop, by means of which each rotor blade remains in an approximately radial position by means of its mounting of the stop. This achieves that only the rotor blades acting on the current of the 15 vertical axis motors in each rotation phase are fixed against the pressure of the driving flow, while the rotor blades, which are just out of order and only pressurized by air resistance, move freely to the lowest flow resistance position.

20

Here, too, it is true that this vertical axis rotor can maintain a rotational speed at most corresponding to the prevailing wind speed.

The object of the invention is to improve a windmill of the type mentioned at the beginning in such a way that it is particularly advantageously located in relation to the wind, that it has a particularly high efficiency and that it is very independent of the prevailing wind speed.

This object is achieved according to the invention in that the vanes are formed as carrier carriers providing a flow and the carrier vanes are pivotally mounted on pivot shafts at the front of the center of gravity of each carrier wing, in front of which there is a cam part.

In this way, a drum-shaped wind wheel of the above-mentioned type is obtained, which rotates in the direction of the cams of the bearing surfaces. At the same time, this means that the bearing surfaces can only move on the end disc. 3 9 9 7 3 3 in the area between the edge of the units and the cylindrical tube, but cannot move outwards from the cylindrical contour of the wind turbine. For this reason, the rotational speed of the wind turbine may be higher than the wind speed. Therefore, the wind wheel is particularly advantageously located in relation to the wind, and has a particularly high efficiency.

In another embodiment of the invention, the free space between the cam of the carrier wing and the tail of the next carrier wing is approximately the same as the free space between the cam of the carrier wing and the cylindrical tube. - This ensures that the wind flowing from the side opposite the windmill can easily enter and flow through the windmill. Therefore, the wind wheel receives a compressive force from the wind inflow point and at the same time a pulling force from the wind outlet point in the direction of rotation of the wind wheel.

15

Gutters can be suitably evenly distributed on the outer surfaces of the support wings. - Gutters or recesses can be arranged according to a specified regular or even irregular pattern on the surfaces of the wing blades. As a result, the wind adheres to the uneven or rough surface due to the grooves or recesses of the carrier wing and thus forms a vortex wind. The wind thus does not slide off the surface of the wing. This guarantees a very good starting of the windmill.

A front wing can be fixedly arranged for each pivot axis.

25 - This creates a space between the front wing and the retracted support wing, in which flow pressure is created by the inflowing wind. The front wings are smooth so that the wind can slide away from them as well as possible.

According to a further advantageous feature of the invention, the device may be arranged so that the carrier wing and the front wing can engage each other in the form of a hinge connection. - This ensures that the front wing remains on the axle and can move back and forth on the carrier wing.

35 In addition, stops may be provided on the edges of both end discs in the area of the tail wings. - This ensures that the wing blades do not move beyond the cylindrical contour of the windmill.

3 9 9 7 3 4

The cylindrical tube is preferably rotatably mounted on a axis of rotation coaxial with respect to the axis of the cylindrical tube.

In this connection, the device can be arranged in such a way that a generator is mounted inside the cylindrical tube 5 so that the stator of the generator is mounted on the cylindrical tube and the rotor on a fixed axis of rotation.

It is also possible to install a pump inside the cylindrical tube.

10

The windmill described above can be used in a horizontal and vertical position.

The invention will now be described in more detail by means of two embodiments shown in the drawings.

15

Figure 1 is a side view of a wind turbine formed according to the invention,

Fig. 2 is a plan view of Fig. 1, Fig. 3 is an enlarged cross-section of the wind turbine of Fig. 1,

Figure 4 is a detail of a second embodiment of the invention and 25

Fig. 5 is a detail according to Fig. 4, in which the carrier wing is turned away.

The drum-shaped windmill shown in the drawing has a cylindrical tube 30 and an upper end disk 2 and a lower end disk 3 attached to both ends of the cylindrical tube 1. In the vicinity of the edges 4 and 5 of the end discs 2 and 3, support wings 6,7,8 and 9 are arranged, which are pivotally mounted on the pivot shafts 10,11,12 and 13.

35 The wind turbine is mounted on a base 14 rotatably.

The support vanes 6,7,8 and 9 are pivotally mounted on shafts 10, 11, 12 and 13 moving in the area between the outer edge 4 and 5 0 9 9 7 3 5 and the cylindrical tube 1. As can be seen in particular from Figure 3, the support vanes 6 and 9 come to the extreme possible position while. the support wing 8 is in the widest inwardly pivotable position, and the support wing 7 moves to the middle position between the edge 4 and 5 of the end discs 2 and 3 and the cylindrical tube 1. In Fig. 3, the carrier wings 7 and 8 are shown in broken lines furthest outwards in a possible position and are denoted by reference numerals 15 and 16.

The free space 17 between the cam 18 of the carrier wing 8 and the tail of the adjacent carrier wing 9 is approximately the same as the free space 20 of the carrier. i Between nozzle 20 of nozzle 9 and cylindrical tube 1.

According to a second embodiment of the invention shown in Figures 4 and 5, the pivot shaft member 13, which can be compared to the pivot shaft 22 of Fig. 3, has a fixed front wing 23. The front wing 23 does not turn and thus maintains its position shown in Figures 4 and 5 in all windmill positions. In addition, a pivot wing 24 is provided on the pivot shaft 22, which can be compared to a pivot wing 9, 20 according to Fig. 3, which is mounted on the pivot shaft 22 in the area between the outer edge of the end discs 2 and 3 and the cylindrical tube.

The support wing 24 and the front wing 23 engage each other in the region of the pivot joint 22 like a hinge joint.

25

As the carrier wheel 24 moves inward, as shown in Fig. 5, a triangular space 25 is created between the front wing 23 and the carrier wing 24.

In order for the outer surface of the front wing 23 to move without forming an edge on the outer surface of the carrier wing 24, the carrier wing 24 is provided with a recess 26 extending over its entire length into which the front wing 23 is embedded when the front wing 23 and the carrier wing 24 are in the position shown in Fig. 4.

35 In a manner not discussed further, the end discs 2 and 3 are provided with stops to prevent the carrier wings 6,7,8 and 9 from moving too far outwards from the cylindrical 0 9 9 73 6 contour of the wind turbine.

In addition, a generator (not shown) can be mounted inside the cylindrical tube 1 so that the stator of the generator is mounted on the cylindrical tube 1 and the rotor on a fixed axis of rotation.

When the wind hits the wind wheel in the direction of arrow a, it flows through the wind wheel in the direction of arrow B and exits the arrow c direction. In this case, the support wing 8 moves against the cylindrical tube 1, and at the same time the support wing 8 acts on the support wing 8 by a force acting on the direction of rotation d. In this operating position, the carrier wing 7 comes to the middle position shown in Fig. 3.

6 and 9, between the hydrofoils and the arrow c direction of the wind wheel out-flowing air causes air outside of the cam wheel 13 in the region 15 of the vortex of the wind, which causes the blade carrier 9, the force of the arrow e direction, and that the direction of rotation d.

When the embodiment shown in Figures 4 and 5 of the wind blowing direction of the arrow f direction, there will be in addition to the above-described forces of the wind wheel to rotate 20 missuunnassa additional force of the arrow g direction, the wind catches the 24 between the front blade airfoil 23 and the triangular-shaped space 25, causing the pressure in the direction of arrow g direction .

Claims (10)

A drum-shaped wind turbine provided coaxially with a cylindrical tube 5 (1) arranged on the axis of rotation of the wind turbine, each end of the cylindrical tube (1) having a circular end disc (2,3), at least four vanes 6 with a curved streamlined profile, 7,8,9), the distance between them in the circumferential direction is equal, and which are mounted on a limited pivotal bearing in the same direction as the axis of rotation of the wind turbine on pivot axes (10,11) arranged close to the outer edge (4,5) of each end disc (2,3). 12,13), characterized in that the vanes are formed as carrier carriers (6,7,8,9) providing a carrier flow and that the carrier vanes (6,7,8,9) are pivotally mounted on pivot shafts (10,11,12, 13) in front of the 15 center of gravity of each carrier wing (6,7,8,9) with a cam part (18,21) in front. 1) r) 9 7 3 Windmill according to Claim 1, characterized in that the free space (17) between the cam (18) of the carrier wing (8) and the tail (19) of the next carrier wing (9) is approximately the same as the free space (20) on the cam of the carrier wing (9). (21) and the cylindrical tube (1). Windmill according to Claim 1 or 2, characterized in that troughs are arranged evenly distributed on the outer surfaces of the support vanes (6, 7, 8 and 9). 25 Windmill according to one of the preceding claims, characterized in that the profile strip (23) is arranged fixedly on each pivot axis (22). Windmill according to Claim 4, characterized in that the surfaces of the profile strips (23) are smooth. Wind turbine according to one of the preceding claims, characterized in that the support wing (24) and the profile strip (23) are hinged to one another in the region of the pivot shaft (22). Windmill according to one of the preceding claims, characterized in that the outer edges (4,5) of the two end plates (2,3) are provided with stops for the tail (19) of the carrier wings (6,7,8,9). area. Windmill according to one of the preceding claims, characterized in that the cylindrical tube (1) is rotatably mounted on one axis of rotation coaxial with respect to the axis of the cylindrical tube (1). Wind turbine according to one of the preceding claims, characterized in that a generator is mounted inside the cylindrical tube (1), the stator of the generator being arranged in the cylindrical tube (1) and the rotor in a stationary axis of rotation. Windmill according to one of the preceding claims, characterized in that a pump is arranged inside the cylindrical tube (1). 9 i 9 y 7 l