DE102007002245A1 - Method for conversion transmission of power of flowing gas or fluid medium, involves guiding rotary power of flowing medium in rotating tower or in turbo machine housing by simultaneous impact of two impeller wall element devices - Google Patents

Abstract

The method involves guiding a rotary power of a flowing medium in a rotating tower or on a rotary axis (7) or in a turbo-machine housing by simultaneous impact of two impeller wall element devices or in a rotating device (1) or a turbo-machine rotating device by impact of an impeller wall element (148) on an impeller wall element device (2). The rotary power is guided in a rotary manner with a medium flowing direction on one side, where the impeller wall element is guided by a flow rotation on another side. An independent claim is also included for a device for conversion-transmission of power of a flowing gas or a fluid medium.

Description

method and apparatus for carrying out the Method of conversion / transmission the power of a pouring gaseous or liquid Medium "z. As air, compressed gas, steam, water, etc. "in axis rotations / rotational movements of a Rotation device over z. B. acted upon by wind and / or water flow wing wall element devices in this or in a turbomachine with pressure passage from a flowing-flowing medium with application of wing wall elements in these and devices for process versions in different variants u. a. with accessories known type.

method and devices for carrying out Rotary movements with energy delivery via this and with energy supply via a flowing-flowing medium on / passing device. This is done power transmission with implementation for Axis rotation / rotation over Actuation of on the one hand with the medium flow and on the other hand against the medium flow Rotating Winged Wing Element Devices. About these Axis rotation is transmitted rotational force with "lifted Efficiency ", at simultaneous power transmission of at least one with the medium flow direction rotating acted upon and at least one acting against the medium flow direction acted upon Wing wall element. It is thus wind and / or water currents in labor-useful energy translating rotary devices of the like with water pressure or Compressed gas driven turbomachine devices, in many variants more economical and thus many Place on land and on water, use.

The The invention relates to a method and apparatus for carrying out the Method according to the preamble of claim 1.

Known Procedure is that a medium flow through obliquely Slats or wings, which is arranged around an axis in / on a wind, compressed gas or water flow in rotational force conversion device, which with flowing through the Medium through the lamellar or wing assembly, of this one Tilting part surface acted upon and there with wing turns the transverse to the medium flow takes place or on the one hand with the medium flow in the direction of flow rotating wing wall with a plate or gutter recess in this opens, while pushing force on this exerts which transmit to the axis rotation becomes. At the same time takes place against the seated on the axis opposite Wing-wall elements which against the medium flow to be led, although this page has a streamlined surface, Braking force effect which does not act positively to the axis rotation. As a result, only the difference of with and against the medium flow rotating Surfaces over axis rotation / rotation to Outside as Kraftabgabe done with power conversion connections and Control processes with known proven technique as preprogrammed, derived used becomes.

disadvantage These known inventions are that of medium flows such versatile in nature in the form of wind and water currents the medium flows very restrictive used or only with low efficiency and thus many place can not be used with economic benefits and the efficiency and economic efficiency of turbomachinery with line connection to a pressure accumulator or generator device only at high and constant flow pressure of primarily with energy feed brought to an elevated energy level medium, an economic Efficiency and benefits can be achieved.

task It is the object of the invention to provide methods and devices for process execution to create natural medium flows, such as air heat buoyancy as well as wind and water movements in and around the sea and larger water surfaces as well rivers or the like, are economical to use. flow force in electrical energy and / or in compressed gas / compressed air or other medium flow to Energy use for Implement device drive differently. The use of and with primary power supply Successful pressure increase to conduction-medium flows over turbomachinery devices, at also fluctuating and low pressure, economical for different work processes to be able to use.

task is achieved by the method and the features of claim 1 and for carrying out the method with the mentioned devices, solved.

advantages the invention are that the different medium flows as predetermined by nature in the most diverse places, as well as primarily generated Pressure specifications with different pressure levels in and with flowing medium in lines, with high efficiency working with and over a flow machine in and with known switching devices, etc. methods and devices for special tasks, to disposal are to be made.

versions are shown in the drawings and will be described in more detail below.

1 shows in a schematic representation and vertical section a to be acted upon by flowing medium water or wind rotary device with power transmission connection from an axis at this offset two sides connected wing-wall element devices and the axis on a fork with stand-column bottom mounting and on this column Slewing ring with servomotor, is.

2 shows in a schematic representation in cross section four offset about an axis wing wall element devices a small wall element with weight insert and large wing wall elements each having a rotating rods or Drehangel, as well as attached to this and / or in the wall element and / or the connection bracket to this to have. Around each wing panel is a support frame of the connection to the support frame construction which has all-around retaining ring connection and axle connection, wherein pull are pressure buffering devices on these and the support frame. "The frame connecting ring is shown in dashed lines".

3 shows a schematic representation of a modification of how to 2 shown rotary device wherein the four wall element devices are shown in the rotation course each with two wing wall elements in a larger angle inclined position to the support frame.

4 shows a schematic representation in vertical section a modification of the Rota tion device as to 1 however, shown standing in the water with a plurality of wing-wall element devices wherein each Drehangel-Achsen-Verbindungsrahmen 2 Piece each having successively offset offset wing-wall element devices. The rotary device with rotary axis in ball bearings stands on columns. "This is indicated by a water level".

5 shows in a schematic representation and in vertical section "a modification of the rotary device as to 4 "Several devices have axle connections with each other and are carried on columns in and on a float device tube assembly, anchored vertically in the water." The float device consists of longitudinally and transversely spaced tubes connected with conduit connections from these to compressed air pumps and compressed air Storage chambers in the pipe assembly and other indicated Vorrich lines that are on / in under the tube-float composition.

6 shows a schematic representation and cross-section of a modification of the rotary device as to 2 shown with mounted around an axis wing wall element device in a pipe / shaft with one-sided axis-outward and a ball bearing in the ground, wherein the wall elements in and with the frame at minimum distance on the ground and outside wall sides held and to the two Exterior Pipe Wall Sides Rounded wall inserts are larger in diameter and in front of and behind these in the Medium Guide Pipe Bay.

7 shows a schematic representation and cross section of a modification of 6 wherein in the medium flow tube guide in front of a wing-Wandelemt-device facing a flow restriction insert and a wing-wall element device in the rotation cycle "like 2 shown "has an angular degree shifts.

8th shows a schematic representation and in horizontal cross-section of a rotary device with turbomachine housing and (in a modification to 7 ) With a supply line connection and a further line connection and the housing a heat transfer flow-through jacket with inlet and outlet guides, also is about two wing Wandele devices from the rotary rod bearing bushes to the axis out the smaller part the wing wall elements protruding with a projection into a recess of an axle casing and folding trays with leaf spring holder and that of two wing wall element devices the rotary carrier bearing bushes to the axis of the larger part of the wing wall elements is. Shown to the housing side surfaces are compression spring connections and tension-telescoping spring devices in / on the axle shroud and / or the brackets outer Umspann-Band-inside.

9 shows in schematic representation and vertical section of a rotary device "flow machine as to 8th however, one side is shown only in an apposition. "To the wing-wall element devices is a minimum distance between the pivot-rod-frame-support frame" attached to the axle "from the frame inside and the wing wall element outside, likewise between the frame outside and the inside of the turbomachine housing (as 8th shown in cross-section).

10 shows in a schematic representation and in vertical section a rotary device with a vertical axis on a float pivot bearing guide 57 the sheath of which on / in a float tube device 21 . 22 held and on the vertically mounted axis is a turret structure. Also indicated white Other rotation devices 56 in / on a lower and upper float device pipe composition 21 . 22 this pipe rod connection and anchors, and "recognizable in the scheme", various devices in / on the upper float-tube assembly 22 attached.

11 shows in schematic and in vertical section a turret rotation device with side-shifted wing-wall element devices 115 . 116 . 131 on an axle device of rods with shrouds, wherein the rotary turret with axle device on a round large surface float device 87 is attached in a water-carrying jacket 88 is stored. A canopy 108 has and power transmission connections from the axle device to the floating body surface area and / or on the canopy upstanding power conversion devices.

12 Fig. 12 schematically shows a cross-section through the lower rotator turret base and / or an intermediate floor therein as well as the outer edge of a water collecting surface below the turret base, wherein in the turret base are air flow through openings with air buoyancy spiral surfaces. In addition, laterally in the turret-axis composition flow openings and in the middle of the axis air buoyancy spiral surfaces and in the rotary turret several wing-wall element devices.

13 shows in schematic representation and in vertical section a rotation turret construction with approach of the pillar axis and in the turret side and height offset wing-wall element devices also in the turret (in a modification to 12 ) the air buoyancy spiral surfaces. In addition, an intermediate floor and indicated a canopy.

14 shows in a schematic representation and in vertical section the approach of a rotary turret with vertical axes on / in a float pivot bearing guide in a modification to 10 and 11 in a float construction tube composition 22 is anchored and underneath the turret an all-round "up and down to surface area reduction" surface overvoltage 60 which are fastened to the tube-float assembly by means of support rods in swivel-axis holders and the surface-tension support rods have ropes or chain-mounted weights with buoyancy devices.

15 shows in schematic representation and in horizontal position plan view of an upper tube-float composition 21 . 22 with on this (in modification to 5 without uprights) fixed rotary devices with wing-wall element devices which are connected to each other over the axis and the upper float device is connected to a lower tube-float composition kept at a distance in slope position.

16 shows in diagrammatic and vertical section a top and bottom tube float composition inclined at / below a water surface. Below the lower float device, a mesh fabric and / or perforated plate surface is attached (shown in phantom). With the rotation device (s) in the upper float tube assembly is coupled a flywheel device power transmission connection.

17 shows in schematic representation and vertical section in the approach an axis and to this a frame-carrier construction with in this (offset to the axis sides) two "vertical right side view" in pivot bearing held Flügel-Wandelemet devices.

18 shows in schematic and horizontal section a rotary device frame support structure with four wing-wall element devices thereof two shown only in the approach, wherein the wing-wall element devices in a modification to 17 and 3 , under the larger and / or on the smaller wall element have a wheel roller with wheel-bearing surface and each of the wing wall elements to / from the axis side of a rod and / or a movable latch gripping lever to a leaf-spring-train pressure Device and the ro tations device outside have a lever arm articulation with a push-pull spring as a rotational directional force conversion device. About this is a roof "hatched / hatched".

Device and general description

A rotary device consists of an axle with axis carrier and force-transmitting device and a plurality of at least two offset to the axis fixed frame with this movably arranged and supported wing-wall element devices with at least one wing-wall element device in the cycle with and one is urged against the medium flow direction thereof, whether rotating with or against the flow, transmitted from each of the wing wall element device, force from the medium flow to the axis rotation. This is described in more detail in the function and detailed description. With this function, the wing-wall element device for converting the force of a flowing-flowing medium in axis rotation with one of the rotary device variants, in particular for wind and air pressure and hydropower over the ground or in and over a water surface are the device Variants also for the use of low tide and high tide as well as other water flow in any conceivable order of magnitude with horizontal or vertical axle bearing running implemented.

Out 1 it can be seen that a rotation device 1 "Use of wind or water flow force" wing wall element devices 2 . 3 . 4 . 5 With outside all around this has several connection frame bands or rings 6 , The device frame connections are on one axis 7 which in ball bearings 8th . 9 in the two fork arms 10 . 11 rest with the storage fork fixed on a pedestal 12 with swiveling upright bearing 13 and the rotary device for broadside alignment with the wind flow (in the case of relatively small devices) is a vane that rotates in the direction of flow 14 and in larger devices, a directional servomotor 15 Has. To the rotational force conversion are from the axis 7 for driving generator 30 or pumps 31 Devices, either as a direct or indirect connection 17 "Z. B. V-belt or the like ".

Out 4 can be seen that a horizontal axis rotation in a modification of the rotary device as to 1 called, this on pillar 18 . 19 mounted in ball bearing device, wherein the columns can be mounted in a composite standing on a rotatable surface. The wing wall element device 150 . 151 . 152 . 153 (in the device 3 and 4 ) dual devices are "like to 3 "Rotation devices are to be aligned to changing medium flow directions have attachment z., B. on a round float before direction 84 "how to 11 shown "or a tube float composition 22 . 23 ,

How out 5 can be seen, are several rotary devices with horizontal axis storage on a float device 22 . 23 which consists of tubes where these in the composite in several layers 23 . 24 connected with spacer mounts connected and partly as a compressed air reservoir 25 . 26 and partly as the chamber to be flooded the tubes of the float devices are divided under. These preferably have compressed air controlled valve flaps 91 the over line connections 28 together and to compressed air pumps and switching and control systems and other devices 29 . 30 . 31 . 32 Among other things, to buoyancy devices of floating body anchoring and other line network 33 Line terminal connections 37 . 38 . 39 are. Out 10 it can be seen that, in contrast to 5 an upper and a lower tube-float device 21 . 22 with rotating device shown in the approach 40 . 41 . 42 each a vertically mounted rotation axis 56 to have. The floating body devices 21 . 22 are over vertical pipes 44 . 45 and / or anchoring rope / chain connection 46 . 47 "Moveable and connected" in and on the floater devices 22 are different devices z. B. chain winch 48 , Generator 49 , Compressed air pump 50 , Turbomachine 51 , ( 8th . 9 ) to the compressed air in power conversion and high-pressure air storage 52 and in outline other devices 53 z. B. to implement with electric energy use water in hydrogen. The vertical axis 56 the device is equipped with a floating pivot bearing device 57 connected with the mobile stand attachment 54 is held. The axis is in the further on a ball 55 stored in the floating body device upright. For the float device are cavity chambers for weight relief 58 assigned. The axis 56 with floating body 57 has a sheath 96 with water filling up to a predetermined height distance below the turret bottom.

Out 11 it can be seen that, in contrast to 10 a turret rotation device 59 a vertical axis 7 the pipes 83 and / or carrier 84 created and several height-shifted surrounding tape strips 85 and within this axle construction on the support tubes 83 . 84 meandering air-lift wing device 86 has fixed and the vertical axis on a round large surface float device 87 . 88 is mounted upright. In the float are offset in a circle tubes as a compressed air storage tank 89 . 90 with cable connection 91 . 92 to the outside and with switching device 93 and connection to compressed air pump 94 and / or generator, and a turbomachine 95 ( 8th and 9 ) Has connection. The turbomachine ( 8th . 9 ) is mounted on / in the float device and has a wheel-roll transmission push-pull connection for power transmission 97 to the buoyant shroud device 88 . 96 , Stand of the generator is outside the float surface with wheel roll force transmission Andrückverbindung on this. The float jacket has water pipe connection 39 and round offset ball holder 98 . 99 at least one touch-up ball at the top edge and around the bottom 100 with holder turntables and above the float surface 101 Mounting on these vertical axes 102 and on / to this all around a roll-wheel-Lauflager 103 , about the a power transmission connection shafts with wheel-roller device with connection to the generator 30 and pump device 105 In order to force transmission to the devices on the all around swimming pool canopy 108 , standing up be strengthened. The roofing 108 is on the casing edge 104 attached and held aligned with the axis at a distance.

Out 12 It can be seen that a rotary turret ( 11 and 13 ) in the ground 117 Air-flow openings 110 with spiral surfaces inserts 111 has, as well as a turret carrier construction of carrier tubes 112 with wing wall element frame beam connection 113 to the axle and the outside all around ring bands 114 , In these compounds are several wall element devices 114 . 115 . 116 Assigned pages and heights offset. In addition, it can be seen that outwardly above, under the bottom edge, a surface 118 with support tubes 119 . 120 . 121 with ball pads 122 . 123 are "like among others 13 and 11 recognizable "on / on the surface 118 are water supply and discharge connection lines 124 . 125 ,

Out 13 it can be seen that a rotary turret 59 "With relatively large diameter and height" from the ground area 117 . 111 and in or between the turret support structure 112 (in modification to 11 ) at least one air-upwind spiral guide 120 has and under the bottom surface 117 the water catchment area 118 is held by this held at a distance to the ground is a column axis with piping in this. The vertical axis 7 consists of tubes connected as a tube bundle outside ring reinforcements 114 has the heights are offset. In the vertical tubes likewise in the other support structure 112 are compressed air and water pipes with line connection 127 . 128 . 129 to the upper floor surface 138 and the support frames of the wing wall elements and the "compressed air controlled" fixing devices 130 , to this. The wing wall element devices 131 . 132 . 133 . 134 . 135 . 136 . 115 . 116 are heights and sides offset and partially arranged in an inclined position in the turret. In the revolving tower floor and intermediate floor 138 are cavities for hot or cold air flow with wiring connection 127 - 129 to this. The respective upper floor surfaces have water drainage connections 137 and the air flow openings 110 above the ground surface, a ridge elevation above the ground and to / in the flow openings are Luftauftriebsleitflächen 111 used. Around the tower-outer support construction are all around heights staggered reinforcing bands 114 with inner and outer wall surfaces. Between the lower water collecting area 118 or tub surface and the axle sub-area 138 over this are force-conversion devices z. B. generator 139 with control switching device 140 and compressed air generator 141 as well as battery and compressed air buffer used, which are carried along by transferring force in axis rotation. The vertical axle bearings with turret rotation guide 59 is like when standing on land in the country 11 shown on a large surface float device 87 which is kept used in the ground, appropriate. For stand areas of a turret in and on a larger area of water z. As sea or the like is the vertical axis guide with and in a floating body device 57 appropriate to that in a body-pipe composition 22 , is classified (composition as to 10 . 14 shown) or as one of the other variants, which are carried in the water and partially anchored anchored in the ground.

Out 14 it can be seen that in contrast to the rotation device 10 the rotation device 42 "Only recognizable in the beginning" a rotary turret device 59 z. For example 11 is and under this all around a multi-part 60 . 61 up and down-hinged canopy over the water surface with a predetermined area size in and above the float 22 Pipe composition is, with the roofing on several joint fasteners 63 . 64 movably held support rods have on or on the / the surface partitions 60 are fixed and this roof completely or partially made of tissue films or z. B. Solar collector surfaces 65 has to the south side. Part-area fasteners are each between at least two joint-carrier cross-connections 67 . 68 the two support rods 61 connects, these have on the side of the turret towards a greater distance 69 and on the other hand a smaller distance 70 from / to the joint fixings 63 . 64 out. To each of the overlapped all around or with minimum gap spacing held partial surface areas are, at least two to be flooded weight containers 71 . 72 or with fasteners 63 . 64 connected. The vessels to be flooded have water inlet valve flaps 91 with compressed air connection connections. From the weight containers 71 . 72 are rope / chains or bar connections 61 to / on the support bar / surfaces. The solar surface areas have line connection 73 . 74 to a heat storage device 75 , The pipe cross points of the Pipe Float Assortment have connection devices 76 ,

Out 15 and 16 it can be seen that, in contrast to 5 Rotary apparatus 1 the horizontal axes 7 in the ball bearing 8th . 9 have passed with connection device 76 on / on an upper buoy tube composition 22 are attached and in conjunction with this a lower float 43 composition in an angle to the upper float 22 is. Under the lower tube float are connecting cross tubes 77 . 78 or connecting beams and between the connecting beam pipe bearings 78 and the float tubes 43 "In side view 16 "are preferably tissue 81 and / or perforated plate strips attached. The rotary devices have a power transmission connection 17 with a flywheel device 82 and from and to a power transmission connection to at least one device 16 z. B. generator and / or pump.

From the 2 . 3 . 6 . 7 . 8th . 9 . 17 . 18 . 19 and descriptions, it can be seen that the wing-wall element movements in rotation devices or turbomachinery housing are planned with and against the flow direction rotating in different variants. Accordingly, the most varied plant sizes, as a smaller and individual device as well as large individual plants and device combinations, can be designed. This allows, inter alia, that in the country depending on the stand wind power and Wärmeauftriebs- with water cooling cycle heat also solar and environmental heat can be used and / or on and in the water to use a water flow. With the buoyant-tube composition are formed between these water-free surfaces. It can be created floating large areas, while water surface smoothing order can be made. Flow-utilizing rotary devices with required accessories should be assigned. With these not only energy production, but also water extraction from salt water is possible. With flooding of chambers in the tube and float assemblies, these may be lowered below the water surface, if required by weather conditions, and later buoyed with compressed air as needed. With buoyant tube composition and apparatus, water currents are to be utilized not only in near-shore water waves and low tides, but also at edges of large-scale float tube compositions. Floating anchored large areas lying far away from the mainland, generate electrical energy and condensed water. Plants for hydrogen production are assigned appropriately.

Device and functional description

Out 2 it can be seen that to the rotation device 1 with the axis 7 connected the wing wall element frame support 113 are and at this per wing wall element device 2 . 3 . 4 . 5 at least one electrically controlled wall-fixing device 130 or a pneumatically controlled locking device 144 is, as well as a rotary device holder in pivot bearing 152 and a wing wall reinforcement 149 from / to one side of the pivot bearings 152 is and a wing wall element bracket 147 or a pipe with a weight insert and on the other side a "larger" wing wall element 148 is, with respect to this, at least one pressing-buffer device 156 and to the wing wall element bracket 147 towards, a directional conversion device 139 z. B. push-pull spring device 158 is.

How it works: z. For example, in the case of axis rotation direction "arrow 145 "and medium flow direction" arrow 146 "it can be seen that of the medium flow, the wing-wall element 148 z. B. the wing-wall element device 4 with the flow against the pressure-buffer device 156 pressed and thus pressure force converted to the axis rotation and at the same time from the medium flow, the wing-wall element 148 "Of the device 2 "with against the flow guided by the buffer device 156 abutting and turning the wing wall element tube weight 147 against the compression spring device 158 presses on this as a directional conversion device 139 In this case, "force converted to the axis rotation is guided impulsively in each case in the rotation cycle", for example as in wing wall element devices 3 . 5 shown "a balancing print buffer 156 and push-pull spring 158 Position in the rotation cycle arises. When switching to throttling or standstill-braking the rotation device this is done with the fixing devices 144 which fixes the wing wall elements, so the rotation of these with force implementation via device 139 not done anymore.

Out 3 it can be seen that a rotation device 16 with the axis 7 a connected support structure with wing wall element 132 . 133 . 134 and outside all-round connection band ring 6 Has. In modification to the device 1 the wing wall elements are dual devices 150 and to this per page a force-conversion device 139 one on the axle side 7 and a connecting band ring side 6 and over each of these side sections a canopy 161 is. The wing wall elements 148 . 162 have a hedging cable connection 163 and to a head side of the wing wall elements 162 a sliding-roller-wheel connection 164 , To every two-way device 150 is one of the force conversion device 139 of which expedient one as a device with toothed rack and rocker arm 155 and a pull-spring device 158 , Function is like too 2 called, in addition to the modification on the one hand on the double-wing wall element device 150 guided with the flow with press this against several Andrück-Puffervorrichtun gene 156 about this axis rotary motion force and on the other hand against the flow guided with prints from the buffer devices 156 Force over the directional conversion devices 139 , is transmitted to the axis rotation. With a train-spring device on the one hand force implementation and on the other hand assistance in the wing-wall element feedback in the cycle takes place.

Out 6 It can be seen that a rotation device in a modification to 1 and 2 in a through a pipe or a gutter / shaft 170 directed water flow inserted into a housing 168 which has a smooth bottom side and two rounded side surfaces 165 and a water inlet and outlet 166 . 167 has, is.

How it works is how to 2 shown and described.

Out 7 is in a modification like too 6 shown in that / in front of the inflow opening 166 Rounded surface is the one pipe constriction / flow control surface 169 has, this receives the case 168 two smooth surfaces in which the axle bearing is inserted and guided on at least one side to the outside.

How it works is how to 2 shown and described.

Out 8th and 9 it can be seen that a rotation device 51 "Is the gaseous medium flow in force conversion, preferably for elevated pressure" (in a modification to 7 ) in a closed "turbomachine" housing with inflow conduit connection 171 and outflow line connection 172 is "at 9 shown only with device interruption approach. "In the housing are wing wall element devices 2 . 3 . 4 . 5 in pivot bushings 151 which in modification too 2 . 3 . 6 to the housing wall inside 173 as well as to the inside ground side 174 and housing top 175 a closed surface at / below / on the device pivot support frame 176 have that on the axle 7 is attached. There is a minimal gap between the closed carrier frame sides and the case insides 177 and to the axis in this wing-wall element side view, with aligning the small side to the axis, with leaf spring hinges 178 attached flaps 179 is. Around the turbomachine housing is a closed chamber / jacket or tortuous tubes 180 to cable connections 181 . 182 , Passed through the housing wall is a water or steam line connection with valve 183 ,

Function: with flow of pressurized gas / compressed air is the impingement with movements of the wing-wall element devices 2 . 3 . 4 . 5 in turbomachinery housing takes place with Be aufschlagung the wing wall elements, in this power conversion and forwarding as to 2 or 3 called. With compressed air flow through the turbomachine 168 and the compressed air relaxation is withdrawn heat, this is preferably heated by heat transfer medium, preferably water and / or water vapor the housing and according to program specification, a proportion of hot water and / or steam via line connection 183 into the flow machine device 51 "Also supplied as a lubricant" and with the "with pressure reduction" forwarded compressed air, derived.

Out 17 is shown "in approach" to infer that a rotation device is a support construction 59 . 112 . 113 . 114 (eg how to 11 shown), in which the wing-wall element devices 115 . 116 levitating with rotary hanger carrier 151 in ball bearing bushes 152 are held. In / on the carrier construction are locating devices 130 and telescopic pressure pad spring devices with compressed air line connection.

Out 18 It can be seen that a rotation device (eg 11 shown) a plurality of wing-wall element devices 115 . 116 . 131 . 132 has, being in modification to 3 the device 132 . 133 . 134 . 135 each wing wall element 115 . 116 a connection with a rotary lever arm 153 with directional transfer pull-spring device 154 and each wing wall element 162 when used in a water flow, a cavity 184 in this case with horizontal axis guidance and levitating insert and vertical axis guide, a roll-wheel device 185 on the wing wall element outer head end with supporting support surface 186 under this, has.

Function: Rotation device insert in air-wind or a water flow as to 2 and 3 called.

1

Rotary device

2

Wing wall element device

3

Wing wall element device

4

Wing wall element device

5

Wing wall element

6

all around Connecting band and / or ring

7

axis

8th

ball-bearing

9

ball-bearing

10

fork arm

11

fork arm

12

pedestal

13

camp

14

Wind flow Alignment wings

15

Direction servomotor

16

Rotary device

17

connection

18

pillar

19

pillar

20

attachment

21

Float device

22

Float device

23

tube composite in several layers

24

tube composite in several situations

25

Compressed air reservoir

26

Compressed air reservoir

27

Pipe chamber division

28

line connection

29

Up down Lifting control systems and other devices

30

generator or similar

31

Pressure Pump or other device

32

switching and control systems and other devices

33

line assembly

34

line assembly

35

line assembly

36

line assembly

37

Line terminal connection

38

Line terminal connection

39

Line terminal connection

40

Rotary device

41

Rotary device

42

Rotary device

43

Float device

44

Tube and / or anchoring rope / chain connection

45

Tube and / or anchoring rope / chain connection

46

Tube and / or anchoring rope / chain connection

47

Tube and / or anchoring rope / chain connection

48

various Devices z. B. winch

49

generator

50

Compressed air pump

51

Flow machine / rotary apparatus

52

High-pressure air accumulator

53

other Devices z. For example Hydrogen generation

54

portable stand mounting

55

Bullet

56

Rotary axis stored vertically

57

Floating body rotary bearing device

58

air chambers

59

Rotary turret device

60

multipart up and down folding roofing

61

support rods

62

support rods

63

joint attachments

64

joint attachments

65

solar collector

66

Up-down-cutting angle degrees

67

Beam cross-connection

68

Beam cross-connection

69

distance

70

distance

71

weight container

72

weight container

73

line connection

74

line connection

75

Heat storage device

76

Connection device / tube intersections

77

Connection cross tubes or connecting carrier

78

Connection cross tubes or connecting carrier

79

Water filling and Compressed air chamber

80

Water filling and Compressed air chamber

81

Tissue rods and plane

82

Inertias device

83

Tube

84

carrier

85

Embracing Hoop strips

86

Air-lift wing device

87

Large Area Float Device Sheathing

88

Large surface float device

89

Compressed air storage tank

90

Compressed air storage tank

91

Compressed air line connection to Valve Flap Devices

92

line connection

93

Switching device

94

Compressed air pump

95

flow machine

96

Float-cladding device

97

Wheel roller-power transmission Andrückverbindung

98

ball retainer

99

ball retainer

100

Planted ball

101

float surface

102

Vertical axis mounting

103

Roll-Wheel bearings

104

sheathing edge

105

-Pump apparatus

106

Power transmission link shafts

107

Force-transmitting connection

108

float roofing

109

Floating body jacket

110

Air-flow openings

 111

Spiral surface inserts

112

Support pipes

113

Wing wall element-mount carrier compound

114

Ring bands

115

Wing wall member devices

116

Wing wall member devices

117

Rotary turret with a relatively large diameter in the ground area

118

Wasseruffangfläche or well area

119

support tubes

120

support tubes

121

Air solar chimney spiral guide

122

ball support

123

ball support

124

Water feeding and drain connection lines

125

Water feeding and drain connection lines

126

Compressed air outlet opening

127

compressed air and water pipes with line connection

128

compressed air and water pipes with line connection

129

compressed air and water pipes with line connection

130

Immobilizing device

131

Wing wall element device

132

Wing wall element device

133

Wing wall element device

134

Wing wall element device

135

Wing wall element device

136

Wing wall element device

137

Drainage connection

138

turret and intermediate floor

139

Power conversion device

140

Control switching apparatus

141

Air compressor

142

Compressed air buffer

143

battery

144

Locking device "pneumatic-electric controlled "

145

Axis rotating direction Note Pfelil

146

The direction of flow-Note arrow

147

Wing wall element, Strap or Allowance, tube with filling

148

Wing wall element

149

Rotary bearing wing wall Versträrkung / Ironing

150

Wing change element dual-device

151

Rotary Fishing Camp rifles carrier

152

rotary Angel or rotary rod in ball bearing bushes

153

Rotary-arm joint

154

Pressure-train-spring device with guided in ball bearings Train holding connection

155

Direction conversion means / leaf spring press-on buffer

156

Pressure-applying buffer device

157

Pressure-applying buffer device

158

Directional relaying train spring device

159

Leaf spring train and pressure device

160

Rocker arm means

161

canopy

162

Wing wall element

163

Protection / cable connection

164

Sliding roll- or bike connection

165

rounded side surface

166

Water inflow

167

Water outflow

168

Housing one Rotary device

169

Pipe constriction / flow guide

170

round or rectangle pipe or gutter shaft

171

Zuström-line connection

172

Outflow line connection

173

Housing inner-wall side

174

Housing inner floor area

175

Housing inner-top

176

Vehicle frame / wing wall element carrier

177

minimal distance

178

Leaf spring / hinge

179

fold with one-sided vertically aligned needle roller bearing strips

180

Heat transfer medium flow chamber / jacket or meandering Tube

181

Zuström-line connection

182

Outflow line connection

183

line connection with valve

184

cavity for buoyancy

185

Roll / wheel

186

Pad Roll-supporting surface

187

Pneumatic larder

188

to Flooding chamber area

189

to Flooding chamber area

190

air Inlet and outlet valve with cable connection

191

water In and outflow flap valve

Claims (26)

Method for converting transmission of force from a flowing gaseous or liquid medium "e.g. As in Achsendrehungen by flow movement in device rotational movements in / via at least one rotary device or turbomachine via medium flow in / through these guided wing devices applied in axis rotational movements implemented the flowing medium in Flow direction of lamellae or wind vane surfaces, with predetermined oblique position of this, along flows while power from them to a ball bearing guided horizontally mounted or vertically guided axis of rotation or by applying wing wall surfaces from medium flow the force to an Ach se in / on a turret, with wind and / or heat buoyancy use, the wing surfaces and spiral surfaces in the applied in the cycle with the areas acted upon from the flow direction, a force component in axial rotations converted with power transmission connection for driving one or more devices such as Pu mpe or generator used, the turret or roller rotation device with horizon taler or vertical axis of rotation of the ground or seabed out at a distance or from a water surface kept rotated in the medium flow or inserted under a water surface in a water flow in pivot bearing guide with a portion of the flow wall elements moves while a part of the force for wall element movement held against the flow and / or exposed via the ground or water surfaces with air flow surfaces exposed to the rotation impingement against the flow direction a decelerating action and on the acted wing surfaces which moved with the medium flow moves power conversion to the axis rotation transmit the Difference between the one hand working effective impingement with the flow guided and the low power transmission or decelerating flow action on the other hand, led against the flow a flow-vane force component in Achsendrehbeweg Unimplemented and flow force when applied with the use of wall surfaces in grooves or plate-well depression an elevated flow-force effect and with action in the wall surface rotation curve against the flow with strömungsschnittige back lower braking force effect only a proportion of the flow force on this implemented as a force difference in rotational force Similarly, in flow power transmission via obliquely acted upon wing wall surfaces in flow machine / turbine for axis rotation of the recovered power from transmitted medium with pressure and lines medium transmitted via device rotational force in electrical energy or compressed air / compressed gas and / or water pressure energy is passed to the outside. Characterized in that on or in a rotary device ( 1 ) ( 16 ) ( 40 ) ( 41 ) ( 42 ) ( 59 ) ( 117 ) or turbomachine rotation device ( 51 . 95 ) in wing wall elements ( 115 ) ( 116 ) ( 148 ) ( 150 ) ( 152 ) Loading the wing wall element devices ( 2 ) ( 3 ) ( 4 ) ( 5 ) ( 115 ) ( 116 ) ( 131 ) ( 132 ) ( 133 ) ( 134 ) ( 135 ) ( 136 ) Rotation power transmission from flowing-flowing medium while applying at least two wing-Wandelemt device in a turret ( 59 ) ( 117 ) or on a rotation axis ( 7 ) ( 56 ) or in a turbomachine housing ( 95 ) ( 168 ), on the one hand the rotationally guided with the medium flow direction and on the other hand against the flow rotationally guided wing wall elements, in the rotation cycle by a few degrees times right times left on a rotating device rod or in / on pivot bearing ( 151 ) ( 152 ) with the application of the medium flow turned against a pressure pad and / or train-suspension device ( 156 ) ( 157 ) pressed or abdrückend moves thereby in each case in the cycle of at least one of the wing wall elements in the direction of flow with the medium flow guided acted upon larger wall surface against Abfeder buffer ( 156 ) ( 157 ) on or in the wall element attachment or axle connection holder ( 84 ) ( 113 ) ( 176 ) while transmitting force in the direction of rotation axis rotation and at the same time the larger area of at least one against the flow direction of the medium flow rotationally acted upon with the flow applied wing wall element on the rotary device rod or pivot bearing ( 151 ) ( 152 ) by a few degrees the hung moves with in the flow direction of the spring-buffer this relaxing pressed thereby by the larger area ( 148 ) with the application of movement of this via the rotary device ( 151 ) ( 152 ) reacted via the Andrück buffer ( 156 ) in thrust and / or traction and over the small surface part ( 147 ) or overhang / frame and / or weight compensation allowance and / or of a wing wall element ( 115 . 116 ) via a rotating bracket device held in a rotary bearing ( 153 ), a force conversion takes place against the flow direction, these force transfer device buffers ( 139 ) and / or tension-spring connection ( 154 ) ( 158 ) transmitted thereby against the medium flow direction acting forward force transferred to the rotation device rotation direction toward the axis of the rotation device transmitted and transmitted via the axis and force transmission connection ( 17 ) Rotational force on the one hand by the against the medium flow direction and on the other hand with the medium flow direction moved acted wing-wall element devices for axial rotation transmitted is used. A method according to claim 1, characterized in that during power transmission from the flow of flowing in large masses / flowing medium z. B. ebb and flow or other medium flow z. B. Wind by applying a double wing wall element device ( 150 ) in the device rotation cycle upon rotation of the wing wall elements (FIG. 148 ) Surfaces against the flow direction or the medium flow of the / the larger wall surface parts ( 148 ) ( 162 ) of the spring buffering ( 156 ) abrückend and with over the on the rotary rod pivot bearing ( 151 ) with rotated small areas ( 147 ) Force conversion via the devices ( 133 ) ( 139 ) takes place and the acted upon by the flow in the direction of flow moving surfaces ( 148 ) of this rotation at the same time the dress nere Wandfläche- or rotating rod bracket projecting part in the direction against the medium flow rotating pressure-tension spring device ( 158 ) transmitted a portion of force and fed back over a unidirectional in one direction in a cross-tilting lever device ( 139 ) supplied guided in the rotation cycle through the respective gap opening passed from the against the medium flow direction / derived and a proportion of the medium flow over with the Flow applied device ( 150 ) In the flow / flow direction pressed by this with pressure on buffer-spring stop and transmitted with the axis rotation, a portion of the medium flow circulated in the direction of flow further conveyed, wherein in the rotation cycle, the wing wall element surface on the rotary rod at a distance ( 69 . 70 ) held by the upper and lower espagnolette rifle in / to the carrier ram and a weight-mass supplement to the smaller wall surface part ( 139 ) a load balance between the larger wall surface portion and the smaller to the smaller surface part takes place or when passing liquid medium by buoyancy force action at least one cavity ( 184 ) in the larger area ( 148 ), is compensated. A method according to claim 1, characterized in that during power transmission from air pressure or liquid and other guided by line and flowing fast or with elevated pressure medium flowing the wing wall elements in the turbomachine device rotation cycle upon rotation of the wing-wall element device against the medium flow the greater of the rotary rod pivot bearing projecting wall surface portion subjected to the medium flow and the weight allowance spanning movable side surfaces of this covers the smaller wing wall surface wherein with the flow direction with the predetermined angular degree rotation of the wing wall elements, the area ratio ( 135 ) from the pressure-buffer springs back and from this wall surface part via / with pivot bearing guided lever device ( 153 ) Force via push-pull spring device ( 154 ) reacted in the direction against the medium flow to the axis rotation and on the one hand with the device movement ( 154 ) in one direction from the small wing area fraction ( 139 ) Force conversion and on the other hand via a rack surface ( 159 ) with tilt lever device ( 160 ) Force "in the pulse cycle" in rotation-axis rotation at the same time sets each flow force transmitted to the rotating direction with the flow direction wing-wall element surfaces transfer this thrust force applied pressure-buffer connection holder power to the axis rotation is transmitted. Method according to claim 1, characterized that a rotation device with multiple wing-wall element devices to an axis, which in a closed Strö determination machine housing device stored vertically or horizontally, wherein with flows of liquid or gaseous Working medium (eg water or compressed air) which with lifted Pressure level flows through a line connection to the housing and an opposite Conduit connection with low pressure level derived / continued, with the medium flow through the housing device in this the wing wall elements from the working medium flow acted upon, while the acted wing wall elements of which at least one with the flow direction rotating in the device holder against the Andrück-buffer device pressed on the one hand with the wing wall and buffer holder device force for axis rotation directly or indirectly depending on the attachment and on the other hand in the rotation cycle work impingement against the flow direction turning over the pivot bearing device holds the larger wing wall element away from the pressure-buffering devices turned over transmit the smaller force to at least one pull-push-spring-direction device, from this to the band hoop and with this over one Axis connection forwarded from this to the axis rotation or with direct attachment of the brackets of the wing wall elements and buffer devices on the axle device over them the force to the axis rotation and from the axis rotation power output for work assignment outward takes place, with the device fixtures attached to this at a fraction of 1 mm distance from the housing interior ceiling and bottom wall guided held as well as the axis side and the wing wall elements respectively in the three-sided closed with the imposition turning out Holder device kept at minimum distance, in modification to Procedures 2 and 3, the entire medium flow down to the indispensable Minimum labor-efficiently passed through the turbomachine and derived by the outflow opening becomes. A method according to claim 1-3, characterized in that supplied to the area under a wind turbine turret rotation device via lines hot water at some degrees above the ambient temperature / passed through and / or heat supplied to / from the surface heat to the water on the Water vapor and air buoyancy heat Buoyancy force generated with the turret rotation via spiral devices and the wind flow Actuation of wing wall element devices on / in the turret, led up a part of the wind Air flow to the outside of the turret-rotation device over and a part from bottom to top in the air buoyancy transported with cooling the air a proportion of water from the air to the wall elements and spirals and fortifications precipitates deposited, this water and rainfall in addition water over the bottom surfaces at/ collected in the turret via spiral and / or down line management implemented this water flow in turret rotation force and / or directed to one or more impact wing, this beauf discharged via water line connection, water after heat removal from the lower surface under the turret forwarded in a circulation and the turret rotation is transmitted via power transmission connections for driving at least one energy conversion device. A method according to claim 1, 3, 5, characterized in that connected via switching program specification, pulse remote control contact to pneumatically and / or electrically controlled locking devices ( 144 ) to the wing wall element fixing, transmit the angular rotation of the wing wall element device in / to a rotary device braked stopped over fixing of which reduce the rotation device rotations and / or the standstill of this causes and of the device no rotational force from the Wind-air medium flow more but supplied braking force and the rotation device slowly rotating if required or led to a standstill, is braked. Method according to the preceding claims, characterized in that energy conversion device located in / on the rotary device ( 30 ) ( 31 ) "Z. As alternator, generator and pump devices "these in the rotation in a turret device ( 59 ) entrained so via connected power transmission and switching devices energy for energy caching z. B. Battery / compressed air / compressed gas tank ( 32 ) ( 50 ) ( 52 ) or heat storage ( 75 ) are cached according to program specification and the energy primarily from the medium flow via the rotary device rotations and power transmission Verbindungsandrücken back to outside held all-around leading surface and / or edge strips ( 103 ) also implemented rotational force from the rotating device to the outside with wheel rollers ( 105 ) to these, via co-rotating edge or axle connection to outside the rotary device fixed generators and / or pump devices ( 105 ), is forwarded. Method according to the preceding claims, characterized in that, in the case of power transmission from sea / ocean current, one or more rotary devices with at least two wing-wall-element devices in combination with horizontal or vertical bearing axis guide the pre-rotation direction with predetermined right or left Rotation course at temporarily low admission of the wing wall elements when changing the water flow direction z. B. low tide and high tide or lack of wind flow in each case no switching operation for directional course of the axis rotation requires and the wing wall element movements with rotation of the rotary device via force-transmission connection of a driven by compressed air flow machine with wing wall elements in this and compressed air supply from compressed air accumulator from turbomachine power transmission to rotator device axis rotation and after switching control impulse delivery partially with / on idle circuit of the pumps and generator devices on time the vane wall elements partially without force feeding medium flow impingement via the force Transmissions from a turbomachine ( 95 ) the direction of rotation is maintained or set in motion again after standstill. Method according to the preceding claims, characterized that rotation transmissions from sea-water current and / or from wind power over Wing wall element Application in and on pipe register float raised and secured connected rotary devices takes place wherein the floats with flooded controlled water inlet or via compressed air supply water From portions of the tube chamber pushed out the devices in the See on a controlled appropriate depth held and with floods of pipe register portions in the floating body device partially or completely submerged under the water surface the water surface in horizontal and / or inclined position held with anchor holders and different filling of chambers, while the wing wall elements of rotating devices in the water flow of this applied and / or wing wall elements from protruding out of the water surface guided Rotational device with wind Impacted, flow force converted / forwarded, and the raising in and up partly over the water surface of the Pipe register float device with controlled flooding of the float device or with controlled Compressed air supply the water from the float chamber controlled again pushed out with accessories depending on weather conditions and maintenance requirements, below or above the water surface held above buoyancy or gravity use raised or lowered and depending on medium flow, wind and / or water flow effective for the production of electricity and / or compressed air becomes. Method according to the preceding claims, characterized in that in the floating body ( 21 ) ( 22 ) in different chambers ( 187 ) Compressed air cushioned from these as needed to push out the water from the flooded ( 188 ) ( 189 ) Chamber area with switching program and valve controlled and after pushing out of the water by the compressed air, this to and through a turbomachine device ( 51 ) work sam passed, compressed air with relaxation derived for cooling purposes, refilled via pumping device in conjunction with rotary device back to a predetermined pressure level, after the squeezing out of the water from the flooded area, the compressed air is lowered to a predetermined pressure level, is deducted labor. A method according to the preceding claims, characterized in that on a floating body device surface, a covering over large areas of rods or pipes surface covering ( 60 ) all around a turret rotation device ( 59 ) and preferably carried with rod connections ( 61 ) ( 62 ) ( 68 ) ( 70 ) with joint devices ( 63 ) ( 64 ) and floating tubes ( 22 ) standing over rope / chains ( 63 ) with weight and float devices ( 91 ) at the ends at a predetermined height ( 66 ) around the turret, whereby from the seawater through pipe guide ( 44 ) ( 45 ) guides the rope / chains with weight containers ( 71 ) ( 72 ) and programmable float ( 71 ) ( 72 ) Press out floods and / or water with compressed air from the weight and float devices ( 71 ) ( 72 ), these raised or lowered and thus the area spanning cover ( 60 ) ( 65 ) over the tube-float body-device surface ( 22 ) in all inclination ( 66 ) to the turret toward weather-controlled raised or lowered, water heat over cooling air supply z. B. with the compressed air insert via a turbomachine device, the water evaporation and this air heating from the sea-sea surfaces, these for heat buoyancy in the turret rotation device ( 59 ) conducted in this the heat buoyancy is converted into rotational force and water precipitation from the air against the upper cooling surfaces in the turret construction in particular soil and device surfaces ( 42 ) ( 131 ), he follows. The water which condenses from the air, working through fall lines in / out of a rotary device ( 165 ) ( 170 ) and / or guided with wing surfaces, is discharged into water reservoir / chambers. Device for carrying out the method 1-10, characterized in that a wind, or water, flow force into rotational force conversion device ( 1 ) ( 16 ) with at least two wing wall element devices ( 2 ) ( 4 ) in a staggered arrangement connection with a horizontally or vertically mounted axis guide ( 7 ) with construction brackets ( 10 ) ( 113 ) or frame connection with rotary rod or pivot bearing ( 149 ) ( 151 ) attaches a wing wall element ( 148 ) which on one side a larger area overhang with Andruck buffer ( 156 ) ( 157 ) and on the other side of the center of the center of the rod a smaller area overhang ( 147 ) or instead of this has a vertically aligned pipe with weight mass or the like projection relation or bow has, to the greater or lesser part of the wing-wall element a pressure buffer or tension-spring connection ( 139 ) ( 155 ) with attachment to a rotary device, outside the outside all-round hoops ( 6 ) and holder connection ( 113 ) ( 155 ) to the axis ( 7 ), having. Device for carrying out the method 1-11, characterized in that in the fastening area ( 113 ) ( 176 ) to the Wing Wall Panel Locking Devices ( 130 ), the switching line connection ( 39 ) to at least one compressed air reservoir and / or an electric battery. Device for carrying out the method 1-11, characterized in that Rota tions device on or in the rotation axis area a wheel-roll-pad and / or all-around overhang enclosure ( 179 ) and are connected to this rotational force / transmission device and via this one or more generators and / or pumping device which are mounted externally of the rotation device and have an axle rod with wheel-roll connections, as well as from the axis of rotation on support connection supported generator and / or pumping device having the wheel-roller connection to the outside fixed Umfassungs-ring devices and / or wheel-roll on or Aufdrückfläche. Device for carrying out the method 1-11, characterized in that a turret rotation device ( 59 ) with vertical axis and a lower round bottom ( 114 ) and at a distance from this one intermediate floor ( 137 ) and a roof surface and through the bottom surface air flow openings ( 110 ) which project over the bottom surface protruding tube inserts with curved wing spiral surfaces ( 111 ) on / in these and at a distance around the outside support rod and / or pipe construction fasteners ( 112 ), as well as around the uprising beam-rod construction several offset heights Umspannbänder ( 6 ) or reinforcing rings and through the turret bottom center an upright axle ( 7 with strut-holder connection therefrom to the turret outer side surface, offset therefrom or to these height-displaced wing wall element devices ( 114 ) ( 115 ) ( 116 ), the connections via espagnolette guide holders ( 151 ) ( 152 ) with push-pull buffer connections ( 139 ) ( 155 ) ( 156 ) to the axis and the outer carrier turret Umspannbands. Device for carrying out the method 1-11, characterized in that an up-pressure and / or roller-wheel rotation device connection ( 97 ) ( 103 ) ( 106 ) from the rotary device rotation axis ( 7 ) starting with axle shaft or V-belt ( 17 ) or the like to the outside of the rotation axis at a distance fixed devices, for. B. one or more generators ( 30 ) and / or pump device ( 31 ), and the rotary devices have an axle bearing construction which rests on liquid bearing guide in / on a rotary floating body device (US Pat. 56 ) attaches a shroud fixture footprint ( 96 ) has. Device for carrying out the method 1-11 characterized in that a rotary rotary tower in and / or under water on a liquid storage or floating body device ( 56 ) ( 96 ) with the buoyant shroud footprint on a large buoyancy device tube composition ( 21 ) ( 22 ) and under the water surface several height and at a predetermined distance movable holder ( 54 ) at the pipe connections ( 21 ) ( 22 ) as well as water supply and compressed air pipe connection and to and in the upright turret and floor surface lines to air pressure and water storage device having. Device for carrying out the method 1-11, characterized in that a wind or water flow force in rotational force conversion device ( 1 ) about a horizontal axis ( 7 ) on spacers a plurality of wing-Wandelemt devices offset to each other with holding device connection to the axis ( 7 ) and this pivot bearing / ball bearing support in or on pedestal ( 18 ) and at this a servomotor ( 15 ) and / or pneumatic slewing ring guide with line connection to a switching and control center has. Device for carrying out the method 1-11, characterized in that floating devices ( 21 ) ( 22 ) several side by side and heights offset successively rotating devices ( 40 ) ( 41 ) ( 42 ) with horizontal or vertical axes ( 7 ) ( 56 ) and these staggered wing Wandelemet devices ( 150 ) ( 151 ) ( 153 ) and from the axle power transmission connection ( 17 ) to pumps and / or generators supporting footprints on the buoyant tube assembly devices ( 21 ) ( 22 ) or on support columns ( 18 ) the footprints on / in or on the buoyant tube composition ( 21 ) ( 22 ) and the buoyant tube composition stand-alone connection with a turbomachine ( 51 ) and a winch ( 18 ) with chains Roller guide ( 48 ) wherein the cable or chain guides preferably by raw ( 45 ) and at the rope or chain end a weight device ( 71 ) with weight mass and cavities ( 41 ) ( 46 ) and to this compressed air line connection with the outer rope roller guides, routed to tube chambers, with compressed air controlled valve flaps and line connection with compressed air storage and to the flooding and compressed air chambers ( 118 ) in the floating body device ( 21 ) ( 22 ), exhibit. Device for carrying out the method 1-11, characterized in that a floating body device several pipe layers ( 21 ) ( 22 ) the criss-cross as well as sides and heights offset pipe support connection devices ( 76 ) to the tube crossing points, wherein in the tubes several chamber subdivisions ( 188 ) ( 189 ) and the tube-chamber partitions conduction connections through the tube-chamber walls with water or compressed air inlet-discharge openings and valve flaps ( 91 ) or the like in the compressed air line connections to compressed air supply raw chambers and from and to these and line connections to a turbomachine ( 51 ) and line connection to a compressed air storage ( 90 ) and these line connections to a compressed air pump ( 94 ) which connection to the rotation device ( 40 ) ( 42 ) or an axis ( 7 ) ( 56 ) has. Device for carrying out the method 1-11, characterized in that a ro tations device ( 16 ) with wing wall element devices ( 198 ) in a water flow guide tube or shaft ( 170 ) with axle ball bearing guide in or outside of the pipe shaft wall and an axis guide through the pipe / shaft wall and at this a force transmission connection ( 17 ) and in the water flow guide tube or shaft ( 170 ) in front of and behind the rotation device a pipe extension ( 166 ) ( 167 ) or in front of the rotary device housing ( 168 ) a cross-sectional division ( 165 ), with rounded surface use. Device for carrying out the method 1-11, characterized in that in / on a rotary device ( 1 ) Wing wall element devices ( 2 ) ( 3 ) ( 4 ) and these are via a retaining fixture ( 151 ) or carrier ( 113 ) ( 176 ) with the axis ( 7 ) And in / on the carrier wing wall element fixing devices ( 130 ) ( 144 ) as well as rotary hanger or rotary bar in / with ball bearing bushes ( 152 ) and in connection with this on one side of the larger wing wall element part ( 148 ) and on the other side of the smaller wing wall element part ( 147 ), preferably a weight-bearing yoke or a weight-filled tube ( 147 ), and the two wing wall elements on one side of one or more pivot bearing reinforcement bracket ( 149 ) and on the other side of the larger wing wall element part ( 148 ) Connection to pressing buffer ( 156 ) ( 157 ) with attachment of these to carriers ( 113 ) and the smaller wing wall element part ( 147 ) opposite from the axis side ( 7 ) Connection to force conversion ( 139 ) Pressure Spring Buffer Device ( 155 ) having. Device for carrying out the method 1-11, characterized in that in / on a rotary device ( 40 ) Wing wall element devices ( 132 ) ( 133 ) ( 134 ) ( 135 ) with the axis ( 7 ) Carrier connection ( 113 ) ( 176 ) to the Surround Ring Band ( 85 . 114 ) a rounded side surface ( 165 ) with roofing ( 161 ) and in / on the bracket-support connection the wing wall element pivot bushes ( 152 ) and buffers and fixing devices, and each wing wall element part ( 147 ) a force conversion device connection ( 139 ) ( 155 ) ( 159 ) and each wing wall element part ( 148 ) a cavity ( 184 ) and a roll-wheel device ( 185 ) under this with supporting roll support surfaces ( 186 ) under these as well as a connection of the wing wall element ( 148 ) Head side with a directional implementation rotary lever joint device ( 153 ) ( 160 ) and over this with a rotary-pull-spring device ( 154 ), Compound. Device for carrying out the method 1-11, characterized in that in / on a rotary device ( 41 ) with frame carrier ( 113 ) ( 176 ) and on / into these two-wing wing element devices ( 150 ), to each of which a wing wall element part ( 147 ) from the pivot bearing ( 152 ) to the axis connection with a force conversion device ( 139 ) ( 159 ) and one wing wall element part ( 147 ) between pivot bearing ( 152 ) and rounded frames ( 176 ) a connection with section outer side surface ( 165 ) and / or encircling ring ( 85 ) and to this a connection with a force conversion device ( 139 ) ( 154 ) also the head sides of the double wing wall elements ( 148 ) ( 162 ) at least one sliding roller guide ( 164 ) and a hedging cable connection ( 163 ), exhibit. Device for carrying out the method 1-11, characterized in that in / on a rotary device ( 42 ) with frame carrier ( 113 ) ( 176 ) wherein the wing wall element devices ( 132 ) ( 133 ) ( 134 ) ( 135 ) ( 136 ) "Floating" in the / the Drehangel ( 152 ) and one or more balls ( 55 ) in the upper part of the rotary carrier ( 176 ) and depending on the wing wall element part ( 147 ) adjacent to the axle shroud ( 7 ) with leaf-spring hinges ( 178 ) attached flaps ( 179 ) and to each wing wall element part ( 148 ) ( 162 ) a fixing device ( 144 ) and buffer device ( 156 ) ( 157 ) which are preferably telescopic springs and compressed air connection connections ( 39 ), exhibit. Device for carrying out the method 1-11, characterized in that a rotary / turbomachine device ( 51 ) ( 95 ) with wing wall element devices ( 2 ) ( 3 ) ( 4 ) with pivot bearing guide ( 151 ) ( 152 ) in a carrier frame ( 176 ) of this movably comprises with minimum joint distance ( 177 ) and the support frame in / around the wing wall elements on three sides of a closed wall and these three sides ( 174 ) ( 175 ) to the housing also a minimum gap distance ( 177 ) and to the axis side a force-conversion device ( 139 ) and a rounded side surface to the housing inner wall ( 173 ), the turbomachine housing has an inlet ( 171 ) and an outflow ( 172 ) Pipe connection and the machine housing outer wall a heat transfer flow-through chamber jacket or pipe coil ( 180 ) with inlet and outlet line connection ( 181 ) ( 182 ) and one in the maximum distance ( 175 ), valved conduit connection ( 183 ) as well as in the housing floor area ( 174 ) the axle bearing and through the housing top ( 175 ) an axle passage with power output connection ( 117 ), having.