DE29623937U1 - Wind turbine - Google Patents

Description

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DESCRIPTION

The invention relates to a wind turbine with the features of the preamble of claim 1.

Wind turbines can be designed to generate electricity (as in the case of a wind turbine according to the invention) and can also be used to convert the form of energy directly into mechanical energy (as in wind pump systems, for example). Wind turbines that generate electricity have the following components: a tower (or mast) and a nacelle, which usually serves as a machine support for the machines of a so-called drive train. The tower, which varies in height depending on the design of the wind turbine, can be made of conical round steel elements or concrete ring modules. In front of the nacelle there is a rotor with its hub. The drive train, which is protected in the nacelle, includes a rotor shaft with bearings in most known systems, hydraulic units for adjusting the rotor blades, brake(s), a generator unit, - in the case of wind turbines with gearboxes - a gearbox unit, possibly with clutches, sensors for recording parameters for operating the wind turbine, and control electronics for monitoring function and operation. The arrangement and design of these components is crucial for the efficiency of the wind turbine and thus also crucial for its economic viability.

The various designs of state-of-the-art wind turbines can be classified into systems with gearboxes and gearless systems. The latter usually have a ring generator (excited by a permanent magnet or via an excitation circuit) and are characterized by the advantage of lower weight and volume.

In known horizontal-axis wind turbines of the type mentioned above, the generator unit consists of a generator, as shown schematically in Figure 1. This is usually arranged on the windward side of the tower. This makes the operation of the wind turbine easier for structural reasons.

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reasons and a possible increase in yield through more variable and better adapted investments was avoided.

The object of the invention is therefore to simplify the design of a wind turbine and to make its operation more variable in order to achieve yield optimization.

This object is achieved according to the invention by a wind turbine having the features of claim 1.

The solution according to the invention has the significant advantage that wind turbines with different performance characteristics can be equipped with one and the same generator module. This reduces the production costs of the entire system. The solution according to the invention also reduces costs because - due to the modular design - the various components of the system can be operated not only at their nominal point, but also increasingly and much more variably in the partial load range, thus achieving better yield values for the entire system.

Another important advantage is that, in addition to assembly, repair and maintenance work can also be carried out more easily, more quickly and therefore more cost-effectively. The individual modules are lighter than a complete generator based on the state of the art. This means that smaller, cheaper cranes can be used, for example. This plays an important role in practice, particularly in difficult terrain and in windy regions - e.g. in developing countries - where logistics can cause problems.

When approving wind turbines, the statics of the system, the stability, is a decisive criterion. The (undesirable) vibration behavior of the nacelle, the tower and the force-transmitting components is crucial for examining the dynamics of the system. The more compact the system, especially the nacelle, is, the more favorable the effect on the static and dynamic conditions of the wind turbine. With the inventive option of optionally

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By arranging the generator modules on the windward and/or leeward side of the tower axis, the design of the system can be adapted much better to current static requirements, which result, for example, from the vibration behavior of the overall system.

Furthermore, aerodynamic aspects, especially the nacelle, are also taken into account when optimizing the yield of a wind turbine. The latter can be optimally adapted to aerodynamic and static requirements thanks to the modular design of the generator unit, which takes up a significant percentage of the nacelle's volume.

In an alternative embodiment of the invention, the generator modules differ in their output power. Advantageously, this makes it possible to better take current environmental and wind conditions into account by taking statistically determined, most frequently prevailing wind speeds into account using appropriate generator modules designed specifically for this purpose. These can then be switched on individually and cover a specific wind condition that statistically occurs more frequently.

A significant advantage over non-modular systems based on the state of the art is that the generator modules can be switched on in stages. This increases the variability of the operation of the wind turbine and thus also its efficiency.

The drawings illustrate embodiments of the invention, namely:

Fig. 1 is a schematic representation of a horizontal-axis, gearless wind turbine according to the state of the art,

Fig. 2 is a schematic representation of a horizontal-axis, gearless wind turbine according to the invention with two generator modules,

Fig. 3 is a schematic representation of a horizontal-axis, gearless wind turbine according to the invention with three generator modules and

Fig. 4 is a schematic representation of a horizontal-axis, gearless wind turbine according to the invention with seven generator modules.

As shown in Fig. 1, a wind turbine 10 according to the state of the art has a generator unit, which is usually arranged near the longitudinal axis of the tower 14 - here on the windward side - in the nacelle 16 on the drive shaft 18. The generator unit consists of a generator module 20. The generator module 20 is designed as a disk-shaped ring generator. For wind turbines according to the state of the art with different performance requirements, differently dimensioned generator units are therefore also necessary. This in turn disadvantageously leads to additional requirements in production, transport and assembly (e.g. cranes).

The nacelle 16 serves as a support for the machines of the drive train 26 and is preferably a cast construction which is soundproofed from the environment, so that noise insulation of the machines, in particular of the gearbox in wind turbines with gearboxes, is achieved.

The height of the tower 14 is determined from the desired hub height of the rotor 22 and this from the desired diameter of the rotor 22 depending on the desired output of the wind turbine 10 and the location-specific wind supply (wind profile). The height of the tower 14 can therefore vary between a few meters and approximately 100 meters.

The wind turbines 10 according to the invention in the drawings 2 to 4 differ - depending on the size of the wind turbine 10 - in the number of generator modules 20 and thus in the output power of the wind turbine 10. The following sections of the detailed description of the figures therefore refer in summary to a wind turbine 10 of the type according to the invention, regardless of the number of generator modules 20.

The operation of the wind turbine 10 depends on several parameters, some of which are recorded by sensors: such as the rotational speed, the wind speed, the power of the generator modules 20, the temperature of the generator modules 20, the vibration behavior of the system, parameters of hydraulic components of the wind turbine 10 (such as oil pressure and temperature) and the current position of the rotor blades 24 in the wind in pitch-controlled wind turbines. The ability to adjust the rotor blades 24 (in pitch-controlled wind turbines 10) enables different flow conditions; this allows the power output of the rotor 22 to be adjusted, e.g. so that it is constant once the nominal power is reached.

The operation of the wind turbine 10 is controlled by a control unit 30. In an advantageous embodiment, the control unit 30 can be flexibly adapted to changing requirements on the part of the operation of the wind turbine 10. All necessary parameters for the control can be automatically recorded and calculated via sensors or can optionally be determined by an operator of the wind turbine 10 and entered into the control unit 30, in particular the number, type and order of connection of the individual generator modules 20. Depending on the operating hours of the individual generator modules 20 and their wear, certain generator modules 20 can be preferred or deferred in individual cases.

An alternative embodiment of the wind turbine 10 according to the invention is a modular wind turbine with so-called "stall control", in which the power limitation is achieved by the flow separation on the non-adjustable blades of the rotor 22.

In the preferred embodiment of the invention, the generator modules 20 - depending on the programming of the control unit 30 - can all be connected to the grid simultaneously or separately from one another via one or more frequency converters. If the generator modules 20 are of the same construction and are connected to the grid simultaneously, the load is distributed symmetrically, which has a positive effect on the even distribution of the service life of the generator modules 20. The efficiency of the wind turbine 10 also advantageously increases through

Use of several generator modules 20 with lower power, since such "smaller" generator modules 20 are more likely to be operated in the nominal range and fully utilized and thus achieve better efficiencies.

In this embodiment of the invention, the generator modules 20 are disk-shaped ring generators that are arranged coaxially on the drive shaft 18. This results in a clear, simple structure that facilitates maintenance and repair work. This is particularly advantageous for transport and assembly work on the wind turbine 10, since each generator module 20 can be transported individually and "plugged" onto the drive shaft. This results in smaller generator dimensions and masses for transport and assembly, which significantly simplifies logistics and requires much smaller cranes than if only one bulky and heavy generator is used, as in wind turbines according to the state of the art.

In an alternative embodiment, the generator modules 20 are arranged at a distance from one another on the drive shaft 18. This increases the axial length of the nacelle 16 only minimally, but allows the individual generator modules 20 to have an improved heat dissipation option and can also be serviced more easily. Depending on the arrangement of the components of the drive train 26, a main bearing 28 for the drive shaft 18 is arranged within the nacelle 16.

By increasing the number of generator modules 20 to more than two, the utilization options for the wind turbine 10 are significantly better than with the prior art. Furthermore, the efficiency of the entire wind turbine 10 is increased because smaller generator modules 20 can be manufactured more precisely (air gap tolerance, bearing tolerances, imbalance, etc.).

By gradually and successively connecting individual generator modules 20, the wind turbine 10 is optimally adapted to frequently changing and/or varying wind speeds. The control unit 30 is preferably designed so that the

Generator modules 20 that are not connected to the grid rotate freely and advantageously act as mechanical damping in the event of strongly changing wind speeds and thus strong fluctuations in the performance of the generator modules 20. A further advantage is that the variability of the operational management is increased by an increased number of options and thus an increased uniformity of energy generation (power feed-in) can be achieved by a more differentiated adjustment of the wind turbine 10.

Further advantageous alternative embodiments of the invention arise from the different arrangement options for the generator modules 20 on the drive shaft 18. One possibility is to arrange the generator modules 20 only on the leeward side (not shown) and to simultaneously use the weight of the generator modules 20 as a counterweight to the weight of the machine parts located on the windward side of the tower (e.g. rotor), in order to provide a statically balanced wind turbine 10. An alternative embodiment is to arrange the generator modules 20 - depending on the design requirements and the desired operation of the wind turbine 10 - both on the windward and leeward side of the longitudinal axis of the tower 14. This results in the further advantages that a more balanced construction of the system, in particular the nacelle 16, is made possible and the mass of the generator modules 20 simultaneously functions as a counterweight to other machines in the drive train 26, such as the rotor 22, in order to shift the nacelle's center of gravity towards the central longitudinal axis of the tower. Due to the modular design, the wind turbine 10 according to the invention - as just shown - can more easily find a balance between the static (dead weight of machines and nacelle, etc.) and quasi-static (air forces from the average wind, centrifugal forces, etc.) forces with a more variable arrangement of the modules of the drive train 26 without additional counterweights, which in themselves have no function for the wind turbine and only serve to compensate for the statics.

As in the previously described embodiments of the wind turbine 10 according to the invention, in a gearless system the operating frequency of the generator modules 20 is determined by a frequency converter. Alternatively

For this purpose, in an inventive design of a wind turbine 10 with a gearbox, preferably one gearbox or several gearbox modules can convert the rotor speed to the nominal speed of the generator modules 20. Here, susceptibility to errors of the electronic components required in gearbox-free systems is avoided and shifted to the mechanical area of the gearbox.

In the drawings, the drive shaft 18 is arranged horizontally. In a modification not shown, the drive shaft 18 extends vertically.

The wind turbine 10 is not necessarily limited to one drive shaft 10, but can also have two or more drive shafts in horizontal and/or vertical arrangement.

Claims (12)

1. Wind power plant for generating electricity, comprising a tower ( 14 ), a nacelle ( 16 ), a rotor ( 22 ), at least one drive shaft ( 18 ), a control unit ( 30 ) and a generator unit, characterized in that the generator unit is of modular construction and comprises several generator modules ( 20 ) and that the control unit ( 30 ) enables the selective connection of individual generator modules ( 20 ). 2. Wind power plant according to claim 1, characterized in that the generator modules ( 20 ) are ring generators. 3. Wind power plant according to at least one of the preceding claims, characterized in that the generator modules ( 20 ) are arranged on the windward and leeward sides of the tower ( 14 ). 4. Wind power plant according to at least one of the preceding claims, characterized in that the individual generator modules ( 20 ) differ in their power consumption. 5. Wind power plant according to at least one of claims 1 to 3, characterized in that the individual generator modules ( 20 ) are constructed identically. 6. Wind power plant according to at least one of the preceding claims, characterized in that the control unit ( 30 ) calculates the connection of certain generator modules ( 20 ) automatically or semi-automatically by means of integrated intelligent electronics. 7. Wind power plant according to claim 6, characterized in that the control unit ( 30 ) calculates the connection according to the following parameters: wind speed, rotational speed, power of the generator module ( 20 ), temperature of the generator module ( 20 ) and further monitoring parameters of the wind power plant ( 10 ). 8. Wind power plant according to at least one of the preceding claims, characterized in that the control unit ( 30 ) controls the connection of the generator modules ( 20 ) in dependence on one another. 9. Wind turbine according to at least one of the preceding claims, characterized in that the wind turbine ( 10 ) is constructed without a gear. 10. Wind power plant according to at least one of claims 1 to 8, characterized in that the generator unit consists of generator modules ( 20 ) and the transmission unit consists of associated transmission modules. 11. Wind power plant according to one of claims 1 to 10, characterized in that it has several drive shafts ( 18 ) on each of which generator modules ( 20 ) are mounted. 12. Wind power plant according to one of claims 1 to 11, characterized in that the drive shaft ( 18 ) or drive shafts ( 18 ) are arranged vertically.