DE19846796A1 - Floating wind power system, has electricity generating wind power devices attached to floating system to be as close as possible above sea surface, and symmetrical about floating system center - Google Patents

Abstract

The system has one or more electrical current generating wind power arrangements (1) attached to a floating system. The wind power generators are mounted as close as possible above the sea surface, and are symmetrical with respect to the center of the floating system.

Description

field of use

The invention relates to a device according to the preamble of claim 1.

State of the art

Wind energy plants (WTGs) are known that are based on land and that work economically, especially in windy areas.

Leave acceptance problems on land and better wind conditions at sea the use of wind turbines at sea, i.e. offshore, appears to be economically worthwhile. To our knowledge, offshore wind turbines have so far been implemented in Denmark and in the Netherlands, the shallow water up to 20 m so-called mono piles or caisson foundations are founded [1]. The Are onshore wind turbines with the lowest specific energy production costs the wind turbines in the performance class around 600 kW [2]. With offshore wind turbines, they are specific energy production costs due to the complex foundation higher. In order to reduce this, offshore wind turbines must have the Rotor diameter and rotor speeds are increased, which causes that the performance of the wind turbine is increased.

Disadvantages of the prior art

According to our information, there are already in the south of England Tenders for offshore projects for Atlantic ocean depths between 50 m and 100 m. There, you keep the specific energy production costs in  Eye, the deeper founded offshore wind farms have to get bigger the deeper would be proof that offshore wind turbines are floating can be operated, equating to the proof that from one certain sea depth the floating wind turbine system is the most economical considered the cheapest solution. As the main disadvantage of the stand or Trends in offshore wind turbine technology must be assessed so that by moving towards building large-scale wind turbines, the proven to be the most economical range of wind turbine size with the Performance class around 600 kW. That big wind turbines with one performance over 1 MW have hardly been tested or operated with little success, must also be regarded as disadvantageous if this with monopile or Mass foundation offshore systems in deep water for Would be used because maintenance and repair costs increase in this case disproportionately compared to tried and tested series wind turbines in Power range between 500 kW and 1 MW. As another related Disadvantages have all the typical disadvantages of large wind turbines over 1 MW be seen in the field of technology in production, installation and the operation of the facilities are available and cannot be disputed away [3].

Object of the invention

• 1) The main task of the floating wind turbine system is that in the low-turbulence sea wind contains kinetic energy of the air flow converting it into electrical energy at sea. Because the roughness length the sea surface is small, does not need to be built high.
• 2) The object of the invention is also that it is its main task as far as possible regardless of the depth of the sea.
• 3) Another object of the invention is to provide the opportunity to Integration of hydrogen production systems into the system if in Future loss of efficiency in the transportation of electrical energy with Submarine cables can not be reduced further than possible today.
• 4) Additional object of the invention is to undertake its main task Using the passive use of the To comply with wind direction tracking, if the local conditions so allow.
• 5) An additional object of the invention should be that possible in the event of accidents the failure of the overall system is avoided.

Solution of the problems posed on the invention

These tasks are carried out by the construction or device with the Features of the claims solved.  

Advantages of the invention

• 1) Electricity is generated using conventional, proven series wind turbines with a performance class between 500 kW and 1 MW. We have specifically planned, for example, floating wind turbine systems with three wind turbines each with 750 kW. Wind turbines with a two-blade pitch system are to be used [4]. By arranging three wind turbines on a cross member, application example 1 ( Fig. 1-5 ) or a relatively flat support system, application example 2 ( Fig. 6 - Fig. 8), one has the advantage of a large flow area preserved without having to build high and expensive.
  Due to the possibility of parking the rotors of the wind turbines horizontally in dangerous storms and heavy seas, the safety distance from the maximum wave height to the lowest point of the rotor circle can be replaced by the safety distance from the maximum wave height to the cross member. This parking position provides mechanical relief for dangerous windstorms for the wind turbine system.
• 2) The floating wind turbine system has the advantage that it is just as far from the depth of the sea can be operated independently, like the fixation of the Systems by two anchor chains, hawser or similar, this allows. This means that the floating wind turbine system compared to established offshore wind turbine systems, economically speaking, all the more cuts cheaper, the deeper the sea is where the floating WEA system can still be operated.
• 3) It is an advantage with the floating wind turbine system that with the Catamaran-like layout either on the floats or on a platform to be inserted between the floats enough construction space can be created, for example the Production, storage and loading of hydrogen allowed.
• 4) Even with conventional onshore series WEAS, the tracking of the Tower head in the wind because of the comparatively high, necessary technical effort problematic. It is a big advantage of the floating wind turbine system, for safety reasons two chains or similar, possibly lighter fasteners To be able to passively let the system drift in the wind. Should be at an angle or across Ocean currents that make this difficult must be active operated rudders or drives are provided on the floats, who take corrective action in this regard. Alignment alignment after Wind direction happens via wind direction sensors, which on the Gondola roofs of the two, each on the outside of the cross member of the wind turbine system sitting WEAs are attached. Should the purely passive wind direction operation the floating wind turbine system would be possible in the event of a lull floating disoriented at sea. Since the system is anchored, this would be at Calm no problem. When the wind comes up, this is correct  floating wind turbine system due to the type of anchorage with a double anchoring brought together at the anchor point, independently according to the wind direction. It’s still an advantage that, for example, if a chain breaks, the wind turbine system from the wind would turn, whereupon the management system immediately transferred the wind turbines into the Would control parking position and, if necessary, an automated radio Service call would send.
• 5) Similar to the operation of onshore wind farms floating wind turbine system the advantage of failure of a wind turbine not the whole wind turbine system comes to a standstill. If maintained of a symmetrical system with regard to the wind turbine arrangement, as shown in the Embodiments is set out, however, for reasons of stable Alignment according to the wind is necessary, for example if a Edge wind turbine, the opposite wind turbine, must also be switched off. In the event of failure, the centrally located wind turbines are not here Compensation measures necessary.
• 6) The single-row arrangement of the wind turbines on the floating wind turbine system, avoids the disadvantage of derating due to wind farm effects, like them would occur in a two or more row arrangement.
• 7) The floating wind turbine system offers the possibility of sea-proof Lightweight construction, based on that of conventional offshore technology used truss-crane construction can be used.

Description of exemplary embodiments

Illustrations of three exemplary embodiments are attached to the invention.

Embodiment 1 of the invention is shown in the accompanying drawing in FIGS. 1-5 and is described in more detail below. Embodiment 2 is shown in the accompanying drawing in FIGS. 6-8 . The embodiment 3 is 10 to be seen in the accompanying drawing in Fig. 9 and Fig..

Embodiment 1

On the drawing in Fig. 1 - Fig. 5, the overall construction is shown of floating WEA system in production mode in three views (Figures 2, 3 and 5...). In two views of the wind turbine system are illustrated which, relieving the case of dangerous storm, the entire carrier system park position (Fig. 1 and Fig. 4) shows.

The floating wind turbine system consists of in this embodiment three wind turbines of the two-blade pitch type as described in [4], but with 44 m Rotor diameter and a nominal speed of approx. 38 rotor revolutions per Minute, so that a nominal power of 3 × 750 kW at a Wind speed of 13 m / s results.

The total rotor circle area is 3 × 1520.53 m ² = 4561.6 m ² . To avoid backflow problems, a rotor circle distance of 17 m was chosen. The three wind turbines ( 1 ) ( Fig. 5) are positioned symmetrically in two spatial axes and rigidly fixed on a 122 m long cross member ( 4 ) ( Fig. 3). In this example, the wind turbines or the wind turbine heads, also called gondolas ( 1 ) ( FIG. 5), cannot be rotated azimuthally (yaw movement) relative to the cross member ( 4 ) ( FIG. 3). The cross member ( 4 ) carrying the three wind turbines is carried by two side supports ( 5 ) ( FIG. 5). The arrangement of an equilateral triangle was chosen for the side support construction for maximum stiffness design parallel to the wind direction. This is intended to largely suppress the transmission of vibrations from the waves coming from the wind direction to vibrate the floating bodies to the wind turbine heads. The side supports stand on catamaran-like floating bodies ( 3 ) ( Fig. 3). The base points of the side supports are connected in the longitudinal and transverse directions with four struts ( 6 ) ( Fig. 3) and ( 7 ) ( Fig. 5). Two struts ( 6 ) connect the floating bodies ( 3 ) to each other and one strut ( 7 ) runs lengthways on or immediately above the two floating bodies between the base points of the side supports ( 5 ).

In this exemplary embodiment, the floating bodies ( 3 ) are designed with a diameter of 7 m and a length of 40 m. With semi-submerged ski floats, there is a buoyancy force that corresponds to 1539 tons without taking into account the mass of the floats.

The possibility of varying this buoyancy under the float The mass of the floats is taken into account by I) Change in diameter, II) change in length, III) immersion depth and IV) Choice of materials. The floats can be made of plastic, steel or concrete be executed. The beams, supports and struts can be made from profiled bars, Truss cantilevers or specially designed support structure Constructions are carried out. Materials to be used must the requirements placed on them and in terms of costs. The WEA weights are estimated at 3 × 50 t to 3 × 70 t. The weight The load-bearing structure depends on the requirements, such as those of the Results from load case examples and simulation calculations required become.

The shown in the drawing, [5] in Fig. 1 to Fig. 5 WTG system is designed as a windward rotor system, so as a facing the wind system. However, a Lee runner variant is also possible.

An anchor chain ( 2 ) ( FIG. 5) or a comparable seaworthy fastening option, which can be designed to be less prone to corrosion or lighter or with less mass, is provided on the front part of each floating body for anchoring on the seabed. For the attachment possibility starting from the two floating bodies, only a common attachment point is provided on the seabed. This can be an anchor designed according to the requirements, a block with a heavy mass or a direct attachment to solid or rocky ground.

If surface ocean currents are not If the wind direction should match, the wind turbine system must be Be equipped. That can on the float stern rudders to be attached or active drives for navigation. The In this case, rudder or drive control must be from the overall control of the wind turbine system.

Embodiment 2 and 3rd

The illustrated embodiments to Fig. 10 in the drawing, [5] in FIG. 6 to FIG. 8 and FIG. 9 show the embodiment 1 is substantially compliant variants whose total height is greater, but with greater compactness of the entire wind turbine system. This reduces the effective lever lengths and the design effort required to achieve the required strength with regard to the loads. The embodiment 2 shown in Fig. 6 to Fig. 8 shows three views of three equally large wind turbines that are all disposed in the upwind direction. The embodiment 3, shown in Fig. 9 and Fig. 10 shows a schematic in two views of a three-dimensional representation (FIG. 9) and a top view (Fig. 10), three different sizes of wind turbines, the two of which outside fitting, smaller WEAs are arranged on the windward side and the larger, centrally located wind turbine is arranged in the windward direction.

Appendix and literature

[1] Development and opportunities at sea; Trade magazine: Wind Energie Aktuell 3/96; Publisher: Winkra-Recom Messe- und Verlags-GmbH, Communication for Renewable Energies, Leisewitzstr. 37, 30175 Hanover
[2] wind energy, theory, application, measurement; 2nd Edition; Molly, Jens-Peter; Published by CF Müller Karlsruhe
[3] wind turbines, basics and design; 3rd Edition; Gasch, Robert; Publisher: BG Teubner Stuttgart 1996
[4] Technical description - Ventis V12 wind turbine; Ventis Energy GmbH, Ernst Böhme Str. 27, 38112 Braunschweig
[5] Draft 1, 2 u. 3 ,: Floating wind turbine system; Drawing, 3 sheets; C. Geissler, D. Kolbert, F. Richert, R. Schemmink; 1998; Brunswick
[6] Wind power plant (Wka) with permanently connected rotor blades on an external rotor ring generator, Richert, Frank, Schulweg 3, 38518 Gifhorn
[7] wind turbines; Security requirements; ENV 61400-1; February 1995; Published by Beuth, Berlin

Claims (12)

1. Device for holding and carrying electrical current-generating wind turbines ( 1 ) ( FIG. 5) at sea (mass-based or monopile-based systems are known), characterized in that one or more wind turbines ( 1 ) ( FIG. 5) is or are attached to a floating system. 2. Device according to claim 1, characterized in that the wind turbines are as close as possible above the Sea surface, in extreme cases lined up uniformly at one level, are arranged. 3. Device according to claim 1, characterized in that the wind turbines are symmetrical to the center (position on halfway between the floats) of the floating system are arranged. 4. The device according to claim 1, characterized in that several wind turbines side by side, across the Wind direction are arranged. 5. The device according to claim 1, characterized in that in extreme operating conditions of the WEAs the special parking position ( Fig. 1 and Fig. 4) u. [7], which can only be realized by wind turbines with a two-blade rotor [4]. The two-bladed rotors assume a horizontal rotor position. Two-blade rotors from Pitch-WEAs [4] u. [7] also take the flag position. 6. The device according to claim 1, characterized in that the entire structure on at least two in parallel, or due to flow-related and to be fulfilled Requirements approximately parallel, arranged floating body based. 7. The device according to claim 1, characterized in that by anchoring with two chains or comparable fasteners, a passive wind direction tracking of the overall system is given. 8. Device according to one of the preceding claims, characterized in that on the ship or. Buoyancy bodies [( 3 ) Fig. 3] ship rudders or ship propulsion systems are attached. 9. Device according to one of the preceding claims, characterized in that the wind turbine arrangement combination Luv and or Lee (for reasons of fluidic optimization of the Overall system) is selected (because with alternating arrangement of wind and  Lee wind turbines change the direction of rotation for a given direction of rotation Single WEAs). 10. Device according to one of the preceding claims, characterized in that the pitch WEAs [4] used are optional can be replaced by a) flap wind turbines [6], b) stable wind turbines, c) speed-resistant and speed-free wind turbines, and d) other not under patent law protected WEAs for grid parallel and / or island operation. 11. Device according to one of the preceding claims, characterized in that a platform for holding devices, for example in connection with hydrogen production is. 12. Device according to one of the preceding claims, characterized in that monitoring via satellite radio or Comparable is realized.