DE4142217C2 - Device for converting the energy of flowing media - Google Patents

Description

The invention relates to a device for conversion the energy of flowing media into another Energy form, with at least two on a holding frame pivotable, running around two deflection points endless support elements with attached at a distance Area elements for absorbing flow energy and their conversion into a rotary movement, the Distance between the front deflection points less than between the rear turning points.  

There are numerous facilities for using wind energy with horizontally or vertically arranged wind turbines or Cable cars are known by the impinging flow energy in a rotary motion to generate electri electrical current can be offset by generators.

Only horizontal wind turbines with the smaller axis can Part of the wind power striking the rotor surface use. If the rotor area is enlarged, step Vibration problems, their mastery with high Plant costs are connected. Vertical wind turbines Axis can use a larger part of wind energy  use, but their rotor area is also relative small and the investment costs are even higher than with comparable horizontal runners.

In the known facilities for converting the Flow energy based on a deflection point running support element, for example a cable car, with attached mounting surfaces for the flowing Medium is a high proportion of the flow energy captured by the receiving surfaces designed as sails, however, it requires considerable control effort and additional energy to get the best possible Position of the system in relation to the respective flow direction to reach the medium. On the other hand, there are the well-known Systems insufficiently protected against overload or a high energy expenditure is also required for this Lich.

From DE-OS 21 50 204, for example, it is already known, two endless support elements with it attached surface elements at an angle to each other arrange that the distance between the front Deflection points less than between the rear Deflection points. The panning of the endless Carrier elements are each centered in one arranged the frame construction of the support elements 360 ° axis.

In the further known from DE-GM 88 09 111 Wind turbines are on two on one platform oppositely swiveling beams several individual Rotors are provided for the absorption of wind energy. At this device, the beams on the front, the side facing the wind swiveling and also on a rotatable around a vertical axis Platform arranged. The angle of the beams and the Baffles are according to the wind speed adjustable, the straps wide in strong winds retracted and set up far in weak winds become.

An automatic, optimal adaptation to the respective Energy supply - while avoiding overloads - is however not with the devices mentioned possible.

The invention has for its object a Einrich device of the type mentioned at the beginning for converting the Ent flowing energy flowing in a rotary motion wrap that automatically and quickly on the ever aligned flow direction, a high off efficiency of flow energy guaranteed and is protected against overload with simple means.  

This task is at the beginning of a facility mentioned way of converting the energy flowing Media solved according to the invention in that the front, the pivot point of each Carrier element forming deflection points in variable, fixed adjustable distance on the Holding frames are arranged and the distance between the rear deflection points by elastic, counter the pressure of the flowing medium Fasteners can be flexibly adjusted.

The basic idea of the invention is that the Distance between the angularly arranged Carrier elements can be changed overall and on them Way an adaptation to certain flow conditions takes place, and on the other hand an automatic elastic Change the angular position of each Carrier element according to the strength of the impinging flow is made so that the device - in connection with the rotatable Arrangement of the holding frame - different Adapts flow conditions optimally.  

This makes it possible for the device to Always convert the flow energy to the respective one Flow direction sets and also smaller changes gene follows automatically, so that the flow energy can be used optimally and on the other hand at Überla stungen the support elements against the effect of elastic means are compressed and thus the area of attack for the flowing medium is reduced becomes. The plant can be used to use the wind energy, but also the energy of flowing water, the rotary generated by means of the flow energy movement to drive other units, for example Pumps, but also for the generation of electrical energy can be used by means of generators.  

According to a further feature of the invention Retaining frame rotatably arranged.

In an advantageous embodiment of the invention the support elements consist of the subclaims Cable cars, each with two superimposed ones endless ropes deflected in rope wheels, on which the surface elements designed as sails attached are. The front rope wheels are at a distance from each other adjustably arranged on the holding frame while the distance between the rear rope wheels a spring-loaded linkage can be adjusted.

In a further embodiment of the invention, the sails fixed to a rope, but up to a predetermined one  Angle α pivotally attached in the direction of rotation and connected to this rope via flexible holding ropes, while moving the other rope over a ring are kept. In addition, the sails are over roll on a rolling surface or a running track guided and finally is a lateral support the ropes over rollers attached to the cable car frame intended.

According to a further feature of the invention Weight balance for the cantilevered rope track counterweights in the area of the front rope wheels attached that over ropes and pulleys with the Rods are connected between the cable car frames, the counterweight when folding the ropeway NEN is increased in the case of high flow loads.

In an advantageous embodiment of the invention is before the front rope wheels with the holding frame or flow deflector connected to the cable cars. Finally, there are various guiding surfaces to guarantee the optimal position of the facility in Strö direction and to influence the flow via under and next to the cable cars, but also between them, provided.

In the subclaims, further features are for the purpose moderate and advantageous embodiment of the invention listed.  

The invention is based on an embodiment the drawings explained in more detail.

Show it:

Figure 1 shows a device for converting flow energy in a schematic representation in plan view.

FIG. 2 shows a partial view of the device according to FIG. 1 in the flow direction from the front;

Fig. 3 is a partial side view of the device for converting the flow energy.

The system for converting the energy flowing media, for example wind energy, into another form of energy consists of two cable cars 19 which are arranged on the front side of a cable car frame 3 in the deflection points on a holding frame 2 so as to be pivotable. The cable car frame 3 connect front and rear cable wheels 4 a; 4 b, over which a rope 5 runs. There are two front and two rear rope wheels 4 a; 4 b arranged vertically one above the other and connected by a rope wheel axis. The cable wheel axles 14 on the front cable wheels 4 a are connected via power transmission elements 18 to the shaft of a generator or a pump (not shown).

The holding frame 2 is rotatably mounted on a mast 1 via a turntable 17 . On the holding frame 2 counterweights, not shown, are also provided for counterbalancing the weight for the leeward cantilever cable cars 19 . The front cable wheels 4 a are fastened to the holding frame 2 so as to be adjustable at a distance from one another.

On the upper and lower ropes 5 of the cable cars 19 sails 6 made of plastic, canvas or metal are continuously fixed at a distance from each other and can be moved about a vertical axis and are held at least by an angle α at a distance from the rope 5 . This prevents an undesirable application of the sail 6 to the rope 5 on the side facing the flow of the cable car 19 and at the same time causes the necessary opening of the sail 6 when Umlau fen around the front rope wheels 4 a. The sails 6 are connected to the ropes 5 by tethers 12 or by springs in the pivot point facing the tethers 12 , so that they turn on the windward side in the optimum angle of attack to the wind and on the other side facing away from the wind , turn out of the wind. In addition, this connection is flexibly designed by springs, so that the sails 6 can turn leeward from the wind when overloaded and, in extreme cases, lay against the ropes 5 .

In order to avoid an inclined position of the sails 6 when the upper ropes 5 run against the lower ropes 5 , namely when the upper and lower rope wheels are rigidly connected to one another, the sails 6 are only rigidly attached to a rope while they are on the rope other rope 5 are loosely held by rings. In this variant, the sails 6 are attached to the rope 5 to which they are firmly connected by additional bracing and struts. If the sails 6 are rigidly attached to both ropes, then it is expedient not to rigidly connect the rope wheels to one another.

In order to prevent vertical sagging of the ropes 5 with the sails 6 attached to them, 6 rollers 15 are provided on the lower side of the sail 5 facing the rope 5 , which rollers 4 a; 4 b run on a rolling surface 16 . But it is also possible to arrange rollers beneath the ropes or to guide rollers 15 in running rails or to arrange the rolling surface 16 or the running rail under the total cable car 19 . In addition, 3 rollers 13 are attached to the cable car frame, which are intended to prevent lateral bending of the cables 5 , particularly in the case of long cable cars 19 . To ensure sufficient rope tension, but also for assembly and disassembly purposes, the center distance between the front and rear rope wheels 4 a; 4 b via a spring-loaded thread on the cable car frame 3 changeable bar.

The arrangement of the two cable cars 19 on the holding frame 2 is V-shaped, that is, at an angle to each other, with the further open side of the angle facing away from the wind and the cable cars 19 are thus each inclined to the wind direction. Both cable car frames 3 are connected to each other by a movable linkage 7 and can be folded up to a predetermined minimum distance against the pressure of a spring 8 in accordance with the wind pressure. When the wind pressure decreases, the spring 8 on the linkage 7 causes the cable cars 19 to spread apart, so that the receiving surfaces of the sails 6 are again completely directed towards the air flow. But it is also possible to fasten the cable cars 3 by springs on the holding frame 2 and thereby to waive on the linkage 7 .

In front of the front cable wheels 4a on the holding frame 2, a flow deflector 9 is fixed, which increases the wind pressure on the windward sail 6 and at the same time reduces the air resistance at the leeward returning sails 6 and upon opening of the sail 6 at the front end wheels 4a. In addition, further baffles 10 to increase the wind power on the sails 6, we can be arranged in front of, behind, next to, above or below the cable cars 19 , with the baffles being movably attached by springs, so that they are exposed to excessive wind pressure to turn the wind. Wide re flow guide surfaces between the axes of the front and rear rope wheels 4 a; 4 b should prevent the wind flow through the cable cars 19 .

Due to the V-shaped, rotatable arrangement of the two cable cars 19 on the holding frame 2 on the mast 1 , the device for converting the flow energy turns automatically even in relatively weak flow in the respective wind direction, so that the wind is optimal at all times is used and a complex control device is not required for this purpose and the incident flow energy can come into effect to a large extent. An optimal use of the flow energy is still guaranteed by the arrangement of the flow deflector and the guide surfaces. On the other hand, the guide surfaces, the cable cars and the sails are arranged by the flexi ble attachment so that the system is protected against overload or automatically adjusts to an excessive flow pressure. Furthermore, the device according to the invention requires a comparatively low structural effort, since it rotates without a bogie on the mast and can be made from components manufactured in series.

Reference list

1 mast
2 holding frames
3 cable car frames
4 a front rope wheel
4 b rear rope wheel
5 rope
6 sails
7 rods
8 spring
9 flow deflectors
10 guide surface
11 angles
12 tether
13 rollers
14 rope wheel axle
15 roller
16 rolling surface
17 slewing ring
18 power transmission elements
19 cable car

Claims (32)

1.Means for converting the energy flowing media into another form of energy, with at least two pivotable on a holding frame, each because two deflection points running, endless support elements with spaced surface elements for receiving flow energy and their conversion in a rotary motion, whereby the distance between the front deflection points is less than between the rear deflection points, characterized in that the front, the pivot point of the respective gene supporting element forming deflection points in variable, fixed adjustable distance on the holding frame ( 2 ) are arranged and the distance between the rear deflection points can be flexibly adjusted by means of elastic connecting elements acting against the pressure of the flowing medium. 2. Device according to claim 1, characterized in that the holding frame ( 2 ) is rotatably arranged. 3. Device according to claim 1 or 2, characterized in that the carrier elements made of cable cars ( 19 ), each with two, forming the deflection points, arranged one above the other interconnected front cable wheels ( 4 a) and rear cable wheels ( 4 b) and around the front and rear rope wheels ( 4 a; 4 b) in two levels revolving ropes ( 5 ), on which perpendicular to the direction of sail ( 6 ) are attached, and a cable car frame ( 3 ). 4. Device according to one of claims 1 to 3, characterized records that the support elements from flat Lanes each with the front points forming the deflection points and rear rollers. 5. Device according to one of claims 1 to 4, characterized in that the axes of the front and rear rope wheels ( 4 a, 4 b) are vertically angeord net. 6. Device according to one of claims 1 to 5, characterized in that the front cable wheels ( 4 a) of the cable cars ( 19 ) are arranged adjustable on the holding frame ( 2 ) at a distance from one another. 7. Device according to one of claims 1 to 6, characterized in that the cable cars ( 19 ) are freely cantilever and pivotally mounted on the holding frame ( 2 ) and the distance of the rear Seilrä the ( 4 b) of the cable cars ( 19 ) a on the cable track frame ( 3 ) attached, spring-loaded linkage ( 7 ) is adjustable. 8. Device according to claim 7, characterized in that instead of the linkage ( 7 ) a resilient connec tion between the cable car frame ( 3 ) on the windward side in front of the holding frame ( 2 ) or between the cable car frame ( 3 ) and the holding frame ( 2 ) is provided. 9. Device according to one of claims 1 to 8, characterized in that the sails ( 6 ) on the superimposed ropes ( 5 ) of the cable cars ( 19 ) are attached. 10. The device according to claim 9, characterized in that the sails ( 6 ) rigidly attached to a rope ( 3 ) and connected by additional struts or rope tension with this rope ( 3 ) or the adjacent sails ( 6 ) and on the other Rope ( 3 ) of the respective cable car ( 19 ) are kept movable. 11. The device according to claim 10, characterized in that the sail ( 6 ) on one of the superposed ropes ( 3 ) through a ring attached to the sail ( 6 ) and by a lock at an angle to the ropes ( 3 ) the windward side are held. 12. Device according to one of claims 1 to 11, characterized in that the front and back tere rope wheels ( 4 a, 4 b) loose and the sails ( 6 ) are firmly connected to both ropes. 13. Device according to one of claims 9 to 11, characterized in that the sails ( 6 ) in the longitudinal direction of the rope ( 3 ) are pivotally attached to the ropes ( 3 ). 14. Device according to one of claims 9 to 13, characterized in that the sails ( 6 ) with each other or with the ropes ( 3 ) connected by flexible holding ropes ( 12 ) and under the ropes ( 3 ) rollers are attached for support. 15. Device according to one of claims 1 to 14, characterized in that on the lower edge of the sail ( 6 ) rollers ( 15 ) are attached, which are supported on a below the cable car ( 19 ) arranged rolling surface ( 16 ) or a running rail . 16. Device according to one of claims 1 to 15, characterized in that on the inward longitudinal edges of the sails ( 6 ) rollers for lateral guidance of the sails ( 6 ) on between the front and rear cable wheels ( 4 a; 4 b) arranged guide surfaces are provided. 17. Device according to one of claims 1 to 16, characterized in that on the cable car frame ( 3 ) rollers ( 13 ) for guiding and lateral support of the cables ( 5 ) are attached. 18. Device according to one of claims 1 to 17, characterized in that the sails ( 6 ) have an aerodynamic profile and consist of plastic, metal or canvas. 19. Device according to one of claims 1 to 18, characterized in that the cable cars ( 19 ) are designed as chain tracks with chain wheels as deflection elements and with chains as carrier elements. 20. Device according to one of claims 1 to 19, characterized by arranged on the rope wheels ( 4 a; 4 b) to ensure the rope tension as well as for assembly and disassembly purposes. 21. Device according to one of claims 1 to 20, characterized in that counterweights are provided at its front end with the linkage ( 7 ) via Umlenkrol len and ropes for weight compensation for the cantilevered cable cars ( 19 ). 22. Device according to one of claims 1 to 21, characterized in that in front of the front rope wheels ( 4 a) a flow deflector ( 9 ) on the holding frame men ( 2 ) or on the cable cars ( 19 ) is attached. 23. Device according to one of claims 1 to 22, characterized in that further guide surfaces are provided in front of and next to the cable cars ( 19 ) to increase the flow effect and to stabilize the flow direction. 24. Device according to claim 23, characterized net that the guide surfaces according to the Strö load through power transmission elements are movably arranged.   25. Device according to one of claims 1 to 24, characterized in that further guide surfaces are arranged in front of, behind and between the rope wheel axes ( 14 ). 26. Device according to one of claims 1 to 25, characterized in that further horizontal and inclined, movable guide surfaces above and below the cable cars ( 19 ) and behind the cable cars ( 19 ) are arranged. 27. Device according to one of claims 1 to 26, characterized in that brakes are attached to the axes of the respective front deflection points, the brake cylinder with a lever with the Seilbahnrah men ( 3 ) connected when folding together the cable car frame ( 3 ) independently effective are. 28. Device according to one of claims 1 to 27, characterized in that the mast ( 1 ) is at least once tiltable. 29. Device according to one of claims 1 to 28, characterized in that the front cable wheels ( 4 a) on the holding frame ( 2 ) arranged force transmission elements ( 18 ) with generators for electricity generation or pumps or similarly driven units are connected. 30. The device according to claim 1, characterized in that on the holding frame ( 2 ) two vertical rotors and a front flow deflector ( 9 ) are introduced. 31. The device according to claim 30, characterized net that the vertical rotors lateral Windleitflä Chen are assigned. 32. Establishment after one of the Claims 1 to 31, characterized through use for demonstration purposes and / or as a toy.