SE524227C2 - Apparatus and method for generating lifting power for extracting energy from a by-flow medium - Google Patents

Abstract

The invention relates to a device for generating a lifting force for extraction of energy from a medium flowing by, comprising an elongated body (11) having an outer surface (12) for affecting a first medium flowing by, a first end (13) connected to an underlayer through a bearing (19) and a free second end (14), wherein the elongated body (11) is arranged pivotally around at least one portion of the bearing (19). The elongated body (11) comprises a plurality of slits (25) for a second medium flowing out through the slits (25), wherein the second medium flows out towards the outer surface (12) to affect the first medium flowing by the outer surface (12) while generating a lifting force. Further, the slits (25) are adjustable, wherein a direction of the second medium flowing out is adjustable for alternating a direction of the lifting force while bringing the elongated body (11) around the bearing (19).

Description

faaan: Jamo 10 15 20 25 O.) C) - n | 524 227 2 comprises one or more elongate and arcuate rotor blades which are connected at both ends to a vertical shaft, such as a vertically arranged tower or the like. The rotor blades are arranged so that they can rotate about the vertical axis, whereby wind energy can be converted into electrical energy by means of a generator. Typically, this type of wind turbine comprises two or three rotor blades, which are flexible and mounted in the axial direction to the vertical axis.

Due to the centrifugal force, the ends of the rotor blades are compressed along the vertical axis during operation, the swept area varying with the rotational speed.

A problem with this type of wind turbine is that it is costly and that large plants are required to keep the costs of electricity production down. This means that wind turbines of known technology can hardly be used for the production of household electricity, for example directly at the consumer or the consumer.

Another problem with wind turbines of known technology is that they can cause negative environmental effects as they are visible in the distance and thus constitute a disturbing element in the landscape. Furthermore, this type of wind turbine has an additional environmental impact in the form of noise. It is not uncommon for wind turbines of known technology to be heard at a distance of several hundred meters.

A disadvantage of such wind turbines of known technology is that they have a complicated construction with a number of moving parts, which provides a low operational reliability and entails large costs for installation and maintenance.

Another disadvantage of wind turbines including the Darrieus turbine is that they have low efficiency.

SUMMARY OF THE INVENTION An object of the invention is to avoid the above-mentioned disadvantages and problems with devices for recovering energy, such as wind turbines, of prior art. The invention provides a cost-effective device and method which is suitable for use by both households and large-scale electricity producers. Furthermore, a reliable and environmentally friendly device is achieved - p4086seO0ps; 10 15 20 25 30 0 t o u: o c 524 227 3 n n u «. .. which does not disturb the landscape image as a result of a less conspicuous pendulum-elongated body being used instead of rotor blades. A disadvantage of devices of known technology is that the rotating movement attracts attention and thus can constitute a negative environmental impact. A further object of the present invention is to provide an apparatus and method for generating lifting force for energy recovery. Yet another object of the present invention is to provide an efficient change of direction of the lifting force. Another object of the present invention is to utilize the elongate body for energy recovery. In the prior art, a tower is instead used to raise the wind turbine or rotor blade from the ground level, which is why only a small part of the construction of non-toxic wind turbines is used for energy recovery. This is achieved by the invention obtaining the features stated in claims 1 and 7.

The device according to the invention comprises an elongate body with an outer surface for actuating a bypassing first medium, a first end connected to a support via a bearing and a second end arranged projecting therefrom, the elongate body being rotatably arranged around at least a portion of the bearing . The device may be in the form of a pendulum wind turbine, the by-passing first medium being by-passing air. The device may comprise conventional transmission, such as hydraulic cylinders or the like, for converting kinetic energy into, for example, electrical energy. Thus, the first medium flows towards the elongate body and is forced around its periphery.

The device comprises an elongate body connected to a counterweight and a bearing, wherein the elongate body can oscillate around the bearing.

The elongate body comprises a first end connected to a base via the bearing and a free second end. Furthermore, the device may comprise supports connected to the bearing and a rotatable foundation so that the device can be rotated in the direction of the bypassing medium. For example, the device comprises a conventional turning machinery so that the device can be rotated in the direction of the bypassing medium. For example, the foundation is connected to the substrate. p4086se00ps; : uno - u 10 15 20 25 30 c c: n nu: '"I I o -ø u.» -, ,, gg-. -..,,' n n.

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I n 4 The elongate body comprises a plurality of slots for a second medium flowing out through the slots. The slits are designed so that the second medium flows out towards the outer surface of the elongate body for influencing the bypassing first medium while generating lifting force. The second medium flows, for example, through the elongate body and out through the gaps. The elongate body may thus be hollow or comprise a channel for the second medium. Furthermore, a fan may be provided in a portion of the elongate body to provide the flow of the other medium. The other medium can also be air or the like.

The columns are distributed around the elongate body in a suitable manner and can stretch in the longitudinal direction of the elongate body. Alternatively, the columns are designed as a plurality of openings arranged in line. For example, the gaps are made as a perforation or a plurality of perforations. The slits may be arranged at an oblique angle to the elongate body so that the second medium flows out substantially tangentially around the periphery of the elongate body. In this way, a lifting force is generated by affecting the by-flowing first medium and accompanying the outflowing second medium.

The device can be designed so that lifting force is generated substantially perpendicular to the direction of the bypassing first medium.

The columns are adjustable so that a direction of the outflowing second medium is adjustable, whereby a change of a direction of the lifting force is effected. Thus, lifting force is initially generated in a direction perpendicular to the direction of the bypassing medium so that the elongate body is moved in the direction of the lifting force. Then the direction of the outflowing second medium is changed so that the direction of the lifting force is changed while carrying the elongate body around the bearing. In this way, an efficient oscillating movement of the elongated body is achieved so that energy can be extracted.

A directional effect of the columns can be fixed or adjustable. Columns with a fixed directional effect can be activated and closed depending on the desired direction of lifting force. For example, the device comprises a set of slits arranged at an oblique angle to a periphery of the elongate body so that the outflowing second medium is caused to flow clockwise along the p4086seO0ps; »Faan 10 15 20 25 30 '0 I e a: 524 227 5 u. =. 1 »the outer surface of the elongate body and at least one set of slits arranged at an oblique angle to a periphery of the elongate body so that the outflowing second medium is caused to flow counterclockwise along the outer surface of the elongate body. For example, the clockwise slots are activated when lifting force in one direction is desired, whereby the counterclockwise slots are closed. When lifting force in the opposite direction is desired, the counterclockwise slots are activated, whereby the clockwise slots are closed. Activation and shut-off of the gaps can be achieved by connecting them to and separating them from the second medium flowing in the elongate body. For example, dampers can be arranged along at least a portion of the respective gap. Thus, a rotary damper or sliding damper or the like can be arranged immediately inside the gap along its entire length. For example, the slots can be made openable, whereby they function both as a slot and a damper. In this way, a rapid adjustment of the lifting force is achieved. Alternatively, dampers and gaps may be provided during the formation of a distribution space, such as a duct, whereby a damper can serve one or more of the gaps and the location of dampers becomes freer. Columns with adjustable directional effect can be activated at all times. instead, the direction of the columns can be adjusted with a mechanism suitable for the purpose.

The adjustment of the columns can be designed in several ways. For example, the device may comprise a rotatable member or a plurality of rotatable members which open and close the slots. The rotatable member can be designed in the form of a damper which enables opening and closing of the slots. The dampers can be made in the form of rotary or sliding dampers. Alternatively, the rotatable member can be designed as a rotatable wall element with a guide member arranged in a central portion thereof, wherein the slits can be opened and closed by rotating the wall element. For example, the channel in the elongate body can be divided by dividing walls so that the second medium can be supplied with a set of gaps or individual gaps for regulating the direction of the outflowing medium. Alternatively, the gaps can be created by means of plates or plate elements which can be rotated via a joint, whereby gaps can be opened and closed. The elongate body may comprise two sets of gaps, one set of which is directed so that the outflowing second medium flows clockwise and the second set is directed so that the second medium flows mop4086se00ps; 10 15 20 25 30 ø o | v q, 524 227 s tour around the elongated body. By causing the second medium to flow out through a set of columns at a time, the oscillating movement is achieved. Alternatively, all columns can be rotatably designed, all columns being directed clockwise for generating lifting force in one direction or counterclockwise for generating lifting force in the opposite direction. However, it will be apparent to one skilled in the art that the columns may be formed in a variety of ways within the scope of the present invention.

The elongated body can be symmetrically designed to achieve an even distribution of the lifting force. In this way, the device has no distinct angle of attack, as is the case with conventional wind turbines. For example, the elongate body is designed as a cylinder, whereby a greater lifting force per unit area is achieved in comparison with conventional wing profiles. For example, the elongate body is designed as a circular cylinder.

The elongated body also provides lifting force within large variations of the angle of attack and the direction of the lifting force can be changed by adjusting the column F13.

The method according to the invention comprises the steps of causing the second medium to flow through the gaps towards the outer surface of the elongate body for influencing the first medium flowing past the outer surface while generating lifting force, and by changing the gaps a direction of the outflowing second medium for changing a direction of the lifting force while carrying the elongate body around the bearing.

In this way, the commuting movement is achieved in an efficient way for further extraction and conversion of energy.

Additional features and advantages of the present invention will become apparent from the following description, accompanying figures, and dependent claims.

BRIEF DESCRIPTION OF THE DRAWINGS The invention will now be described in more detail with the aid of exemplary embodiments with reference to the accompanying drawings, in which p4086se0Ops; 10 15 20 25 '~ n. pp. 524 227 7 n n t. ..

Fig. 1 is a schematic side view of the device according to an embodiment of the invention, Fig. 2 is a schematic front view of the device according to Fig. 1, Fig. 3 is a schematic side view of the device according to Fig. 1 and Fig. 2 showing the oscillating movement of the elongate body, Fig. 4 is a schematic side view of a portion of the device according to the invention in cross section, showing an interior of a portion of the elongate body and a portion of the transmission of the device, Fig. 5 is a schematic view from above of the device according to the present invention, Fig. 6 is a schematic cross-sectional view of the elongate body according to a first embodiment of the present invention, Fig. 7 is a schematic cross-sectional view of the elongate body according to Fig. 6, showing the generation of lifting force in a Fig. 8 is a schematic cross-sectional view of the elongate body of Fig. 6, showing the generation of lifting force in the opposite direction; Fig. 9 is a schematic side view of a portion h Fig. 10 is a schematic cross-sectional view of the elongate body according to a second embodiment of the present invention, Fig. 11 is a schematic cross-sectional view of the elongate body according to a third embodiment of the present invention. Fig. 12 is a schematic cross-sectional view of the elongate body according to a fourth embodiment of the present invention; Fig. 13 is a schematic cross-sectional view of the elongate body according to the fifth embodiment of the present invention, p4086se00ps; true 10 15 20 25 en. .inn 524 227 š ii! 8 ~ | . . Fig. 14 is a series of schematic cross-sectional views of the elongate body according to a sixth embodiment of the present invention, Fig. 15 is a series of schematic cross-sectional views of the elongate body according to a seventh embodiment of the present invention, and Fig. 16 is a series of schematic cross-sectional views. of the elongate body according to an eighth embodiment of the present invention.

The invention according to Fig. 1 and Fig. 2 schematically illustrates a device 10 in generating lifting force for extracting energy from an bypassing first medium according to the present invention. The device 10 is embodied, for example, as an energy conversion device or energy recovery device for converting or recovering energy from the bypassing first medium. For example, the bypassing first medium is an air flow, such as wind, the device 10 being embodied in the form of a oscillating wind turbine for recovering energy by generating lifting force. The device 10 is designed, for example, for converting wind energy into electrical energy.

The device 10 comprises an elongate body 11 with an outer surface 12 for actuating the bypassing first medium, the first medium flowing towards the elongate body 11 being forced around the outer surface 12 of the elongate body 11 for passage thereof before continuing its original direction. Thus, a first medium flows around a periphery of the elongate body 11.

The elongate body 11 further comprises a first end 13 and a second end 14. The first end 13 is arranged in a lower portion of the elongate body 11 and the second end 14 is arranged in an upper portion thereof. The first end 13 is connected to a base 15 via a foundation 16 and a bearing 19 arranged in a first support 17 and a second support 18.

The first end 13 is also connected to a counterweight 20. Thus, the elongate body 11 is connected to the base 15 via the bearing / 19, the elongate body 11 being rotatably arranged about at least one p4086se00ps; 10 15 20 25 30 v I v | zu øn. ,,,.

'Ifova, "" n:' .'_'__. Fl =; a:. z .v n n g '° l n-fß, "I n." =. ~ 9 batch thereof. The bearing 19 can be arranged in another way, which is obvious to a person skilled in the art. The counterweight 20 is suitably made with an overweight relative to the elongate body 11 so that the elongate body can oscillate around the bearing 19.

The base 15 is suitably firmly anchored in the underlying ground so that the device 10 stands firmly when the elongate body 11 oscillates. The first support 17 and the second support 18 are in a lower part connected to the foundation 16, an upper part projecting in the vertical direction upwards. The supports 17, 18 are arranged, for example, in parallel to form a space for the lower part of the elongate body 11 and the counterweight 20. The bearing 19 is suitably arranged at the upper part of the supports 17, 18 and above the counterweight 20 so that the elongate body 11 brought to a vertical position in the absence of the influence of the bypassing first medium. The bearing 19 is for instance designed as a shaft arranged through the supports 17, 18 and the lower part 11 of the elongate body 11. The second end 14 is a free end, or arranged projecting from the first end 13 and the base 15.

Referring also to Fig. 3, the oscillating movement of the elongate body 11 is illustrated. The device 10 is designed so that the elongate body 11 is rotatable about at least a portion of the bearing 19, whereby a oscillating movement can be effected. This is illustrated by means of the arrow A. In Fig. 3 the elongate member 11 is shown in a first end position as it has been turned clockwise as a result of the bypassing first medium while carrying the counterweight 20. Furthermore, the elongate member 11 is shown in a vertical position and in a second end position when, as a result of the bypassing first medium, it has been turned counterclockwise by means of dotted lines. The device 10 is designed to generate a lifting force perpendicular to the bypassing first medium, whereby the elongate body 11 is caused to rotate around a portion of the bearing 19. When the elongate body 11 passes a given boundary position, the direction of the lifting force changes so that the elongate body 11 is caused to accelerate in the opposite direction and thereby turn at the desired end position. In this way a oscillating movement is effected of the elongate member 11, whereby energy can be extracted from the bypassing first medium and converted into, for example, electrical energy. Energy conversion is accomplished p4086seO0ps; canon n o 10 15 20 25 524 227 10 n o n 1 | o 'for example in a conventional manner by means of hydraulics, a generator and the like.

The elongate body 11 is suitably symmetrically designed to facilitate rotation in opposite directions about the bearing 19 and to achieve a smooth oscillating movement. For example, the elongate body 11 is formed in the form of a circular cylinder. Alternatively, the elongate body is made with an elliptical cross-section or the like.

Referring to Fig. 4, a portion of the device 10 is partly illustrated in cross section. The elongate body 11 comprises a channel 21 for transporting a second medium inside the elongate body 11. For example, the elongate body 11 is hollow so that a second medium, such as air, can flow in the elongation of the elongate body 11. In the channel 21, a fan 22 is arranged to effect a flow of the second medium inside the channel 21. The fan 22 is arranged, for example, in the lower first end of the elongate body 11.

Fig. 4 also schematically illustrates the transmission of the device 10 for converting energy from the oscillating movement into, for example, electrical energy according to an embodiment of the present invention. The device 10 comprises a counterweight 20 and the support 17, 18 connecting first hydraulic cylinder 23 and a counterweight 20 and the support 17, 18 connecting second hydraulic cylinders 24. Alternatively, the hydraulic cylinders 23, 24 are connected to the elongate body 11 and the foundation 16 or otherwise so that the hydraulic cylinders 23, 24 are compressed and pulled apart as the elongate body oscillates. For example, hydraulic cylinders are arranged in a corresponding manner on the opposite side of the device 10, the device 10 comprising four hydraulic cylinders. The hydraulic cylinders 23, 24 are connected to a generator or the like, which is not shown in the figures, so that the energy can be converted into electrical energy or another form of energy. The transmission of the device 10 is, for example, carried out in a conventional manner. Referring to Fig. 5, the device 10 is illustrated seen from above.

The foundation 16 is connected to the base 15 via a hinge member, which is not shown in the figures, so that the foundation 15 is rotatable in the horizontal direction. This p4086se0Ops; : anno 10 15 20 25 30 o o n. ., 524 227 11. u n o | eo is illustrated in Fig. 5 by means of the arrow B. Thus, the foundation 15 can be rotated while carrying the supports 17, 18 and the elongate body 11, whereby the elongate body 11 can be adjusted in the direction of the bypassing first medium. In this way, the device 10 is adjustable according to a wind direction so that the elongate body can oscillate perpendicular to the wind direction regardless of its direction. For example, the device 10 comprises a motor for rotating the foundation 15 around the hinge member. The hinge member and the motor are, for example, designed in a conventional manner and are not described in more detail.

Referring to Fig. 6, the elongate body 11 is illustrated in cross-section according to a first embodiment of the present invention. The elongate body 11 comprises a plurality of slots 25 for a second medium flowing out through the slots 25. The second medium flows out towards the outer surface 12 for influencing the bypassing first medium while generating lifting force. The columns are, for example, designed as an elongated opening. Alternatively, the slots are made as a plurality of openings, such as a perforation or a plurality of perforations. The slits 25 connect the channel 21 and the outer surface 12 of the elongate body 11. The slits 25 are thus performed for transporting the second medium flowing inside the elongate body 11 to the outer surface 12 thereof. As a result of the bypassing first medium following the outflowing second medium, a lifting force is generated perpendicular to the direction of the bypassing first medium, the elongate body being caused to rotate around the bearing 19 in the direction of the lifting force. The elongate body 11 is suitably provided in its upper other end 14 with a closure, a lid or the like so that the second medium is forced out through the slots.

The slits 25 are distributed around a periphery of the elongate body 11 to enable the generation of lifting force in opposite directions so that the oscillating movement can be effected. The slits 25 are symmetrically distributed around the elongate body 11 to achieve a smooth oscillating movement. In the first embodiment of the present invention shown in Fig. 6, the device 10 comprises a first set of slots for generating lifting force in one direction and a second set of slots for generating lifting force in the opposite direction. The first set of columns are arranged at an angle to a radial p4086se0Ops; »Vara 10 15 20 25 30 o o | c; stretching of the elongate body 11, the outflowing second medium flowing along the outer surface 12 in the direction of the bypassing first medium. The slits 25 are thus made at an oblique angle to the elongate body 11 so that the second medium flows tangentially with the outer surface 12. This is illustrated by means of the arrows C. The second set of slits is arranged in a corresponding manner, which is illustrated by means of of the arrows D. The device 10 is designed so that the direction of the lifting force can be changed, which is described in more detail below. Alternatively, the slits are made with a curvature or the like for the outflowing second medium to follow the outer surface 12 or mantle surface of the elongate body 11. For example, the elongate body 11 includes reinforcements 26 or a framework or the like to stabilize the elongate body. The reinforcements 26 are, for example, arranged in a conventional manner.

Referring to Fig. 7, the direction of the lifting force and the by-flowing first medium is illustrated as the outflowing second medium flows out of the first set of gaps. The direction of the outflowing second medium is illustrated by means of the arrows C, the direction of the overflowing first medium is illustrated by means of the arrows E and the direction of the lifting force is illustrated by means of the arrow F.

With reference to Fig. 8, the direction of the lifting force and the bypassing first medium is illustrated as the outflowing second medium flows out of the second set of gaps. The direction of the outflowing second medium is illustrated by means of the arrows D, the direction of the overflowing first medium is illustrated by means of the arrows E and the direction of the lifting force is illustrated by means of the arrow G.

Referring to Fig. 9, a portion of the device 10 is shown perpendicular to the direction of the bypassing first medium. The slits 25 are arranged in the longitudinal direction of the elongate body. Thus, the slits 25 extend from a lower portion of the elongate body 11 to an upper portion thereof, or substantially from the first end 13 to the second end 14. Thus, the slits 25 divide the outer wall 11 of the elongate body into a plurality of wall elements. Alternatively, the columns are made in the form of a plurality in the elongate p4086se00ps; : axon 10 15 20 25 30 I - | . u. u a = | n 524 227 13 openings of the body 11. The elongate body 1.1 comprises at least two slits 25 symmetrically arranged around the circumferentially arranged body of the elongate body so that a gap 25 is arranged on each side. For example, the elongate body comprises four or six gaps 25. The slats 25 are distributed around the elongate body 11 to provide a suitable angle of attack, i.e. the angle between the direction of the bypassing first medium and the respective gap 25. Alternatively, the elongate the body has several columns 25. In order to stabilize the elongate body 11, the device 10 comprises reinforcements 26 distributed in the longitudinal direction of the elongate body. Alternatively, the elongate body 11 comprises a framework or the like for stabilizing it.

Referring to Fig. 10, the elongate body 11 according to a second embodiment of the present invention is illustrated in cross section. In accordance with the second embodiment, the elongate body comprises four slots 25.

Two slots 25 are provided at one side of the elongate body 11 for generating lifting force in one direction and two slots 25 are provided at the opposite side of the elongate body 11 for generating lifting force in the opposite direction. The slots 25 are adjustable, one direction of the outflowing second medium being adjustable. Damper 27 is arranged at the respective gap 25 so that these are adjustable. otherwise the slots 25 are fixedly arranged. The dampers 27 are designed to enable the slits 25 to be closed, whereby they can be opened and closed to control the direction of the lifting force. The dampers 27 are for instance connected to the elongate body 11 via guide elements or the like, whereby the dampers can be rotated towards the slits 25 pre-closure thereof or from the slits 25 for opening thereof. In this way, the outflowing second medium can be regulated with respect to which gap it is to flow out of, whereby the direction of the lifting force is controllable with respect to the direction. In Fig. 10, a first set of slots 25 is open so that the second medium can flow out therefrom. This is illustrated by means of the arrows C. For example, the dampers 27 are connected to a conventional motor or the like for opening and closing thereof. Alternatively, the dampers 27 are designed as sliding dampers and the slits in the form of a plurality of openings arranged in the longitudinal direction of the elongate body 11, which is not shown in the figures. Such sliding dampers include p4086se0Ops; , usac sonen 10 15 20 25 30 - n v | 524 227 14, for example, a plurality of openings separated by means of strips, the gaps being openable and closable by displacing the sliding dampers.

Thus, a gap is opened when the openings of the corresponding sliding damper are arranged against the openings of the gap and is closed when the band of the sliding damper is arranged over the openings of the gap.

Referring to Fig. 11, a portion of the elongate body 11 according to a third embodiment of the present invention is illustrated in cross section. In accordance with the third embodiment, the elongate body 11 comprises at least one rotatable wall element 28. The wall element 28 is designed to enable opening and closing of the slits 25 by rotation thereof.

The wall element 28 comprises a hinge member 29, the wall element 28 being rotatable about the hinge member 29. The hinge member 29 is for instance arranged at a central portion of the wall element 28, whereby when rotating a gap 25 is opened at one end of the wall element 28 and closed at opposite ends thereof. For example, wall portions 30 arranged next to the rotatable wall element 28 comprise a portion 31 projecting in the direction of the rotatable wall element 28. Thus, when the rotatable wall element 28 is rotated, one end of the rotatable wall element 28 abuts the projecting portion 31 of an adjacent wall portion 30. , because a gap is formed at the opposite end. In Fig. 11, the rotatable wall element 28 has been rotated counterclockwise. The direction of the second medium flowing out of the formed gap 25 is shown by means of the arrow C. For example, the rotatable wall element 28 is connected to a motor or the like for rotation thereof, which is not shown in the figures.

Referring to Fig. 12, the elongate body 11 according to a third embodiment of the present invention is illustrated in cross section. In accordance with the third embodiment, the elongate body comprises four slots 25.

Two slots 25 are provided at one side of the elongate body 11 for generating lift in one direction and two slots 25 are provided at the opposite side of the elongate body 11 for generating lift in the opposite direction. A dividing wall is arranged across the channel 21, whereby the second medium can be guided towards the respective slot 25 or the respective set of slots. For example, the elongate body 11 includes a first partition wall 32 for separating the first set of gaps from the second p4086seOOps; »Arna arsa: 10 15 20 25 30 -. «. u 524 227 15 | . -. n set of columns. Thus, the channel 21 is divided into two chambers for transporting the second medium to the respective set of slots. For example, the elongate body 11 also comprises a second dividing wall 33, the flow of the second medium to the respective gap 25 being controllable. Thus, the channel 21 is divided into a first chamber 34, a second chamber 35, a third chamber 36 and a fourth chamber 37 for transporting the second medium to the respective gap 25. By alternately supplying the second medium to the respective chamber 34 37, the outflowing second medium can be regulated with respect to which gap it is to flow out of, the direction of the lifting force being adjustable with respect to direction. In Fig. 12, the second medium is supplied to the first chamber 34 and the second chamber 35 so that the second medium can flow out through the gap 25 belonging to the first chamber 34 and the gap 25 belonging to the second chamber 35. This is illustrated by means of of the arrows C.

Referring to Fig. 13, the elongate body 11 is illustrated in cross section according to a fourth embodiment of the present invention. In accordance with the fourth embodiment, the elongate body 11 comprises a plurality of rotatable slots 25, the direction of the outflowing second medium being adjustable. In this way, the second medium can be caused to flow tangentially along the outer surface 12 of the elongate body 11 both clockwise and counterclockwise to change the direction of the lifting force. In this way, adjustable gaps are provided, whereby the direction of the outflowing second medium is adjustable. In Fig. 13, the slits 25 are adjusted so that the second medium flows out clockwise around the elongate body 11, which is illustrated by means of the arrows C. The direction of the bypassing first medium is illustrated by means of the arrows E and the generated lifting force with the arrow F. The slots 25 can be designed in a number of different ways to achieve the rotatable function and thus the change of the direction of the lifting force. For example, the elongate body 11 includes rotatable plates for opening and closing the slots 25. Some examples are described below. The slots or plates are, for example, connected to a motor or the like for rotation thereof, which is not shown in the figures. Referring to Fig. 14, a portion of the elongate body 11 according to a fifth embodiment of the present invention is illustrated. in accordance with p4086se00ps; . ;; n | 10 15 20 25 30 -. . . ., 524 227 - -. 16 with the fifth embodiment, the elongate body 11 comprises rotatable plates for changing the direction of the outflowing second medium. The elongate body 11 comprises, for example, a rotatable first plate 38 and a rotatable second plate 39. The plates 38, 39 thus comprise a guide element 40, around which the plates 38, 39 are rotatable. The guide element 40 is arranged in a first end of the respective plate 38, 39, whereby a gap can be formed or opened at their second end. The plates 38, 39 are rotated to a position where the other end of the second plate 39 projects outside and past the other end of the first plate 38 when a gap 25 for outflow of the second medium in a motor direction is to be provided. Thus, a space is formed between the first plate 38 and the second plate 39. This is illustrated in the top figure in the series of figures. To change direction of the outflowing second flow, the first plate 38 is rotated clockwise and the second plate 39 counterclockwise until the other ends of the plates 38, 39 are arranged against each other. This position is illustrated by the middle figure in the figure series. Thereafter, the first plate 38 is rotated counterclockwise and the second plate 39 clockwise so that the first plate 38 is placed outside the second plate 39. The rotation continues until the second end of the first plate 38 projects outside and past the second end of the second plate 39, as illustrated. in the lowest figure in the series of figures, In this way adjustable gaps are provided, whereby the direction of the outflowing second medium is adjustable.

Referring to Fig. 15, a portion of the elongate body 11 according to a sixth embodiment of the present invention is illustrated. In accordance with the sixth embodiment, the elongate body 11 comprises a rotatable plate member 41 for changing the direction of the outflowing second medium.

The plate element 41 is arranged in a space between a first wall segment 43 and a second wall segment 44 of the elongate body 11. A length of the plate element 41 is suitably slightly longer than the space between the wall segments 43, 44, a first end portion 45 projecting past a end of the first wall segment 43 and a second end portion 46 protrudes past one end of the second wall segment 44. The plate element 41 comprises a joint 42, around which the plate element 41 is rotatable. The joint 42 is arranged in a central portion of the plate member 41, whereby a gap can be formed or opened at its end portions 45, 46. The plate member 41 is rotated to a position where the first end portion p4086se00ps; ou »u none 10 15 20 25 o I» «n v 524 227 17 ~ - ~. u 45 projects outside and past the end of the first wall segment 43 and the second end portion 46 projects inside and past the end of the second wall segment 44 when a gap 25 for outflow of the second medium in a counterclockwise direction is to be provided. Thus, a space is formed between the plate element 41 and the respective wall segments 43, 44. This is illustrated in the top figure in the figure series. To change direction of the outflowing second flow, the plate element 41 is rotated clockwise until the plate element 41 is arranged across the stretch of the wall segments 43, 44. This position is illustrated by the middle figure in the figure series. Thereafter, the plate member 41 is rotated clockwise until the first end portion 46 is placed outside and past the end of the second wall segment 44 and the second end portion 46 inside and past the end of the first wall segment 43.

This is illustrated in the bottom figure in the figure series. In this way, adjustable gaps are created, whereby the direction of the outflowing second medium is adjustable.

Referring also to Fig. 16, a portion of the elongate body 11 according to a seventh embodiment of the present invention is illustrated. In accordance with the seventh embodiment, the elongate body 11 comprises two plate elements 41 rotatably arranged in parallel by means of hinges 42 for changing the direction of the outflowing second medium. A plate element 41 is arranged on the inside of the outer wall of the elongate body 11 and a plate element 41 is arranged on the outside thereof. In this way, the two plate elements 41 are rotatable so that a gap can be formed in the respective direction. This is illustrated in the figure series in Fig. 16. p4086se00ps;

Claims (10)

fl anu: 10 15 20 25 30 524 227 18 PATENTKRAV An apparatus for generating lifting force for recovering energy from a by-flowing medium, comprising an elongate body (11) having an outer surface (12) for actuating an over-flowing first medium, a first end (13) connected to a substrate via a bearing (19) and a free second end (14), the elongate body (11) being rotatably arranged around at least a portion of the bearing (19), characterized in that the elongate body (11) comprises a plurality of slots (25) for a second medium flowing out through the slots (25), the second medium flowing out towards the outer surface (12) for influencing the first medium flowing past the outer surface (12) while generating lifting force, and that the slits (25) are adjustable, one direction of the outflowing second medium being adjustable for changing a direction of the lifting force while carrying the elongate body (11) around the bearing (19). Device according to claim 1, wherein the elongate body (11) is symmetrically designed to evenly distribute the lifting force in alternating directions. Device according to claim 2, wherein the elongate body (11) is designed in the form of a circular cylinder. The device of claim 1, wherein the slits (25) are arranged at an oblique angle to a periphery of the elongate body (11) so that the outflowing second medium is caused to flow tangentially along the outer surface (12) of the elongate body (11). ). p4086seO0ps; 10 15 20 25 30 524 227 19 ø. r Q u Device according to claim 1, wherein the elongate body (11) comprises a fan (22) and a channel (21) arranged in at least a portion of the longitudinal direction of the elongate body for transporting the second medium from the fan to the slots (25). ) and the slots (25) connecting the channel (21) and the outer surface (12) of the elongate body (11). The device of claim 1, wherein the elongate body (11) comprises a slidable or rotatable member (27, 28, 38, 39, 41) or a dividing wall (32, 33) for adjusting a direction of the outflowing second medium . A method of generating lifting force for recovering energy from a by-flowing medium, comprising an elongate body (11) having an outer surface (12) for actuating an over-flowing first medium, a first end (13) connected to a support via a bearing (19) and a free second end (14), the elongate body (11) being rotatably arranged around at least a portion of the bearing (19), comprising the steps of causing a second medium to pass through a plurality of slits (25) flow out towards the outer surface (12) of the elongate body (11) for influencing the first medium flowing past the outer surface (12) while generating lifting force, and to change direction by adjusting the slits (25) of the outflowing second medium for changing a direction of the lifting force while carrying the elongate body (11) around the bearing (19). A method according to claim 7, wherein the outflowing second medium is caused to flow tangentially along the outer surface (12) of the elongate body (11) by arranging the slits (25) at an oblique angle to a periphery of the elongate body (11). . p4086se00ps; : rann vounø 10 524 227 20 - - -. n A method according to claim 7, wherein the second medium is caused to flow in a channel (21) arranged in at least a portion of the longitudinal direction of the elongate body (11) by means of a fan (22). A method according to claim 7, wherein a direction of the outflowing second medium is changed by means of a displaceable or rotatable member (27, 28, 38, 39, 41) or a dividing wall (32, 33). p4086seO0ps;