DE3501807A1 - Fluid-flow engine for obtaining energy - Google Patents

Abstract

Fluid-flow engine for obtaining energy, in particular wind power machine operating by using the Magnus effect, having at least one roller-shaped rotor with transverse incident flow. In this case, the rotors (11) are guided with their axes (12) at least approximately parallel to each other on a closed circuit about the axis of a shaft (14) arranged perpendicular to the flow direction, while their drive varies during the circulation about the shaft (14) in such a way that the direction of rotation of the rotors (11) is reversed at the latest when they are moving on their circuit about the shaft (14) from the sector thereof with the incident flow into the sector of the fluid-flow engine (10) averted from the flow (w), and vice versa. <IMAGE>

Description

Flow machines for energy generation

The invention relates to a turbomachine for generating energy, in particular a wind power machine that uses the Magnus effect, with at least one cylinder-shaped rotor with a transverse flow.

In known turbomachines of the type mentioned, the rotors star-shaped on axes rotating in the vertical plane around a horizontal shaft arranged.

With a correspondingly strong, at least approximately in the direction of the wave running air flow displace them in the same direction with their own driving force driven rotors due to the so-called Magnus effect on them effective transverse output, the shaft rotates like a windmill.

To compensate for the increasing distance from the shaft, increasing relative speed between the flowing air and the in the rotating flow generated around the rotors are in the DE-PS 483 813 known turbomachine of this type, the rotors are frustoconical with formed on the shaft lying smaller diameters. By this way adjusted relative speeds become friction losses of the flowing Medium largely avoided.

The known ones based on the use of the Magnus effect Turbomachines require the rotors to be arranged in a vertical plane requires a considerable overall height of these turbomachines. Since this at least must correspond to twice the length of the rotors, are used for the assembly of the known Fluid flow machines are particularly stable, high and therefore expensive and complex frames respectively. Lattice towers are required, which also reduce the flow resistance on the leeward side increase and thus have an unfavorable effect on the efficiency of the system. The known Turbomachines with rotors rotating in a vertical plane also have the disadvantage that the rotational speed of the rotors because of the increasing Height increasing flow velocity of the air not or only with disproportionate great effort can be optimally adapted to the wind speed.

The invention is therefore based on the object of the Magnus effect to simplify exploiting flow machines and the implementation of the available to improve standing wind energy.

In a turbo machine, this task is closer to the one at the beginning described type solved according to the present invention in that the rotors with their axes at least approximately parallel to themselves on a closed one Orbit around the axis of a shaft perpendicular to the direction of flow are performed, from which the energy obtained can be removed and that their drive changes during the revolution around the shaft.

Because of the axes that are guided parallel to themselves according to the invention the rotors succeed in the overall height and the width of such turbomachines to reduce significantly and thus save the costs for high frames. Simultaneously succeeds in eliminating the differences in the flow rate to be largely eliminated and thus more favorable energy conversion values to achieve. Turbomachines with the features according to the invention are suitable due to its relatively small dimensions, it is particularly suitable for use where they should only be conspicuous a few and take up little space, such as as superstructures on tall buildings or the like.

An advantageous development of the subject matter of the invention is seen in the fact that the direction of rotation of the rotors reverses at the latest when they move on their orbit around the wave from the sector to which the flow is flowing to that of the flow remote sector of the turbomachine and vice versa move. In this way it is possible to achieve the same flow conditions the shaft exerted torques and thus the performance of the turbomachine double.

According to a preferred embodiment of the subject of the application, it is provided that at least two rotors are arranged on a bogie, which rotatably is connected to the shaft and this with rotors rotating in flowing air drives.

Particularly favorable conditions arise when according to a Another embodiment of the invention provides that the rotors are arranged vertically and move with their axes around a vertical wave.

In this case, the otherwise required in such turbomachines Devices with which the rotors are aligned perpendicular to the wind direction must, superfluous.

According to a modified embodiment it is provided that the rotors are arranged at least approximately horizontally across the flow and with their Move axes around a parallel shaft.

Further, characterized in the claims, advantageous features of Invention are in the following description with reference to two in the attached Drawings as schematically illustrated exemplary embodiments explained. 1 shows a wind power machine operating according to the Magnus effect, with three rotors rotating around a vertical axis, against which the flow is flowing, in the view from the side, as a first embodiment, Fig. 2 is a view the wind power machine according to Fig. 1, with three at the corner points of an equilateral Rotors arranged in a triangle and FIG. 3 shows one operating on the same principle Wind power machine in which the transversely flowed rotors lie around a horizontal one Move the axis, as a second embodiment.

In a wind power machine designated by 10 in FIGS. 1 and 2 are three independently drivable rotors 11 to utilize the Magnus effect mounted perpendicular to axes 12, which near the ends of the arms of a three-pronged Turnstile trained bogie 13 are arranged. In the illustrated embodiment rotors arranged in the corner points of an equilateral triangle on the turnstile are only at their lower end and therefore cantilevered.

To stabilize their storage, however, you can also use a second turnstile seated at its upper end. Furthermore it is possible to store the rotors in the middle on only one turnstile, provided that the required stability is guaranteed. Instead of the one used here Bogie in the form of a turnstile with only three arms are also other frames conceivable, on which then a large number of rotors with a pitch that is as uniform as possible are arranged on a circle around the center of the bogie.

The rotors designed as hollow rollers to reduce weight 11 are, as will be explained in more detail below, individually by invisible Electric motors can be driven, which are protected and aerodynamically inside the rotors 11 seated.

The bogie equipped with the rotors 11 in the manner described 13 is rotationally fixed in its center to a vertical shaft 14, which in turn in a known and therefore not shown manner in a pivot bearing 15 stored in the form of a vertical tube and from which the generated Torque is removable.

In the illustrated embodiment, the pivot bearing 15 a wind vane 16 is arranged which, in cooperation with a control disk 17 serves to drive the rotors 11 as a function of the individual motors to control the wind direction w. The control of the motors for the rotors 11 is designed so that the latter, as can be seen in particular from Fig. 2, a drive in the sense of a right turn + u experience as long as they are facing the wind Side of the wind power machine 10 are located. However, as soon as it is rotating the Bogie 13 in the direction of arrow R around the center of that facing the wind page Move to the side of the wind power machine 10 facing away from the wind, the drive direction of the rotors 11, for example by reversing the polarity of the motors driving them, reversed. Each time the center plane normal to the wind direction w is exceeded, the Rotors 11 stop before they start in the opposite direction. However, it can it can also be provided that the rotors 11 only in one direction and then only as long be driven as they move towards or away from the wind on their path Move the side of the wind power machine 10.

With the drive direction described and one in the sense of the arrows w moving air results in those indicated in FIGS. 1 and 2 by arrows + u and -u Conditions. Due to the fact that occurs when the air is flowing and the rotors are running Magnus effect. and the forces q acting on the rotors 11 as a result Via the bogie, moments that change with the changing angular position exerted on the shaft 14 and released from it. By adapting accordingly the speed of rotation of the rotors 11 to the prevailing wind speed and possibly also the changing angular position of the rotors, it is possible to improve the efficiency the illustrated and described wind power machine and the energy yield generated with it to optimize Deviating from the illustrated and described embodiment it can also be provided that the wind vane 16 is located above the wind power machine 10 is arranged so that it can be flown freely by the wind. The control the motors is done here with the help of the wind vane 16, for example by on the control disk segment-like arranged sliding contacts.

While the drive speed of the rotors 11, as at below Usage of the Magnus effect working wind power machines - so chosen is that their peripheral speed is about four times the flow speed corresponds to the wind, their length and diameter should be selected as far as possible so that that under the prevailing conditions, the greatest possible energy yield is achieved. The number of rotors and their distance to the shaft, on the other hand, is in widely variable. Just take care that neighboring rotors are not too close together so that they move around shaft 14 Do not cover for too long in the direction of the wind, otherwise the efficiency will be reduced by the formation of eddies and the like. Is adversely affected.

The embodiment shown in FIG. 3 is based on the Magnus effect based wind power machine 10 'differs from that in connection with 1 and 2 described wind power machine 10 essentially in that here the rotors 11 are arranged horizontally, transversely to the flow w and with move their axes 12 about a shaft 14 running parallel thereto. Unlike in the previous case, the wind power machine 10 'is direction-dependent here. This one Factor is taken into account by a pivot bearing 15 ', through which it is possible the wind power machine 10 ', for example, with that acting on a wind vane 16' Align wind power in the direction of arrow r transversely to the wind direction. In this case the motors driving the rotors 11 are controlled from the wind direction w independently via sliding contacts on the control disk 17 '. With the one shown here Wind power machine it is possible to have the shaft 14 'as well as the axes 12 of the rotors 11 to be set in any position within the plane perpendicular to the wind direction w, without affecting the function of the wind power machine.

- blank page -

Claims (7)

Claims 1 flow machine for energy generation, in particular using the Magnus effect working wind power machine, with at least a roll-shaped rotor with a cross-flow, d a d u r c h e k e n n n z e i c h n e t that the rotors (11) with their axes (12) at least approximately parallel to itself in a closed orbit around the axis of a perpendicular to the Flow direction (w) arranged shaft (14, 14 ') are guided, and that you Drive changes during the revolution around the shaft (14, 14 '). 2. Turbo machine according to claim 1, characterized in that the direction of rotation (+ u, -u) of the rotors (11) reverses at the latest when they on its orbit around the shaft (14, 14 ') from the sector against which the flow flows into move the sector of the turbomachine (10) facing away from the flow and vice versa. 3. Turbomachine according to claim 1 or 2, characterized in that that at least two rotors (11) are arranged on a bogie (13, 13 '), which is rotatably connected to the shaft (14, 14 ') and this is in flowing Air (w) drives rotating rotors (11). 4. Turbomachine according to claim 1, 2 or 3, characterized in that that the rotors (11) are arranged vertically and with their axes (12) around move a vertical shaft (11). 5. Turbomachine according to claim 1, 2 or 3, characterized in that that the rotors (11) are arranged at least approximately horizontally across the flow (w) are and their axes (12) around a parallel shaft (14 ') move. 6. Turbo machine according to claim 5, characterized in that the rotors (11) can be aligned transversely to the flow (w) by means of a wind vane (16 ') are. 7. Turbo machine according to one of the preceding claims, characterized characterized in that the drive of the rotors (11) via a control disc (17) and a wind vane (16) influenced by the direction of flow (w) can be controlled.