DE102012100118A1 - Rotary bladed rotor assembly has guide wheel that is cooperatively arranged in direction of rotation of rotor blade - Google Patents

Abstract

The rotor assembly (1) has rotor annulus (18) that is movably arranged in such way that the baffle surface (14) turns away to the end of the movement in the direction of fluid flow by rotation of the rotor blade (13) until rotor blade occupies position in a return movement counter to the fluid flow. The guide wheel (7) is provided between the sun gear (6) and the operating wheel (11). The guide wheel is cooperatively arranged in the direction of rotation of the rotor blade. The direction of rotation of rotor blade is equal to the operating wheel about sun gear. An independent claim is included for method of converting kinetic energy of fluid flowing into mechanical rotational torque by rotary bladed rotor assembly.

Description

The present invention relates to a rotating blade rotor assembly and to a method of converting kinetic energy of a flowing fluid to mechanical torque by means of a rotating blade rotor assembly.

Rotary blade rotor assemblies are known in the art. It is also known to build them up of a plurality of resistance surfaces which move about their axis and about a central axis. Rotary vane rotor arrangements of the present type are preferably used in run-of-river power plants, while other fluids such as, for example, wind are also suitable as sources of kinetic flow energy if the energy density or flow velocity is sufficiently high.

That's how it describes EP 908621 A1 a novel wind or water wheel, in which the connection between a smaller gear in the middle and another gear with twice as many teeth is realized by a chain. The outer gears each have a resistance surface or a sail. By the chain drive ensures that the fluid, wind or water, when flowing through the device on one side of the flow cross section, the resistance surface flows in full extent, while it is on the opposite side in the return movement against the flow in the flow direction, that it represents only a minimal flow resistance. However, such a transmission is very susceptible to wear and dirt. In addition, only a single resistive surface can ever be operated in a plane, which limits the efficiency of the device.

Remedy could create here a turbomachine with a rotary blade rotor, as in the DE 2925249 A1 is described if it was used as an engine. In this turbomachine, a plurality of individual propellers are provided in a plane which rotate about a major axis and also about its own axis. The adjustment is made in such a way that the propeller when passing through a certain point on the circular path around the major axis also have the same angular position. However, this is only possible if the speeds around the main axis and about the propeller axis in the ratio 1: 2 to each other behave. To drive the propeller, these are each provided with a gear wheel, which rolls on the central gear. With a larger diameter of the propeller or the pitch circle large gear diameters are required, which have high costs and a high weight of the turbomachine result. According to the described solution, a primary gear for the central gear is alternatively provided, but also does not provide a remedy for the aforementioned problems.

The object of the invention is therefore to provide a rotary blade rotor assembly having a robust, low-wear, while inexpensive, small and lightweight construction and high flexibility in terms of usable flow velocities of a fluid.

The object is achieved by a rotary blade rotor assembly having a sun gear and at least one baffle surface of a rotor blade which faces a fluid flow and is connected to a work wheel that is movably mounted around the sun gear on a rotor circle ring in such a way that the baffle faces the end of the movement in the direction of the fluid flow from this by a rotation of the rotor blade away until the rotor blade against the fluid flow occupies a position substantially longitudinally thereto in a return movement, wherein between the sun gear and a working wheel, a guide wheel is arranged cooperating with these and the direction of rotation of the Rotor blade is equal to that of the working wheel around the sun gear. With the use of wheels can advantageously be used on one level, several planet gears, here the work wheels, and thus multiple rotor blades. The deflection wheel also ensures that the most important function, namely the establishment of the rotor blade position with respect to the position on the rotor ring, the orbit of the rotor blades around the sun gear, exactly, easily, flexibly and with little material cost is feasible.

In this case, a part, preferably half, of the flow cross section is guided by utilizing the kinetic flow energy to the baffles set up against the flow. In contrast, the other part of the flow can flow substantially unhindered through the rotary blade rotor assembly, since the rotors are set up in the flow direction such that the baffles are not or only to a small extent flowed. This also facilitates the return movement of the rotors in the starting position to be re-flowed by the flow again after appropriate employment and moved under force. In particular, the uniform pivoting in and out of the baffles with respect to the fluid flow is advantageous because this sudden loads are avoided and the rotating blade rotor assembly accordingly weaker, so easier and less expensive to interpret.

Preferably, the output shaft and a respective working wheel by a guide rod, which preferably has a wheel arm for receiving at least the working wheel connected. As a result, the power transmission from the fluid flow acted rotor on the working wheel to the output shaft realized in a low-loss and easy way. Preferably, the guide linkage is further connected to a respective deflecting wheel on a wheel arm or on the rotary ring, where the deflecting wheel is arranged.

Particularly preferably, a rotary ring is provided, on which each deflection wheel is arranged. If several deflection wheels are provided, then preferably all are fastened to one another at the same angular distance from the rotary ring. This has this Umlenkradachsen on which the deflection wheels are rotatably mounted. Alternatively, however, it is also provided that at least part of the deflection wheels itself has stub axles which are mounted in corresponding bearings in the rotary ring. In a further alternative embodiment, it is provided to break the rotary ring in the manner of lightweight construction, that it is a linkage, for example, an embodiment of the guide linkage is.

It has proved to be advantageous if the sun gear interact with the deflection wheel and / or the deflection wheel with the working wheel in each case by a toothing as a gear transmission. Gear drives are characterized by low wear and a particularly good, slip-free power transmission. This is particularly important so that there is no change in the position of the baffle at the intended position when circulating around the sun gear. Regardless of this, however, it is also provided as an alternative to gear transmission to use other forms of transmission such as the system friction wheel, if slippage can be avoided.

It is also advantageous if the rotary ring slides on a sliding surface on the base plate. This creates an inexpensive, low-interference solution to reduce friction. There are no complicated components that would require maintenance. However, it is alternatively provided in principle to use a rolling bearing or other known in the prior art type of storage.

Particular advantages result from a solution in which the sun gear, the guide linkage with at least one respective radar arm, a guide wheel and a working wheel with rotor blade are arranged on a base plate provided opposite the ground. This particularly preferred solution, in which the guide rod and the gearbox, ie sun gear, guide wheel and work wheel, are at the top, can dispense with a sliding surface, since the guide wheels do not load on a substrate. Above all, however, the transmission is thus not exposed to too much impurities in the fluid, for example flotsam in the water of a watercourse.

However, it is also provided in a modification to this, to arrange the rotary blade rotor assembly in a different way, for example, vertically in a falling stream or in an inclined barrel.

It is favorable if the housing has guide surfaces extending in the flow direction. Then the flow is directed in the area of action of the baffles, caught and can bring a higher efficiency in energy production, since a deflection away from the baffles is not possible. In this case, the fluid, preferably water, flows virtually laminarly along the guide surfaces in the housing, which are preferably fixedly connected to the base plate.

The object of the invention is further achieved by a method for converting kinetic energy of a flowing fluid into a mechanical torque by means of a rotary blade rotor assembly according to one of the preceding claims, wherein a fluid flows into the rotary blade rotor assembly, meets at least one baffle surface of a rotor blade and moves it in the flow direction wherein the rotor blade acts on a driven shaft via a working wheel and a guide linkage on which a torque can be tapped off, wherein the rotor blade with the working wheel has the same direction of rotation as the output shaft.

In this case, energy can be obtained even at a low-speed flow without adversely affecting the aquatic fauna. By a total of slow movement, which performs the rotary blade rotor assembly and thus allows evasion of the living beings existing there or even in a collision with these, the risk of injury can be extremely low. In addition, in the area where the impact surface is rotated from the flow, there is sufficient space for an undisturbed passage of the living beings with the flow and against this, especially for fish.

Further details and advantages of the invention are shown with the description of the figures. Show it:

1 a schematic perspective view of an embodiment of a rotary blade rotor assembly according to the invention;

2 a schematic representation in section transverse to the flow direction of an embodiment of a rotary blade rotor assembly according to the invention;

3 a schematic representation in section along the flow direction of an embodiment of a rotary blade rotor assembly according to the invention and

4 : A schematic half-schematic view in section transverse to the flow direction of an embodiment of a rotary blade rotor assembly according to the invention.

1 shows a schematic perspective view of an embodiment of a rotary blade rotor assembly according to the invention 1 , A housing 2 has a base plate 3 on, at the fins 4 are arranged. Between the fins 4 Central in the preferred embodiment is a sun gear 6 arranged and fixed to the base plate 3 connected.

To the sun wheel 6 run, in the preferred embodiment five, pulleys 7 , mounted on diverter axles 8th , The deflecting wheels 7 stand with the sun wheel 6 engaged. These are with a rotating ring 9 connected, concentric with the sun gear 6 and also around this movable on the base plate 3 is arranged.

The deflecting wheels 7 remain in engagement with the work wheels 11 , each on a wheel axis 12 are stored. The work wheels 11 continue to each have a rotor blade 13 on, over a baffle 14 , which is positioned against the fluid flow, has.

2 shows a schematic representation in section transverse to the flow direction of an embodiment of a rotary blade rotor assembly according to the invention 1 , The housing 2 is closed all around and has only openings for the inlet and outlet of the fluid flow. The baffle 14 is placed in the right area of the figure against the fluid flow, so that this kinetic energy removed and on the rotary blade rotor assembly 1 can be transferred. Means in the area of the base plate 3 and this opposite to the top of the housing 2 arranged guide rods 15 This energy acts as a mechanical force on the output shaft 17 transmitted and there induces a torque.

The flow cross section is through the baffles 4 that with the base plate 3 are connected, limited and the flow thus in the area of the rotary blade rotor assembly 1 guided. In the area of the base plate 3 is still a sliding surface 10 arranged the friction between the pulleys 7 and the base plate 3 helps to lessen.

3 shows a schematic representation in section along the flow direction of an embodiment of a rotary blade rotor assembly according to the invention 1 , Here, the arrangement of summarized to the preferred gear transmission working wheels 11 , Deflecting wheels 7 and the sun wheel 6 and their interaction through the gearing 24 clearly visible. The sun wheel 6 is here by means of fasteners 19 with the base plate 3 of the housing 2 connected. To the sun wheel 6 The turning ring is concentric around 9 arranged, the inclusion of the deflecting wheels 7 on the with the rotary ring 9 connected Umlenkradachsen 8th serves. The work wheels 11 each have a rotor blade 13 with a baffle 14 on. The deflecting wheels 7 and the work wheels 11 move in the direction of rotation 23 around the sun wheel 6 around, while at the same time the work wheels 11 in the direction of rotation 23 ' around her working wheel axis 12 rotate.

The fluid flows in the direction of flow 5 in the rotary blade rotor assembly 1 a, then meets at least a partial flow on the against the flow direction 5 erect baffle 14 on the rotor blade 13 on. The occurring force moves the rotor blade 13 in the flow direction 5 and, since the work wheel 11 over the here not recognizable guide rods concentric to the sun gear 6 is guided, in rotation 23 on the rotor circle ring 18 around the sun wheel 6 around. At the same time it also leads a rotational movement in the direction of rotation 23 ' around its own axis, the working wheel axis 12 , out. This is caused by the intermediate deflection wheel 7 ,

Has the work wheel 11 half a turn around the sun gear 6 performs, stands by the rotation of the work wheel 11 also the rotor blade 13 essentially along the flow, so that the baffle 14 no longer or only to a limited extent offers flow resistance. This is the return of the rotor blade 13 against the flow direction 5 relieved until it returns completely with the baffle after another half turn 14 set against the flow.

In the preferred embodiment is on the bottom of the housing 2 the rotary blade rotor assembly 1 , preferably in the center, a solid circular base plate 3 attached, on the preferred a sliding surface 10 on which the rotary ring 9 can slide easily, friction and wear, is appropriate. The one around the central axis 20 rotatable turning ring 9 gets from the sun gear 6 axially fixed and serves as a receptacle for the wheel arms 16 of the guide linkage 15 of which, in the preferred embodiment, five are arranged in a pitch circle at preferably the same angular distance.

Each wheel arm 16 leads by means of a Umlenkradachse attached thereto 8th and a working wheel axis 12 one divert wheel each 7 and a work wheel 11 to the central by means of fasteners 19 rigidly fixed sun wheel 6 around. By between sun wheel 6 and work wheel 11 arranged and engaged with these deflecting 7 experiences the work wheel 11 when loaded by that in the flow direction 5 flowing fluid the desired direction of rotation 23 ' , the direction of rotation 23 the output shaft 17 equivalent.

4 shows a schematic of an embodiment of a rotary blade rotor assembly according to the invention 1' in half-schematic representation, along the central axis 21 cut, and in section across the flow direction. Here, in a particularly preferred embodiment, the transmission consisting of the sun gear 6 , the diverter wheel 7 and the work wheel 11 , which engage with each other, at the top of the housing 2 arranged. The sun wheel 6 is with the connecting element 19 on the base plate 3 attached. The base plate carrying the gearbox 3 is the underground 22 arranged opposite, so that in the lower part of the fluid mitschwimmende impurities can not interfere with the transmission. This is especially important in a natural watercourse. Alternatively, however, it is also envisaged to protect or encapsulate the gearbox in such a way that neither foreign bodies nor living beings get into it.

The guide linkage 15 and its function is particularly visible here. The at the baffle 14 acting force is on the work wheel 11 , the working wheel axis 12 and on the wheel arm 16 of the guide linkage 15 transfer. This is with the output shaft 17 in the central warehouse 20 stored and where the desired torque can be tapped connected. An alternative embodiment provides that only half the cross-section, approximately along the central axis 21 divided, flows through or the flow in this area of the housing 2 is directed, in which the baffle 14 opposes the fluid flow.

It is also an application of the rotary blade rotor assembly 1 . 1' provided as a drive by passing through the baffles 14 a flow is driven.

The generated torque is in the preferred embodiment of five guide rods 15 on the output shaft 17 , coaxial with the central axis 21 runs, and preferably via a coupling, not shown, on an optional unit to be connected, for example, a generator for converting the applied torque into electrical energy transmitted.

The rotary blade rotor arrangement is preferred 1 . 1' can be used for small users and can be used particularly advantageously at a flow rate from 2 m / s. However, it is also envisaged the rotary blade rotor assembly 1 . 1' to optimize for other flow rates. Either the full flow cross-section can be used and passed through the rotary blade rotor or only part of it. It is also possible, the rotary blade rotor assembly 1 . 1' firmly anchored, for example, at the bottom of the watercourse, or a floating application, for example in the range of maximum flow or in an area where a disturbance of the other function of the flowing medium is excluded to provide.

The application of the rotary blade rotor assembly according to the invention 1 . 1' opens up untapped energy resources in running waters without changing them in their course and endangering them without water creatures. The solution according to the invention therefore brings particular advantages for the environment and at the same time nature conservation.

LIST OF REFERENCE NUMBERS

1, 1 '

 Rotating blade rotor arrangement

2

 casing

3

 baseplate

4

 baffles

5

 flow direction

6

 sun

7

 guide wheel

8th

 Umlenkradachse

9

 rotating ring

10

 sliding surface

11

 working wheel

12

 Arbeitsradachse

13

 rotor blade

14

 baffle

15

 guide linkage

16

 wheel arm

17

 output shaft

18

 Rotor annulus

19

 connecting element

20

 central warehouse

21

 central axis

22

 underground

23, 23 '

rotation

24

 gearing

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• EP 908621 A1 [0003]
• DE 2925249 A1 [0004]

Claims (8)

Rotary blade rotor assembly ( 1 . 1' ) with a sun wheel ( 6 ) and at least one impact surface ( 14 ) of a rotor blade ( 13 ), which faces a fluid flow and with a working wheel ( 11 ) connected to the sun gear ( 6 ) on a rotor ring ( 18 ) is movably arranged in such a way that the baffle surface ( 14 ) to the end of the movement in the flow direction ( 5 ) of the fluid from this by a rotation of the rotor blade ( 13 ) until the rotor blade ( 13 ) in a return movement counter to the flow direction ( 5 ) of the fluid occupies a position substantially longitudinally thereto, characterized in that between the sun gear ( 6 ) and one working wheel each ( 11 ) a deflection wheel ( 7 ) is arranged cooperatively with these and the direction of rotation ( 23 ) of the rotor blade ( 13 ) equal to the direction of rotation ( 23 ' ) of the working wheel ( 11 ) around the sun wheel ( 6 ). Rotary blade rotor assembly according to claim 1, characterized in that the output shaft ( 17 ) and at least one working wheel ( 11 ) by a guide rod ( 15 ) are connected. Rotary blade rotor assembly according to claim 1 or 2, characterized in that a rotary ring ( 9 ) is provided, on which each diverting wheel ( 7 ) is arranged. Rotary blade rotor assembly according to one of the preceding claims, characterized in that the sun gear ( 6 ) with the deflection wheel ( 7 ) and / or the deflection wheel ( 7 ) with the working wheel ( 11 ) each by a toothing ( 24 ) interact as a gear transmission. Rotary blade rotor arrangement according to one of the preceding claims, characterized in that the rotary ring ( 9 ) on a sliding surface ( 10 ) on a base plate ( 3 ) slides. Rotary blade rotor assembly according to one of the preceding claims, characterized in that the sun gear ( 6 ), the guide rod ( 15 ) with at least one respective radar arm ( 16 ), a deflection wheel ( 7 ) and a work wheel ( 11 ) with rotor blade ( 13 ) on one opposite the ground ( 22 ) provided base plate ( 3 ) are arranged. Rotary blade rotor arrangement according to one of the preceding claims, characterized in that a housing ( 2 ) in the flow direction ( 5 ) extending guide surfaces ( 4 ) having. Method for converting kinetic energy of a flowing fluid into a mechanical torque by means of a rotary blade rotor arrangement ( 1 . 1' ) according to one of the preceding claims, wherein a fluid in the rotary blade rotor assembly ( 1 . 1' ) flows on at least one baffle surface ( 14 ) of a rotor blade ( 13 ) and this in the flow direction ( 5 ), wherein the rotor blade ( 13 ) via a work wheel ( 11 ) and a guide rod ( 15 ) on an output shaft ( 17 ) acts, at which a torque can be tapped, characterized in that the rotor blade ( 13 ) with the working wheel ( 11 ) the same direction of rotation ( 23 . 23 ' ) has like the output shaft ( 17 ).

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