Twin turbine system which follows the wind/water (windtracker), for wind and/or water power

The invention relates to a turbine system comprising two radial turbines in accordance with the preamble of claim 1.

By comparison with the known three-blade wind generators having a horizontal axis of rotation and aircraft-type blades, a radial turbine has the major advantage of operating independently of the direction of the incident wind. Thus, the radial turbine having a vertical axis of rotation does not have to be turned to the wind.

In a particularly economical embodiment, the radial turbine is provided with deflector plates, which collect the wind energy and deflect it onto the blades of the radial turbine in a concentrated form. However, this has the drawback that, because of the deflector plate, independence from the wind direction is no longer achieved. The radial turbine comprising a deflector plate therefore has to be tracked to the wind.

An arrangement according to the international patent application WO 2011/059760 A2 [U.S. Pat. No. 8,167,533] (having the priority of Oct. 29, 2009) is known, which in any case is not aerodynamically optimized and does not automatically orientate itself to face into the wind. In this case, economical operation is not possible. This applies in particular to wind generators of the VAWT (vertical axis wind turbine) type, which operate more easily in regions of light wind at low heights.

Moreover, it should be noted that the principle of the above-mentioned patent application had already been applied for as a specific configuration more than 2 months earlier (see WO 2011/022836 A8—having the priority of Aug. 8, 2009). This device does not automatically orientate itself to face into the wind at low wind speeds, which can easily be demonstrated by reproduction, for example with a turbine diameter of approximately 1 m including power transmission and a connected generator.

Object of the invention: a radial turbine is to be used which comprises a deflector plate and which automatically turns to an optimum angular position with respect to the incident wind, and is thus self-tracking, without a tracking arrangement being necessary for this purpose. The advantages of the deflector plate in the radial turbine are thus to be combined with the independence of the radial turbine from the incident wind direction.

This object is achieved in accordance with the invention by the features of claim 1.

Advantageous embodiments of the invention are specified in the dependent claims.

Another important consideration: suppose there are two turbines in a system enclosed by deflector plates and having additional beveled concentration plates which are attached above and below the turbines. As a result of the closed system and the additional concentration plates, optimum use is made of what is known as the Magnus effect, and as a result the system according to the invention, which is mounted on a mast, can rotate to the wind automatically and thus always receive an optimum wind flow. This “turning to the wind” has been demonstrated in a number of specific models in natural wind.

The Magnus effect, named after Heinrich Gustav Magnus (1802-1870), who discovered it, is a phenomenon in fluid mechanics, specifically the transverse force effect (force) experienced by a round rotating body (cylinder or ball) in a flow.

By way of frictional effects, a rotating roller induces rotation in the fluid surrounding it. If there is additionally a flow over the roller, the different speeds of fluid overlap. As a result, the fluid flows around the rotating roller faster on one side than on the other (in the rest system of the roller). On the side of the roller where the frictional effects are greater, it is as if the fluid were flowing more rapidly. This results in “deflection” of the roller, pushing the roller downward (see FIG. 4).

• • Football players kick the ball with spin in such a way that it flies into the goal in an arc. The more quickly it rotates, the greater the deviation of the path (curling cross, knuckleball).
  • Table tennis players and tennis players use this effect, for example with topspin and slicing.
  • Curve balls in baseball and risers in softball.
  • Spin-bowling in cricket.
  • Golf balls have a large number of small depressions on the surface, known as dimples. As turbulators, they improve the adhesion of the boundary layer which lies against the ball and is entrained by the rotation thereof. This increases the formation of turbulence and the associated deviation of the ball due to the Magnus effect. Since the golf ball rotates backward as a result of the wedge shape of the golf club, it is lifted by the Magnus effect; it does not simply fly like a cannonball, but instead experiences a lift. Additional deviations to the left or right are possible, and are also used by players who have mastered this technique. Moreover, the supercritical turbulent circulation reduces the air resistance, and this in turn leads to greater flight distances.

According to the invention, high performance is achieved in combination with low installation costs, in such a way that the cost-effectiveness, in terms of power output, is much greater than in the known wind generators comprising a horizontal shaft and blades of the aircraft-wing type.

To increase the cost-effectiveness, a ring generator is provided for power generation. In addition, to increase the cost-effectiveness further, the mast and the wind splitter can be used as advertising space.

By contrast with the known wind generators comprising a horizontal shaft and three blades, the radial turbine according to the invention can be operated even at relatively low wind speeds. As a result of the Magnus effect, the radial turbine according to the invention “pulls” the wind in, as it were, and amplifies low wind speeds. For example, the radial turbine according to the invention can also be used in circulating winds, in which the wind speed is greater below at a low height than at the large height at which the three-blade wind generators have to be operated simply because of the blade size. A wind speed which is too low for the known three-blade turbines in any case is sufficient for energy production with the radial turbine according to the invention.

In the event of fluctuations in the wind direction, the radial turbine according to the invention adjusts itself automatically, partly as a result of the Magnus effect, and immediately rotates to the optimum direction, even at wind speeds of less than 1 m/s. Rapid adaptations of this type of the generator are not possible with the known three-blade turbines.

Since the radial turbine according to the invention only takes up a small amount of space, it can be used as an add-on to pre-existing parts of buildings or structural elements, for example as an attachment to a street light.

FIG. 1 is a perspective drawing of the wind generator according to the invention, comprising two radial turbines 1, 2 and a V-shaped wind splitter 3, the radial turbines and wind splitter being attached to a steel mast 5 or another base part 6 so as to be rotatable (pivotable) as a whole about a vertical axis.

The efficiency of the wind generator is substantially dependent on the position of the V-shaped wind splitter, based on the distance and inclination to the turbine blades and the turbine shaft. The wind generator is additionally advantageously technically equipped such that, according to the wind speed, the optimum position of the wind splitter can be set. The setting can take place on the one hand as a fixed setting for the average (most probable) wind speed; on the other hand, it is also possible to automatically reset to the optimum position based on the current wind speed.

For an overall height of 20 m, the height of the turbines is 10 m. The turbines have a diameter of 1 m. The expected capacity for a site on the coast, where the wind generator captures the circulating coastal wind, is approximately 21,700 kWh, with an efficiency averaged over the year of 38%.

FIG. 2 shows the constructional details of an embodiment as a tubular mast mounting system in a view from the side corresponding to A-A in FIG. 3. Three support plates 7, 8, 9 are attached to the 20 m high steel mast 5 by means of bearings 10, 11, 12, 13, 14 so as to be rotatable about the longitudinal axis 15 of the steel mast 5. The lower support plate 7 has three rotary bearings 10 on the steel mast 5 and two turbine bearings 16, 17 on the turbine shaft 18. The central turbine plate 8 has three rotary bearings 12 and two turbine bearings 19, 20, and the upper support plate 9 has three rotary bearings 14 and two turbine bearings 21, 22. The turbine bearings 17, 20 and 22 are not shown in FIG. 2, and are associated with the other turbine.

The rotary bearings 10, 11 on the one hand and 13, 14 on the other hand are kept at a distance by a spacer collar 23, 24. The spacer collar is in the form of a hollow tube.

Finally, FIG. 3 is a plan view of the wind generator. The turbine blades 25 can be seen. The wind direction, when the wind generator according to the invention has turned to the wind in such a way that the tip of the V-shaped wind splitter 3 points counter to the wind, is also indicated with an arrow.

What is known as a thread test was carried out on the system according to the invention (FIG. 5). Wind 28 at up to 6 m/s was blowing into the system. The ratio of the circumferential speed of the turbine to the wind was up to 3:1. The point where the thread direction breaks away can be seen clearly in FIG. 5 (at the bottom of the picture). The system according to the invention can extract energy from the pressure difference or the potential energy of the wind, not just from the kinetic energy of the moving air.

The significance of the reference numerals in FIG. 5 can be seen from the list of reference numerals.

A side effect is the ping-pong ball which is “suspended” in an oblique airstream. As a result of the Conda effect, the flow of the airstream is not stripped away from the ball, but encircles it (almost) completely without being stripped away. Since the ball is suspended slightly below the center of the airstream, the air does not flow around it symmetrically. More air is deflected downward, since the flow speed and flow cross-section are lower at the underside of the ball than at the upper side. As a result, the ball experiences an upward force. This is superposed on the Magnus effect (the ball rotating). The two effects each prevent the ball from falling downward and only allow it to “slip” along the underside of the airstream. The resistance of the ball to the flow holds it at a distance from the nozzle, and gravity prevents it from simply being blown away. Thus, the ball can float in a more or less stable position.

FIGS. 6 to 8 show further variants with modified deflector surfaces 29 and additional concentration plates 30. Evaluation of static and dynamic torque measurements on the wind turbine according to the invention of diameter 1 m and length 1 m in Moers

The following data are taken into account, directly or indirectly, in the evaluation:

• • Static torque measurements (stationary torque) from 24 to 26 Sep. 2010
  • Dynamic torque measurements in the period from 4 to 8 November 2010

An eddy current brake, with which various braking forces could be set by varying the coil current, was also used during the dynamic measurements in each case.

The measurement values were checked for plausibility and evaluated using various averaging and filtering methods.

The result data for wind speeds of between 2 and 8 m/s are compiled in the following table.

FIGS. 9 and 10 are graphical representations with corresponding interpolated lines.

FIG. 9: torque vs. rotational speed characteristics, interpolation with average power coefficient (PC) 35%

• • Torque vs. rotational speed; parameter wind speed [m/s]
  • Key to graph:

 2 m/s measurement

• • ▴ 3 m/s measurement
  • X 4 m/s measurement
  • + 5 m/s measurement
  • − 6 m/s from measurement
  • ▪ 7 m/s from measurement
  • x 8 m/s from measurement
  • ------ max. torque
  • - - - - ave. torque
  • FIG. 10: characteristics
  • Mech. power
  • Extrapolation in the maximum power range with average PC=35%
  • Mechanical power vs. torque; parameter wind speed [m/s]
  • Key to graph:
  • ▪ 2 m/s eddy current brake
  • x 3 m/s eddy current brake
  •  4 m/s eddy current brake
  • − 5 m/s eddy current brake
  • ♦ 6 m/s from eddy current brake
  • ▴ 7 m/s from eddy current brake
  • x 8 m/s from eddy current brake

Since the dynamic measurements thus far have only been carried out with relatively weak braking forces, the interpolation outside the measurement range that has been established thus far is shown in dashed lines. In this context, it has been assumed that at the maximum power point a power coefficient of 35% is achieved. From the dispersion of the result data, sufficiently precise calibration verification for the measurement technique used can provisionally be placed at approximately 30-40%. Otherwise, the systematic errors in the measurement technique have to be additionally taken into account. The power coefficient can be determined more precisely if further measurements at higher braking forces are taken into account.

The turbine system according to the invention can also advantageously be used in water for obtaining energy from the flow of water, that is to say as a marine turbine system.

Attaching two additional deflector plates 38, 39 (see FIG. 11) results in what is known as the Venturi effect. The Venturi effect increases the efficiency of the turbines.

From the development, a further embodiment is presented which has demonstrated high efficiency values in turbulent wind in the preliminary studies.

The pivot point for the independent azimuth adjustment and the deflector plate in the form of a “nose” has been optimized (see FIG. 12 and FIG. 13a). In this case, the turbine system already turns optimally to the wind from approximately 1.0 m/s when the turbine support system is well mounted.

Advantageously, the upper tower section is rotatably mounted relative to the lower tower section. The mounting is configured such that, above a wind speed of approximately 1.0 m/s, the azimuth torque is sufficient to safely overcome the brake forces of the bearings, taking into account the wind pressure.

By contrast to the published solution of the international patent application WO 2011/059760 A2 (having the priority of Oct. 29, 2009), the invention in this case relates to an aerodynamically optimized system which automatically orientates itself to face into the wind. Efficient operation is only possible if it can be guaranteed that the orientation to face into the wind can take place with no (or with almost no) additional energy. This applies all the more to wind generators of the VAWT type, which operate more easily in regions of light wind at low heights.

Moreover, it should be noted that the principle of the above-mentioned patent application had already been applied for as a specific configuration more than 2 months earlier (see WO 2011/022836 A8—having the priority of Aug. 28, 2009). As a distinction from the last-mentioned application having earlier priority, it should be noted that this device does not orientate itself to face into the wind at low wind speeds, which can easily be demonstrated by reproduction, for example with a turbine diameter of approximately 1 m including power transmission and a connected generator. Instead of the described sail, an aerodynamically optimized double deflector plate in the form of a “nose” is additionally used in this case, which increases the efficiency of the whole system and simultaneously guarantees automatic orientation to face into the wind for all winds having relevant energy, including light winds from wind force 1.

The V-shaped “nose” according to the invention (referred to as a wind splitter) was not primarily developed as either an accelerator or as a deflector. Rather, it serves as a resonance chamber for infrasound in the range of approximately 1 to 10 Hz (i.e. silent). The nose and rotor blade form an air guide device for generating a pressure oscillation between the nose and the rotor blade in the interior of the nose. This pressure oscillation takes place in phase with the rotation of the turbine. By means of this silent pressure oscillation and a generally very low-vibration construction, the efficiency of the turbine is increased in regions of light wind, such that it is eminently suitable for use in urban areas.

The distance between the V-shaped wind splitter and the turbines is preferably variable and adjustable, so that optimum operating conditions can be achieved for all wind conditions.

The edge of the V-shaped wind splitter (3) is preferably rounded, in order to prevent a tendency to whistling and to the formation of turbulence.

A further parameter for characterizing the embodiment is the height of the turbine and/or row of turbines. Functionally, the height can be adjusted largely as desired, for example according to a site of operation approximately 0.3 to 100 times the radius of the turbine, wherein a tall (or long) turbine can be configured as a positive-fit coupling of a plurality of turbines to a shaft which is optionally flexibly connected by means of positive-fit couplings.

In the embodiment, a ratio of height to radius of approximately 20 is set. In this case, the turbines are all mounted approximately 5 m apart and are interconnected by a flexible, positive-fit coupling, and are connected directly or indirectly via a gearbox to a current generator at the end of the shaft, the bearing being rigidly connected to the rotatable part of the mast.

A further variant relates to the upper or lower end of the turbine. By means of a planar wind guide plate which is chamfered away from the turbine at the outer edges optionally slightly and up to approximately 45°, the wind can be deflected in the edge region onto the turbine more effectively (see FIGS. 13a and 13b). FIG. 13b shows a plan view of the section A-A in FIG. 13a. Moreover, the stability of the turbine suspension is improved thereby.

In order to avert and/or reduce danger in the event of heavy storms, the system can be equipped with a self-damping control system, such that the turbines are moved closer together above a certain wind speed; the dynamic pressure at the back behind the “nose” is increased thereby, which ultimately leads to the damping of the rotational speed, such that when this damping system is suitably dimensioned, the rotational speeds can be kept in the safe range. The damping can be verified when the distance between two turbine shafts is less than 3×R1 (R1=radius of the is turbine). An additional mechanical brake would only be necessary in the event of a very improbable emergency or for maintenance work.

The aim of the turbine system is to obtain the optimum amount of energy from the wind, wherein obtaining electrical energy is the priority. In addition, a generator adapted to the turbine system is mechanically connected to the turbine shaft directly or indirectly via a gearbox in a non-positive or positive-fit manner, which shaft is connected to the turbines in a non-positive or positive-fit manner, in order to guarantee the transmission of power from the turbine to the generator. In this case, one generator can be used for the two turbines, or each turbine can each be individually connected to a generator.

The generator is controlled according to the wind speed, such that by controlling the generated power, an electromagnetic braking torque is transmitted to the turbine, such that an optimum tip speed ratio (TSR) for converting energy is set, which is between 45% and 65% based on the tip speed ratio of the unbraked turbine. As a result, the maximum possible energy can always be “harvested”.

The generated electrical energy (direct current, alternating current, three-phase current) can be utilized in a plurality of ways:

• • a) it can be converted into grid-synchronous alternating voltage and fed into the public power grid,
  • b) it can be buffered in a local battery system, i.e. a battery system located in the tower, which is is converted into grid-synchronous alternating voltage according to the requirements of the network operator, taking into account the maintenance of a consistently receptive battery system, intermittently with a high degree of efficiency, and then fed into the public power grid. In this variant, there will be times where only charging takes place, where only discharging takes place and the electrical energy is fed into the grid, or where the charging and discharging take place in parallel. Optionally, this variant also allows buffering of the current from the grid in times of low current uptake; an embodiment of this type would be a combined wind energy system comprising integrated storage components which can be used internally and externally.

In order to safely preclude overcharging the battery system or overloading the current transformer to the grid feed, the control system in the embodiment allows excess generated electrical energy, which can neither be charged into a battery nor fed into the grid, to be converted by a chopper resistor into heat, in a manner which is safe and free from wear. By means of this control system, the range of applications of relevant wind speeds can be optimally expanded.

A further variant relates to use as an advertising medium or as street lighting. Any desired highly efficient light sources, for example LEDs for advertising illumination or street lighting, can be attached to the turbine system whilst adhering to the external shape specifications (turbine, nose-deflector plate, upper and lower cover). The current would be supplied directly from the battery system and is therefore also still independent from the grid.

The control system of the turbine system is also independent from the grid, since it is powered by an independent battery which is stored in a fireproof manner and is permanently monitored.

A further variant relates to a use as a support for urban infrastructure measures, for example alarm devices, surveillance cameras, mobile phone antennae, urban WLAN Intranet, display boards, traffic guidance devices, broadband internet connection, etc. In this case, the particular advantage is that an independent current source (battery storage) is available locally on site.

When there is low demand for electrical energy, the wind and solar energy can be stored locally for later use and by selectively discharging at peak times, a particularly economical use can be achieved.

In a further embodiment, a grid mast construction, which is and/or can be used as a frame for the special accumulator and turbine mounting system, is provided above the rotary connection, which is fixed to a stationary mast (see FIG. 13a). The cavity inside the grid mast provides enough space for safely installing/fastening accumulators and for load control; at the same time, the cable lengths from the generator can be kept short so as to keep Ohmic losses low.

It is advantageous to bring together a plurality of windtrackers to form a decentralized network-communicating energy supply system and other applications. It is therefore proposed to provide an arrangement of the turbine systems according to the invention and/or of the windtrackers along the traffic infrastructure, such as streets, motorways, railway lines and canals, which arrangement is additionally provided for telecommunications or for buffering current from the grid in times of low current uptake and/or for use as an advertising medium and/or as street lighting and/or for providing safety spaces.

• 1 radial turbine
• 2 radial turbine
• 3 wind splitter
• 5 steel mast
• 6 base plate
• 7 support plate
• 8 support plate
• 9 support plate
• 10 (rotary) bearing
• 11 (rotary) bearing
• 12 (rotary) bearing
• 13 (rotary) bearing
• 14 (rotary) bearing
• 15 longitudinal axis
• 16 turbine bearing
• 17 turbine bearing
• 18 turbine shaft
• 19 turbine bearing
• 20 turbine bearing
• 21 turbine bearing
• 22 turbine bearing
• 23 spacer collar
• 24 spacer collar
• 25 turbine blades
• 26 upper collar flange
• 27 guide flange
• 28 wind
• 29 modified deflector surface
• 30 concentration plate or concentration surface
• 31 Magnus effect
• 32 Conda effect
• 33 Magnus/Conda superposition
• 34 high lift
• 35 negative pressure
• 36 overpressure
• 37 thread direction breaks away
• 38 external deflector surface
• 39 external deflector surface
• 40 turbine or turbine blade
• 41 center of rotation of the turbine
• 42 center of azimuth rotation of the turbine system
• 43 nose deflector plate
• 44 limit of the upper and/or lower wind guide plate
• 301 external radius of the turbines or turbine blades
• 302 rounding of the wind guide plate
• 303 wind guide plate
• 304 grid mast
• 305 V-shaped wind splitter