WO2003025391A1

WO2003025391A1 - Area sub-division of a wind-energy farm

Info

Publication number: WO2003025391A1
Application number: PCT/EP2002/009802
Authority: WO
Inventors: Jin Shen; Thomas Grieser
Original assignee: Abb Research Ltd.
Priority date: 2001-09-14
Filing date: 2002-09-03
Publication date: 2003-03-27
Also published as: DE10145346A1

Abstract

The invention relates to a wind-energy farm (1) comprising a plurality of wind-energy turbines (2), which are connected to electric generators (12), whose electric output voltages are supplied to an interconnected network (18). In known wind-energy farm systems (1), the electric networks are entirely or partially configured in a tree and/or ring structure. The electric lines (8, 15, 21 and 23) are dimensioned according to the maximum current of all generators (12) and are thus over-dimensioned. The inventive wind-energy farm is sub-divided into rectangular or hexagonal areas (3, 5), which are combined into segments (4, 6) with a star-shaped structure. A respective wind-energy turbine (2) is installed at the centre of said areas (3, 5). The a.c. voltages supplied by the generators (12) of the segments (4, 6) are converted into d.c. voltages and are fed via a common line for high-voltage d.c. transmission (15) to an inverter (16), which is connected to a network link point of an interconnected network (18). The a.c. voltage outputs of all generators (12) of each segment (4, 6) can also be connected to a transformer (10). If this is the case, all transformers (10) of all segments (4, 6) are connected to a rectifier (13), whose output voltage is fed via a line for high-voltage d.c. transmission (15) to an inverter (16), which is connected to a network link point of an interconnected network (18).

Description

WINDPARK FLAT SUBDIVISION

The invention relates to a wind farm system according to the preamble of patent claim 1.

Such a wind farm system is preferably used in the generation of electrical energy with the aid of wind turbines.

Up to now, wind farm systems are known in which the entire site is divided into individual areas. A wind turbine is arranged on each of these surfaces. These areas are dimensioned so that a prescribed minimum distance between immediately adjacent wind turbines is maintained. The electrical networks of these wind farm installations are entirely or partially constructed in a tree and / or ring structure. The lines of these networks are dimensioned according to the maximum current of all wind power generators. They are therefore oversized over a large part of their length. The electrical networks, including their connections to a network, are designed as three-phase AC systems. The distances between the wind farm facilities and the interconnected networks into which the energy is to be fed are becoming ever greater. However, three-phase AC systems have considerable electrical losses, especially at long distances. The generators used to form the wind turbines usually have an output voltage of 690V. A transformer is therefore connected downstream of each electrical output of such a generator.

The invention is therefore based on the object of demonstrating a wind farm installation in which the available area is used optimally and the electrical network is designed such that a maximum of electrical energy can be fed into a network with a minimum of components.

This object is achieved by the features of patent claim 1. According to the invention, the wind farm is divided into areas which are designed as regular rectangles or hexagons. The dimensions of all rectangular or hexagonal surfaces are the same size. A wind turbine is arranged in the center of each surface. Each wind turbine is provided with a rotor, which is formed by a rotatable drive shaft, on which several blades are attached at a distance all around. The smallest distance from the center of a surface to the center of all immediately adjacent surfaces corresponds to 5 to 15 times the diameter of such a rotor. The diameter of the rotor corresponds to the diameter of a circle that the free ends of the wings describe.

A defined number of these areas is combined into a segment. Preferably, seven hexagonal areas or nine rectangular areas are combined to form a segment. With this arrangement, better utilization of the wind farm facility is possible. In addition, it is achieved that each of these segments has a star-shaped structure, and a wind turbine is always arranged in the center of each segment. The outer wind turbines can then be connected in a star shape with this wind turbine. If a line is interrupted within one of these segments, only the electrical energy supplied by a wind turbine fails. This means that the wind farm has high availability. In addition, electrical lines can be used, the cross-sections of which are substantially smaller than comparable electrical lines in known wind farm systems. However, the amount of electrical energy that can be transported through the lines of the wind farm installation according to the invention is not less than in known devices of this type. When the wind farm facility is divided into hexagonal surfaces, the same number of wind turbines is installed on rectangular surfaces 13% less space is required. With this solution, more electrical power can be obtained per square meter. A transformer for each wind turbine is not required because the wind turbines are connected to electrical generators that deliver an output voltage up to 25kV. In the wind farm system according to the invention, direct current technology is also used in order to minimize transmission losses and to improve the quality of the electricity. The star structure of the segments also enables exact dimensioning of all operational medium, avoids oversizing and minimizes costs. The spatial subdivision of the wind farm in combination with a star-shaped connection of the wind turbines also minimizes the transmission losses, since only short cable routes on the lower voltage levels and high voltages are required for the large outputs to be transmitted.

Further inventive features are characterized in the dependent claims.

The invention is explained in more detail below with the aid of schematic drawings.

Show it:

1 is a wind farm, which is divided into hexagonal areas,

2 shows a wind farm system which is divided into rectangular areas,

3 shows the electrical networking of a wind farm installation with hexagonal surfaces,

4, the electrical networking of a wind farm with rectangular areas,

5 shows a variant of the networking shown in FIG. 3,

6, a variant of the networking shown in FIG. 4,

7 shows the electrical networking of 91 wind turbines,

8 the electrical networking of 108 wind turbines,

9 the electrical connection of a wind farm to a network by means of tel voltage or high voltage direct current transmission, 10 shows a medium-voltage direct current transmission within the wind farm installation and a medium-voltage or high-voltage three-phase transmission between the wind farm installation and a network.

11 shows a variant of the electrical connection of a wind farm installation to a network shown in FIG. 10,

12 shows a further electrical connection of a wind farm to a network.

1 shows a wind farm installation 1 with a plurality of schematically illustrated wind turbines 2. The entire surface of the wind farm installation 1 is divided into seven hexagonal surfaces 3, which are combined to form a segment 4. A wind turbine 2 is arranged in the center of each surface 3. The vertical distance between two immediately adjacent wind turbines 2 is selected such that it corresponds to 5 to 15 times the rotor diameter d _{R of} a wind turbine 2. Each wind turbine is provided with a rotor (not shown here), which is formed by a rotatable drive shaft, on which several blades of equal length are attached all around at a defined distance. All wind turbines 2 are the same size. The size of a hexagonal surface 3 thus results from the equation F = 3/4 (k _A * d _R ) ² , where k _A. is a number between 5 and 15, which varies depending on the local conditions of the wind farm. The size of each segment 4 is determined by the size of the seven times the area F.

FIG. 2 shows a wind farm installation 1 which, in contrast to the wind farm installation 1 shown in FIG. 1 and explained in the associated description, is divided into rectangular areas 5 of the same size. Each nine rectangular surfaces 5 are combined to form a segment 6. A wind turbine 2 is arranged in the center of each surface 5. Here, too, the vertical distance between the center of a surface 5 and the center of each immediately adjacent surface 5 is selected such that it corresponds to 5 to 15 times the rotor diameter of a wind turbine 2. All wind turbines 2 are also of the same size here. The size of each surface 5 thus results from the equation F = (k _A * dp) ² . Here too, the wind farm 1 in Aonangιgκeιt be divided into a corresponding number of segments 6 from the total area available.

A wind farm installation 1 with four segments 4 is shown schematically in FIG. 3. Six wind turbines 2 of each segment 4 are connected to the centrally arranged seventh wind turbine 2 via electrical lines 8. The electrical output of each central wind turbine 2 of each segment 4 is connected to a transformer 10. In the exemplary embodiment shown here, a defined number, as shown, in each case four transformers 10, are electrically connected to a further transformer 11 in order to achieve a higher voltage level for energy transmission over long distances. When building any wind farm, it makes sense to decide with the help of a profitability test whether such additional transformers 11 are required.

FIG. 4 shows a wind farm installation 1 with four segments 6, each of which comprises nine wind turbines 2. Here, too, eight wind turbines 2 of each segment 6 are connected to the centrally arranged wind turbine 2 of each segment 6. The electrical outputs of the centrally arranged wind turbines 2 are each connected to a transformer 10 in the same field. In this exemplary embodiment, a defined number of transformers 10 can also be connected to a further transformer 11 in order to achieve a higher voltage level for energy transmission over long distances.

5 and 6 each show four immediately adjacent segments 4, 6. In each segment 4, 6, the six or eight external wind turbines 2 of a segment 4, 6 with the respective central wind turbine 2 of the associated segment 4, 6 e - be connected electrically. Each central wind turbine 2 of a segment 4, 6 is followed by a transformer 10. The transformers 10 three of these segments 4, 6 are electrically conductively connected to the transformer 10 of the fourth segment 4, 6. If necessary, this fourth transformer 10 can be connected to a transformer 11 (not shown here), as shown in FIGS. 3 and 4 and explained in the associated descriptions. Fig. 7 shows a wind farm 1 with 91 wind turbines 2, which are arranged on the hexagonal surfaces of 13 segments 4, 40. In order to have to lay only the shortest possible electrical lines 8 within the wind farm installation 2, the six external wind turbines 2 of a segment 4 are connected to the centrally located wind turbine 2 of this segment 4 via electrical lines 8. The centrally located wind turbines 2 of the segment 4 are connected to a transformer 100 via a transformer 10. This is connected downstream of a transformer 10 of a wind turbine 2, which is arranged in a central segment 40, which is surrounded by six segments 4. The wind turbines 2 of five further segments 4, 40 are electrically connected in the same way. The wind turbine 2 of the second segment 40 is followed by a transformer 10, which is also in electrical connection with the transformer 100. With the aid of the transformer 100, the voltage is transformed to such an extent that the electrical energy of the wind farm installation 1 can be fed into a network (not shown here) as efficiently as possible. Here, the geographical arrangement of the transformer 100 within the wind farm installation 1 can vary based on the local conditions.

8 shows a wind farm system 1 with 108 wind turbines 2, which are distributed over rectangular areas 5 of 12 segments 6, 60. Here, too, the wind turbines 2 are interconnected according to the same scheme as the wind turbines 2 shown in FIG. 7 and explained in the associated description.

FIG. 9 shows the electrical connection of the wind turbines 2 of segments 4, 6, as shown in FIGS. 2 and 3 and explained in the associated descriptions. In the embodiment shown here, however, only two of the seven or nine wind turbines 2 of a segment 4, 6 are shown. The drive of each wind turbine 2 is mechanically connected to a generator 12, which supplies a three-phase AC voltage from 0.69 kV to 25KV. The output of each generator 12 is connected to a rectifier 13. The outputs of the rectifiers 13, which belong to the seven or nine wind turbines 2 of each segment 4, 6, are connected in parallel and connected to a common DC voltage converter 14 connected, the output of which provides a DC voltage between 10kV and 150kV. The DC-DC converter 14 corresponds to the transformers 10 shown in FIGS. 3 to 6. All the DC-DC converters 14 are connected to a network coupling point of a network 18 via a common transmission line 15 for high-voltage DC. An inverter 16 is connected upstream of this. A transformer 17 can also be connected between this inverter 16 and the network coupling point of the interconnected network 18 if this is technically necessary.

10 also shows the electrical connection of wind turbines 2 of two segments 4, 6, as shown in FIGS. 2 and 3 and explained in the associated descriptions. In the embodiment shown here, however, only two of the seven or nine wind turbines 2 of a segment 4, 6 are shown. The drive of each wind turbine 2 is mechanically connected to a generator 12, which supplies a three-phase AC voltage between 0.69kV and 25KV. The output of each generator 12 is connected to a rectifier 13. The rectifiers 13 of seven or nine wind turbines of each segment 4, 6 are connected to an inverter 19 which is followed by a transformer 10. The transformers 10 correspond to the transformers 10 shown in FIGS. 3 to 6. The inverters 19, like the transformers 10, are installed in the vicinity of the respective central wind turbine 2 of each segment 4, 6. All transformers 10 are connected in parallel and connected via long three-phase lines 23 to a distant transformer 22, the output of which is connected to a network coupling point of a network 18.

11 shows the transmission of the electrical energy from the wind turbines 2 to a network coupling point of a network 18 in the form of three-phase current. Here too, only two out of seven or nine wind turbines 2 of two segments 4, 6 are shown for illustration. The outputs of the generators 12 of the wind turbines 2 of a segment 4, 6 are connected to a transformer 10, with the aid of which the output voltages of the generators 12 can be transformed from 0.69kV to 25KV to a higher voltage of, for example, 10kV to 150 kV. All Transformers 10 are connected via three-phase AC voltage lines 21 to a further transformer 22, with the aid of which the voltage present at its input is increased to, for example, 100 kV to 500 kV and forwarded via three-phase lines 23 to a network coupling point of a network 18.

12 also shows the transmission of the electrical energy from wind turbines 2 to a network coupling point of a network 18. The alternating voltage outputs of the generators 12, to which the wind turbines 2 of each segment 4, 6 are mechanically connected, are connected to a transformer 10. Such a transformer 10 is assigned to each segment 4, 6 and transforms the output voltages of the generators 12 to a higher voltage of 10 kV to 150 kV. The transformers 10 of all segments 4, 6 are connected to a rectifier 13, with which the AC voltages of the transformers 10 are converted into a higher DC voltage of 40 kV to 500 kV. By means of a transmission line for high-voltage direct current 15, which is connected to the output of the rectifier 13, the electrical energy is conducted to a distant inverter 16, which is connected to the network coupling point of a network 18.

Claims

claims

1. A wind farm system which is divided into areas (3, 5), at least one wind turbine (2) being arranged on each area, the rotatable drive shaft of which is mechanically connected to a generator (12), characterized in that the areas (3, 5) designed as hexagons or rectangles and a defined number of immediately adjacent surfaces (3, 5) are assigned to a segment (4, 6), and that in each case a wind turbine (2) is set up in the centers of these surfaces (3, 5) ,

2. Wind farm system according to claim 1, characterized in that the surfaces (3, 5) are designed as regular hexagons or squares, and each segment (4, 6) is provided with a star-shaped structure and with a wind turbine (2) in the center.

3. Wind farm system according to one of claims 1 or 2, characterized in that each segment (4) comprises seven hexagonal surfaces (3) and each segment (6) nine square surfaces (5), and the centers of all surfaces (3, 5) all have the same distance from the centers of all immediately adjacent surfaces (3, 5), and that the drive shaft of each wind turbine (2) is mechanically connected to a generator (12).

4. Wind farm system according to one of claims 1 to 3, characterized in that the AC voltage output of each generator (12), which is assigned to a segment (4, 6), is connected to a rectifier (13) that all rectifiers (13 ) a segment (4, 6) is followed by a common DC-DC converter (14) that the DC-DC converters (14) of all segments (4, 6) are connected via a line for high-voltage DC transmission (15) to an inverter (16) whose voltage output is via a transformer (17) is connected to a network coupling point of a network (18).

5. Wind farm system according to one of claims 1 to 3, characterized in that the alternating voltage output of each generator (12), which is assigned to a segment (4, 6), is connected to a rectifier (13), that all rectifiers (13 ) of a segment (4, 6) are connected via a series circuit consisting of an inverter (19) and a transformer (10) to a line for three-phase transmission (23), in which a further transformer (22) is integrated, the voltage output of which is connected to a Network coupling point of a network (18) is connected.

6. Wind farm system according to one of claims 1 to 3, characterized in that the AC voltage output of each generator (12), which is assigned to a segment (4, 6), is connected to a transformer (10) that all transformers (10) Are connected via a three-phase line for AC voltage (21) to a transformer (22) common to all segments (4, 6), which is connected via a line for three-phase transmission (23) to a network coupling point of a network (18).

7. Wind farm system according to one of claims 1 to 3, characterized in that the AC voltage output of each generator (12), which is assigned to a segment (4, 6), via a transformer (10) to one for all segments (4, 6 ) common rectifier (13) is connected, the voltage output of which is connected via a long line for high-voltage direct current transmission to an inverter (16) which is connected upstream of a network coupling point of a network (18).