DE3526342A1 - Vertical wind energy converter which is mechanically controlled in dependence on wind speed - Google Patents

Abstract

Vertical rotor (wind energy converter) having two or more vertical blades, on the outside of which there are mounted folding blades which are in the shape of a half-shell and which, when all opened out, produce an upright, circular rotor body which is closed on the outside. Being rotatably mounted on one side, the folding blades mounted on the blades of the rotor automatically open on the side of the rotor receiving the wind and automatically close on the other side of the rotor, facing away from the wind. The folding blades, which are situated approximately opposite one another in pairs, are connected to one another by means of cable bracings, the length of cable determining the possible opening-out angle of the other folding blade. The cable bracings, which in each case connect two folding blades, are horizontally guided through the axial region of the rotor on deflection rollers, and, when raised here, can bring about a horizontally effective shortening of the cable leading to the open folding blade in each case, ie. leading to a reduction in the opening-out angle of the said folding blade. As a result of the fact that the folding blades are opened by the wind on the side of the rotor which receives the wind and are closed by it on the side of the rotor facing away from the wind, excellent wind resistance values which are compatible with rotation are yielded by a concave, wind-receiving side of the rotor and a convex side of the rotor facing away from the wind. The rotary energy delivered by the rotor can be set to predetermined ranges of wind speed by means of a wind flap control system ... Original abstract incomplete.

Description

The device according to the invention relates to a wind energy Converter to take advantage of very low wind speeds, with a mechanical, wind-induced Control mechanism. The combination of rotor construction and control mechanism can be within different Wind speeds are the basic size of the rotor blade surfaces up to 300% enlarged, wind-absorbing effect let what is infinitely variable and adjusted to the wind speed done automatically. The combination mentioned causes A total of three things: The possible stop of the rotation starting from a set wind speed, restarting from this stop position when it subsides of the wind back into the area of action of the rotors, both soft and gentle on the device. The continuous adjustment of the Wind acceptance values of the rotor blade surfaces within a predetermined wind speed range, and it causes on the rotor side opposite the wind through the construction minimal wind resistance values of the rotor blade surfaces.

Vertical wind energy converter, basically for hundreds of years with regard to their usability of wind energy are known in the elaboration according to the invention with those controlled by the wind speed Wind resistance values on the rotor blade surfaces, up to towards the completely neutral position of the wind resistance values on the rotor blade surfaces all around, and the resulting Possibility of action area of the new development narrow down within given wind speed ranges, in the construction and execution to be shown here  unknown.

Specifically, the device of the invention with the drawings and the associated descriptions according to Figs. I to Fig. III explained.

Fig. I perspective view of an exemplary rotor body with four folding wings and inner standing wing, as well as the top view of the rotor body with opened and closed folding wings according to the wind direction.

Fig. II View and top view of the effective deflection of the cable connections in the region of the rotor axis between two mutually opposite folding wings by deflection rollers arranged here.

Fig. III side view of the functional effect of a wind for example shaped flap with the connection to the deflection rollers in rotorachsialen area.

Fig. I shows the perspective view of a rotor design with, for example, four folding wings 4 and 6 , which are rotatably mounted about a central axis 1 on wings 2 attached here with additional half-shell-shaped wings 10 to improve the wind acceptance capability of the rotor itself. One in the direction 9 on the rotor Impacting wind (for example wind direction) opens the folding wings 6 , which are connected to the cable braces 7 with the opposite opposite folding wings 4 , guided horizontally through the rotor-axial area, the rope length of the bracing 7 being able to determine the possible opening angle of the folding wings 6 . This construction ensures that the wind against the rotor opens the folding wing on the one hand and closes the folding wing on the other. Because of the concave shape, it finds a considerable resistance area on the opened folding wings 6 , while on the convex side opposite the wind, with closed folding wings, it finds only low resistance values.

The rotor top view also shown shows with the rotary flaps 6 on the respective wind-accepting rotor side a variable changeable opening angle of the folding wings, which is determined by a mechanical control mechanism, influenced by the wind speed, as a result of which the respectively opened folding wings 6 can be reduced in their opening angle with increasing wind speeds, and thereby also in addition to the reduction of any static problems on the construction itself, the turning energy on the rotor can be reduced, so that a relatively constant rotor turning energy can be achieved over a larger wind speed range.

Also ensures the mechanical, wind speed influenced Control mechanism when the wind speeds are too high a complete closing of all folding wings, so that the rotor automatically releases the turning energy sets, - but it also starts again automatically, when the wind speed returns to the given Wind speed range of the rotor action decreases. As a result, the range of action of the rotor can be on the Wind speed range can be set, and can within this range by the folding wing control specifically deliver turning energy.

Fig. II showing a part of the control mechanism for an example, four-wing rotor design in terms of the variable folding wing-opening angle. Here, the cable strain is respectively opposite folding wings out 7 between two horizontally through the rotorachsialen area with the deflecting rollers 11 and 12, wherein the tension cable 7 can be lifted vertically by means of the deflection rollers 12, thus making it possible to shorten their effective length horizontal. After the bracing cable 7 is fixed in its horizontally effective length by a folded-up folding wing in each case, the vertical lifting of the tensioning cable 7 via the deflection rollers 11 and 12 causes a horizontally effective shortening in the direction of the respectively opened folding wing and a reduction in their opening angle.
The supervisory shows the axle tube 1 with attached thereto wings 2, in which the deflection rollers 11 are supported, and the central mounting of the guide rollers 12 by which the Umlnekrollen can be raised or lowered on the hawser 12 13.

Fig. III shows the other part of the control mechanism in a side view with the wind flap 15 , which rise above the bearing 16 in accordance with the wind speeds 20 , and thus can also lift the traction cable 13 fixed to the upper part of the wind flap, so that the wind flap, for example, at high wind speeds can ultimately reach position 18 , which means that the traction cable is fully raised. 19 here shows the exemplary stroke of the pull cable 13 with the lifting function for the deflecting pulleys. The wind flap 15 is constantly held in the wind direction by a wind vane 21 by means of its pivot bearing 22 in the axle tube 1 . This construction secures fully opened folding wings up to a certain wind speed. From this wind speed, the wind flap 15 begins to rise and reduces the opening angle of the folding wings until the wind flap has raised so far that the folding wings are all closed around the rotor and can practically no longer release any rotational energy. By shifting the weight 23 forward or backward on the wind flap 15 it can be achieved that this wind flap begins to rise sooner or later depending on the wind speed, so that the wind speed range for the use of the rotor can hereby be adjusted. (For example up to 10 m / s, up to 15 m / s or up to 20 m / s wind speed!)
parts list
1 rotor axis
2 wings
3 bearing side of the wing
4 closed folding wings
5 hinged wing stop
6 opened folding wings
7 rope tensions
8 Direction of rotation of the rotor
9 for example wind direction
10 half-shell-shaped inner wings
11 pulleys
12 pulleys
13 pull rope to the wind flap
14 Pull rope attachment to the wind flap
15 wind flap
16 Rotary bearing of the wind flap for lifting and
Lowering depending on the wind speed.
17 Wind flap lifting direction
18 fully raised position of the wind flap
19 total stroke of the pull rope
20 Direction of wind impact
21 wind vane
22 Rotary bearing of the wind flap in the rotor axle tube
23 Weight on the wind flap to control the
Wind sensitivity to lifting.

Claims (10)

Vertical wind energy converter controlled in a manner dependent on the strength of the wind, characterized in that any number of vertically arranged, vertically arranged blades are fastened around a rotor axis, on the outer ends / sides of which approximately semicircular-shaped folding blades can be rotated on one side with hinge-effective devices, or can be folded down. The overall folded up towards the rotor axis results in a vertically standing, circular and completely closed rotor body, whereby two opposing folding wings are connected by means of a rope or the like in such a way that the possible opening angle of the other folding wing is determined, and the rope, which is guided approximately horizontally through the rotor-axial area, can be lifted vertically upwards from its horizontal position in this area by means of a deflecting roller construction, whereby the horizontally effective rope length can be shortened, the possible opening angle of the folding wing changes accordingly can be. Vertical wind energy converter controlled depending on wind strength according to claim 1, characterized in that the Redirection of the rope by an approximately in the center of the axis Rotor-acting pulley system also take place can if the pulley system through the wind flap is pressed down, d. H. that this increases with increasing Wind speed the wind flap down presses.   -3- Vertical wind energy converter controlled depending on wind strength according to at least one of the claims, characterized characterized that the wind flap for control the possible opening angle of the folding wing with a Wind vane can be kept in the direction of the wind, which is why they are rotatably mounted above or on the rotor axis can be. -4- Vertical wind energy converter controlled depending on wind strength according to at least one of the claims, characterized characterized that a rope deflection for shortening of the rope between the folding wings not only can be done by a pulley system, but also can be deflected via hooks or eyes etc. -5- Vertical wind energy converter controlled depending on wind strength according to at least one of the claims, characterized characterized by a shortening of the rope lifting approximately in the middle without actual deflection can, also by pressing down accordingly. -6- Vertical wind energy converter controlled depending on wind strength according to at least one of the above claims characterized that the rope connections between two folding wings each in the form of connections can exist over belts, rods or chains.   -7- Vertical wind energy converter controlled depending on wind strength according to at least one of the claims, characterized characterized that on the wings of the rotor axis attached folding wing in an opening direction pivoted on the wings as much as you like, limited by rope length can unfold, and with the unfolding one folding wing, the opposite folding wing closed, that is pressed against the rotor. -8- Vertical wind energy converter controlled depending on wind strength according to at least one of the claims, characterized characterized that the folding wing with their the Pivoting opposite ends of the neighboring folding wing can also cover beyond its pivot bearing which in the unfolded state of the folding wing larger wind-receiving area can arise without this is on the opposite side of the rotor, then closed / folded, with regard to their wind resistance value adversely affects rotation. -9- Vertical wind energy converter controlled depending on wind strength according to at least one of the above claims characterized by a maximum opening reach a shortening of the rope so far leaves that all folding wings are in contact with the rotor, this one adjusts its rotation, and by means of the lifting process the wind flap a hook-effective device on this Flap can engage in the rotor around this one prevent further rotation.   -10- Vertical wind energy converter controlled depending on wind strength according to at least one of the above claims characterized that on by the wind speed caused opening or lifting Wind flap weights are slidably attached can be arranged accordingly in relation to Wind speed a sooner or later lifting the wind flap can cause the action area of the actual rotor rotation so on different wind speed ranges thereby being adjustable.