• 专利附录
  • 专利说明
  • 权利要求
  • 类似技术
  • 同族专利
  • 引用文献
  • 法律状态
  • 优先权
    • 专利摘要:
    In a method and apparatus for controlling the operation of a powertrain of a power plant with an electric machine (6, 16, 24) connected to a network (10, 19, 28), which is powered by a frequency converter (7, 8, 17, 25) with a DC intermediate circuit and optionally a transformer (9,18, 27) connected to a power grid (10, 19, 28), the brake (20) is an electrodynamic brake, which during the braking process from the DC intermediate circuit of the frequency converter (7, 8 ; 17; 25) is powered.
    公开号:AT514170A1
    申请号:T232/2013
    申请日:2013-03-28
    公开日:2014-10-15
    发明作者:Gerald Dipl Ing Hehenberger
    申请人:Gerald Dipl Ing Hehenberger;
    IPC主号:
    专利说明:

    I
    The invention relates to a work string of an energy production plant and a method for regulating the operation of a drive train of an energy production plant.
    The technical development in the field of wind turbines leads u.a. to ever larger rotor diameters and tower heights. This causes large power fluctuations due to e.g. Mains fault or strong gusts of wind a correspondingly large deflection on the tower, which in turn leads to high loads on the system. For this reason, e.g. Wind turbines, which usually use three-phase generators in combination with full inverters for realizing a variable rotor speed, are connected with large resistors via so-called choppers to the DC intermediate circuit of a full converter so that the load on the rotor is maintained in the event of spontaneous loss of the load (eg in the event of a network fault) and thus a fast one Adjustment of the rotor blades can be avoided. A rapid adjustment of the rotor blades would be necessary in case of sudden load loss to avoid an overspeed of the rotor, but would lead to a correspondingly large change in the rotor thrust and thus heavily load the tower. This problem increases the higher the tower is. Similar problems can also be found in e.g. Hydroelectric plants occur by e.g. in the case of long-lasting network faults, the turbine goes into overspeed due to lack of load, which may be would cause damage to them. Likewise, for drives for industrial applications, there are operating states in which e.g. Power failure for a short period of a drive or driven side braking torque is required to bring the system in a safe state.
    The period of time for detecting the fault until the system is at a standstill or until the end of the power failure can take up to several seconds, which requires a correspondingly large dimensioning of the abovementioned resistors.
    However, the method described for systems with full inverters can not be realized with classic differential systems, since in these cases the generator is connected directly to the grid. The same applies u.a. also for so-called double-fed three-phase machines. 2.27
    The object of the invention is therefore to solve this problem.
    This object is achieved with a drive train having the features of claim 1.
    This object is further achieved by a method having the features of claim 18.
    By applying a brake behind the rotor of the power plant, the power for which is taken from a DC link of the frequency converter for excitation and which can introduce a braking torque into the driveline, may be applied e.g. Wind turbines react to the pitch system delayed, resulting in a correspondingly slow change in the thrust of the system and thus the burden is kept as small as possible, in particular the tower or the structure of the structure.
    In a preferred embodiment of the invention, the brake is a service brake and in the drive train, an emergency brake is additionally arranged. With the brake as a service brake so that the repeated operation of the usually not dimensioned for this purpose emergency brake, especially in case of frequent power failure can be avoided.
    Preferred embodiments of the invention are subject of the dependent claims.
    Hereinafter, preferred embodiments of the invention will be explained with reference to the accompanying drawings. It shows:
    1 shows the drive train of a wind turbine with a permanent magnet synchronous generator, full converter and DC link chopper with resistor according to the prior art, FIG. 2 shows the drive train of a wind turbine with a differential drive, FIG.
    3 shows an embodiment of the invention in which a brake is connected to a DC intermediate circuit of the differential drive,
    4 shows a further embodiment of the invention in which the brake is connected to a DC intermediate circuit of a frequency converter 3/27 '' ': -1 ...... a double-fed three-phase machine, Fig. 5 shows a third embodiment of the invention, in which the brake is connected to a DC intermediate circuit of a frequency converter of a permanent magnet synchronous machine,
    Fig. 6 shows a realizable characteristic for a service brake system according to the invention and
    7 shows a characteristic according to the invention for a service brake system in comparison to a typical torque curve of a wind turbine.
    The power of the rotor of a wind turbine is calculated from the formula
    Rotor power = Rotor area * Power factor * Air density / 2 * Wind speed3 where the power coefficient depends on the speed of rotation (= blade tip speed to wind speed ratio) of the wind turbine rotor. The rotor of a wind turbine is designed for an optimum power coefficient based on a fast running speed to be determined in the course of the development (usually a value between 7 and 9). For this reason, when operating the wind turbine in the partial load range, a correspondingly low speed must be set in order to ensure optimum aerodynamic efficiency.
    The power consumption of the system is according to the above formula proportional to the cube of the wind speed. The thrust on the system is proportional to the square of the wind speed. Both, however, depends, inter alia. also from the set rotor blade angle. As a result, thrust and power go to zero as soon as the rotor blades are adjusted in the direction of feathering.
    Fig. 1 shows a solution for realizing the variable speed according to the prior art. The rotor 1 of the wind turbine is mounted in the machine frame with a rotor bearing 2. The rotor 1 is in most cases a so-called three-blade rotor with mostly individually adjustable rotor blades. By adjusting the rotor blades, the power consumption of the drive train of the system is regulated, or this can be turned off by adjusting the rotor blades in the direction of feathering as possible stress-free. At 4/27 " 4 , "r ..... to shut down the system safely, the rotor blades are usually adjusted individually, creating a required redundancy and thus the rotor blade adjustment also serves as an emergency brake.
    As a result, the rotor 1 drives the main transmission 3. This main gear 3 usually consists of two planetary and one spur gear. Here, however, there are a variety of variants in terms of number and type of gear stages. The high-speed side of the main transmission is usually by means of a coupling 5 with the generator 6, e.g. a permanent-magnet-excited low-voltage synchronous machine, connected. For safety reasons, in addition or as an alternative to rotor blade adjustment, there is an emergency brake 4, which in most cases is arranged between the main transmission 3 and the generator 6 and which can also be designed only as a holding brake (for example for maintenance work). The emergency brake 4 is usually a non-positive device, e.g. a disc brake, but may also be used as a positive locking device, e.g. be designed as a rotor lock. In addition, the emergency brake 4 may also be positioned between the rotor 1 and the main transmission 3 or in front of or behind the generator 6. The main function of this emergency brake 4 is to bring the plant safely in the event of a fault or for the protection of persons, preferably in combination with the above-mentioned rotor blade adjustment. Thus, the emergency brake 4 is a self-sufficient protection device, which (based on the valid standards) usually no other operating functions may take over. The rotor blade adjustment, which is not shown graphically, theoretically alone can fulfill the function of the emergency brake 4, which would not be necessary in this case. The generator 6 is connected via a frequency converter with a rectifier 7 and an inverter 8 and a transformer 9 to the medium-voltage network 10. With the DC link connecting the rectifier 7 and the inverter 8, a so-called chopper 12 is connected to a resistor 11.
    In the examples of FIGS. 1 to 3, the rotor 1 with a rotor bearing 2, the main gear 3, an emergency brake 4, the clutch 5 and the generator 6 are the essential components of a so-called drive train. In plants for the production of energy from ocean currents, hydropower turbines, or industrial working machines or pumps, the drive train may be similarly constructed, but must be e.g. Do not have components such as the main transmission 3 or may have other components.
    Due to a fault in the drive train, or in an operational quick or emergency stop the system or in a network failure or failure of the generator 6 can no longer reduce power and there is a power dip. Thus, the torque driving the rotor 1 would cause the driveline of the system to overspeed. In order to prevent damaging speeds for the system, one could theoretically activate the emergency brake 4, which is designed in most cases as a disc brake. In the case of a weak network 10, however, this often fails, which in any case also leads to a power dip. For safety reasons, therefore, the use of the emergency brake 4 is not permitted for this recurring operating state. Therefore, in systems according to the prior art, the overspeed is prevented by rapid adjustment of the rotor blades, whereby activation of the emergency brake 4 can be avoided. A major disadvantage of this method is that this also reduces the thrust acting on the system accordingly quickly, which leads above all to a high load on the tower of the plant. Another disadvantage would be that it may take a relatively long time for short-term power failure, which is a power failure with short-term nominal voltage - LVRT called short, until the system comes back to the power level produced before the occurrence of this network error, since the rotor blade adjustment back to the original Working position, which sometimes takes longer than required by the current grid feed-in regulations.
    For this reason, in the prior art systems, the chopper 12 and the resistor 11 are now dimensioned so that they can absorb the rated power of the system for several seconds and convert it into heat. The resulting advantage is that the torque on the drivetrain can be maintained for the time being and thus no rapid rotor blade adjustment is required, which also does not change the thrust acting on the system abruptly. In addition, when power returns the power delivered into the network can be quickly up-regulated again, because then instantly the inverter 8 can return power into the Metz, while the chopper simultaneously regulates the energy released into the resistors. Ideally, this will be the 6/27
    Drivetrain pending torque during a brief mains voltage dip constant.
    Fig. 2 shows an embodiment of a wind turbine with electromechanical differential drive according to the invention. Here again, the drive train of the wind turbine fundamentally begins with the rotor 1 with its rotor blades and ends with the generator 13. Also here, the rotor 1 drives the main gear 3 and subsequently the planet carrier of the differential gear 14. The generator 13 is connected to the ring gear of the differential gear 14 and its pinion with the differential drive 16. The differential gear 14 is in the example shown 1-stage and the differential drive 16 is in coaxial arrangement to both the output shaft of the main transmission 3, as also to the drive shaft of the generator 13. In the embodiment shown, a hollow shaft is provided in the generator 13, which allows the
    Differential drive 16 is positioned on the side facing away from the differential gear 14 side of the generator 13. As a result, the differential stage is preferably a separate, connected to the generator 13 assembly, which is then preferably connected via an emergency brake 4 and a clutch 5 to the main transmission 3. The same applies analogously to the emergency brake 4 as was already explained in the explanation of FIG. The connecting shaft 15 between
    Differential gear 14 and differential drive 16 is preferably in a particularly low moment of inertia variant than e.g. Fiber composite shaft with glass fiber or carbon fiber or a combination of both materials, in which different sections of the shaft have different materials executed. The differential drive 16 is connected by means of a frequency converter 17 and a transformer 18 to the medium-voltage network 19. An essential advantage of this concept is that the generator 13, preferably a third-party medium-voltage synchronous generator, can be connected to the medium-voltage network 19 directly, that is to say without elaborate power electronics. The compensation between variable rotor speed and fixed generator speed is realized by the variable-speed differential drive 16, which has an output of preferably about 15% of the total system power.
    The torque equation for the differential drive is: 7/27 '' ' ,, t, :: on ; R ... ·· "
    Drehmomentnifferenzial_An, rubbed = torque R0t0r * y / x, wherein the size factor y / x is a measure of the gear ratios in the main gear 3 and in the differential gear 14. The torque in the differential drive 16 is always proportional to the torque in the entire drive train.
    A disadvantage of this concept in contrast to the system concept according to FIG. 1, however, is that, for example, power failure or LVRT, the generator 13 can no longer feed power into the network 19. Thus, the torque would bring the rotor 1 and the drive train of the system in overspeed, unless the rotor blade adjustment system reacts promptly and quickly. üm to overcome this disadvantage ^ is a service brake 20 is installed between the main gear 3 and the differential gear 14. In the example shown, this is between the emergency brake 4 and the clutch 5, but it can optionally be positioned anywhere in the drive train. The advantage of the positioning between the main gear 3 and the differential gear 14 is that here the braking torque acts on the high-speed shaft of the transmission and thereby the lowest possible torque is present. In addition, the braking forces divide in accordance with the mass moment of inertia, which causes a large part of the braking torque acts on the rotor 1 via the main gear 3. Thus, the generator 13 and the differential drive 16 through the braking operation as small as possible torque load. This is not the case when the service brake is e.g. is connected to the rotor shaft of the generator 13 and the differential drive 16 must thus hold against the introduced by a service brake 20 braking torque. According to the invention, this variant, which is shown schematically in Fig. 3, but not excluded. The purpose of the service brake 20 is comparable to that of the chopper 12 and the resistor 11 of FIG. 1, namely that it can only partially absorb and convert the rated power of the system for a few seconds, or if sufficient, and convert it into heat. The resulting advantage is also here that torque on the drive train can be maintained for the time being and thus no fast rotor blade adjustment is required, which also does not change the thrust acting on the system abruptly. 8.27
    If necessary, the system controller first detects whether there is a power failure or a short-term network fault (a so-called LVRT error), in which the system should or must remain on the grid. Depending on the technical grid feed conditions, this takes a period of about 0.5 to 3 seconds, during which, ideally, the rotor blades are not significantly displaced. Thus, in the event of a sudden return of the network, the power to be supplied to the network can be upshifted very quickly by reducing the power dissipated by the service brake 20. Performance is reduced accordingly rapidly. Ideally, the service brake 20 is to be controlled so that the torque acting on the rotor 1 from the drive train remains substantially constant over this period or at least is so high that an overspeed of the rotor 1 is prevented. This works much faster than would be feasible by adjusting the rotor blades. If this is not the case and there is another error, the system can be switched off slowly. For example, such a turn-off operation may take up to 15 seconds during which correspondingly large amounts of energy are dissipated, e.g. have to be converted into heat. In this case, the torque acting on the rotor 1 from the drive train is regulated to zero after approximately 3 to 5 seconds, preferably after at most 7 seconds, but ideally in order to limit the thermal load.
    In summary, it should be noted that the main function of the service brake 20 is the limitation of the rotor speed and / or the generator speed, as this is a fast adjustment of the rotor blades largely no longer necessary. In contrast, the emergency brake 4 aims at a shutdown (rotor speed in about 0 min-1) of the system.
    For an electrodynamic retarder as service brake 20, e.g. an eddy current brake, are e.g. two steel discs (rotors), which are not magnetized, connected to the drive train. In between lies the stator with electric coils. When power is applied by activation of the retarder, magnetic fields are generated which are closed by the rotors. The opposing magnetic fields then generate the braking effect. The resulting heat is e.g. discharged through internally ventilated rotor discs again. 9.27
    An essential advantage of a retarder as service brake 20 is its freedom from wear and good controllability. Thus, the braking torque can be adjusted or optimized depending on the operating state of the system, or over the course of a braking maneuver. The torque in the retarder is preferably regulated so that when power returns the power fed by the generator 13 into the network 19 at least the minimum requirements of the prescribed grid feed conditions.
    Fig. 3 shows a differential drive according to another embodiment of the invention. In the example shown, the service brake 20 is connected to the rotor shaft of the generator 13. The service brake 20 is designed here as an electrodynamic retarder. The power for the excitation of the service brake 20 is taken from a DC intermediate circuit of the frequency converter 17. Thus, the differential drive 16 additionally acts as a brake. By means of a controllable semiconductor bridge 21, preferably IGBT-based, the exciting current for the retarder 20 can be regulated according to the required braking torque. The required braking torque for the service brake 20 depends on the operation of the plant. In wind turbines this can according to the description of Fig. 2 to reach about the height of the rated torque of the drive train, but can be higher if necessary. With optimum coordination between the rotor blade adjustment, the permitted overspeed for the components of the drive train and the braking torque of the service brake, the required braking torque for the service brake 20, however, also be much lower.
    The driveline braking torque is distributed to the rotor shaft of the generator 13 and the differential drive 16 according to the ratio of the differential gear 14. At a gear ratio of e.g. 5, the braking torque acting on the drive train increases by approximately 20% compared to a retarder positioned as in FIG. 3.
    In addition, the system shown in Fig. 3 is very easy to control. According to the invention, the frequency converter 17 can be designed and operated as described in WO 2010/121783 A or WO 2013/020148 A and have an electrical energy store or a chopper with a resistor in the intermediate circuit. This is also for the 10/27
    Energizing the electrodynamic retarder 20 necessary energy available at any time, which allows the use of the service brake 20, regardless of the state of the network 19.
    The object of the scheme is to prevent an overspeed of the drive train, at the same time, e.g. in the LVRT case, the rotational speed or the phase angle of the generator 13 can be kept constant. That the differential drive 16 and the associated frequency converter 17 have to fulfill in this embodiment according to the invention two functions. First, the supply of the service brake 20 with excitation current from the DC intermediate circuit of the frequency converter 17 and secondly, the control of the speed of the generator 13 to be substantially in phase with the network 19 at power return.
    The service brake 20 can alternatively be connected to a DC intermediate circuit of a double-fed three-phase machine, as shown in Fig. 4, and wherein the rotor 23 of the generator 24 via a frequency converter 25, but the stator 26 of the generator 24 directly or by means of a transformer 27th connected to the network 28. Also in this concept, in contrast to the plant concept according to FIG. Power failure or LVRT the generator 24 no longer feed power into the network 28. Thus, the torque would bring the rotor 1 and the drive train of the system in overspeed, unless the rotor blade adjustment system reacts promptly and quickly, which, as mentioned, however, lead to a correspondingly large change in the rotor thrust and thus heavily load the tower. In order to avoid this and a separate power supply for the service brake 20, according to the embodiment of FIG. 4, the electrical power for the excitation of the service brake 20 is taken from a DC link of a frequency converter 25 for the rotor 23 of the generator 24, but may alternatively be of any other shape be connected to the power supply.
    1, wherein the service brake 20 may be arranged in the drive train in particular on a shaft 22 between the main transmission 3 and the generator 6. As Fig. 5 shows in such an embodiment, the service brake 20 may be coupled to the DC link between the DC bus and the DC bus. Α, Α W,
    Rectifier 7 and the inverter 8 of the generator 6 are connected to ensure the power supply of the service brake.
    Fig. 6 shows a typical characteristic of an electrodynamic retarder. Due to the specific design of the retarder its design characteristic can be adapted to the requirements. In operation, the characteristic curve for electrodynamic retarders can be changed by varying the exciter current.
    For example, the characteristic curve for the service brake 20 is set so as to come as close as possible to the speed / torque characteristic of the system, whereby e.g. In case of power failure, the behavior of the system is hardly changed compared to normal operation.
    At a speed equal to zero, the retarder generates no braking torque.
    Since in the case of energy recovery systems at low turbine speed even a small torque is present, but this does not create an application-specific disadvantage.
    This is shown in FIG. 7. The continuous line shows a typical torque / speed characteristic curve for a wind turbine. The point with 100% speed or 100% torque describes the nominal point of the wind turbine. By about 105% of the speed, the system settles in nominal operation at preferably constant torque. Above a speed of 110%, the torque decreases again, while up to a speed of 115%, the system is operated at a constant power. When exceeding 115% of the speed, the system is usually taken off the grid. In the operating range below the nominal point, it is attempted to get as close as possible to a cubic characteristic curve, whereby design-specific speed limits must be observed here.
    The dotted line is the characteristic of the retarder, which preferably describes a cubic line. In the middle operating point in rated operation of the plant, which is for example at about 105% of the speed, the torque line of the wind turbine intersects with the characteristic of the retarder.
    In a particularly simple embodiment, the variation of the excitation of the retarder is dispensed with and the characteristic is set so that at the intersection of the two curves a braking torque in the height of 12/27 .....
    Nominal torque of the system is achieved. Since the rotor of the wind turbine, if the rotor blade adjustment is not active, also follows a cubic characteristic, the system is kept sufficiently balanced in the event of a momentary power failure by the service brake 20. Thus, although the effect is not perfect for all operating ranges, but since a power dip in the operation of the system with high performance has a particularly damaging effect, this simplification is a good compromise between on the one hand behavior of the system in case of failure and on the other hand complexity of a service brake 20. The 6 shows the torque characteristic curve of the service brake 20 runs over a majority of the operating range approximately in the range of the torque characteristic of the wind turbine. By exact control of the excitation current, an even better match of the two characteristics can be achieved - up to a largely exact coverage of both characteristics. During operation of the system, the speed of the drive train will settle anyway on the characteristic of the service brake and thus an overspeed be prevented. The power to be delivered at power recovery can then be regulated by the power control of the system according to the requirements of the grid feed-in conditions or the specified operating conditions.
    In the described embodiment, the working machine is the rotor of a wind turbine. Instead, however rotors for the recovery of energy from ocean currents, hydropower turbines, or pumps can be used. Moreover, the embodiment of the invention is also applicable to industrial applications, e.g. to be able to brake in the event of a system malfunction in the operating mode in order to prevent an overspeed in the event of a fault. 13/27
    权利要求:
    Claims (22)
    [1]
    i 1. 'o, h, t. 12 'fc, c. Drive train of an energy recovery system with a differential gear (14) with three inputs or outputs, wherein a first drive with the drive shaft, an output with a generator (13), preferably a third-drive synchronous machine, and a second drive with a differential drive (16), wherein the differential drive (16) is an electric machine, which is connected by means of a frequency converter (17) with a DC link and optionally a transformer (18) to a power grid (19) and wherein the drive train is a brake (20), characterized in that the brake (20) is an electrodynamic brake which is connected to the DC intermediate circuit of the frequency converter (17).
    [2]
    2. powertrain of an energy production plant with a generator (6, 24) by means of a frequency converter (7, 8; 25) with a DC intermediate circuit and optionally a transformer (9, 27) to a power grid (10, 28) is connected and wherein the Drive train has a brake (20), characterized in that the brake (20) is an electrodynamic brake, which is connected to the DC intermediate circuit of the generator (6, 24).
    [3]
    3. Drive train according to claim 2, characterized in that the generator (24) is a double-fed three-phase machine and that the brake (20) to the DC intermediate circuit of the frequency converter (25) of a rotor (23) of the generator (24) is connected.
    [4]
    4. Drive train according to claim 2, characterized in that the generator (6) is a permanent magnet synchronous machine and that the brake (20) to the DC intermediate circuit of the frequency converter (7, 8) of the generator (6) is connected isr.
    [5]
    5. Drive train according to one of claims 1 to 4, characterized in that the DC intermediate circuit an electrical energy storage, e.g. a capacitor, and / or a chopper 12 having a resistor 11. 14/27
    [6]
    6. Drive train according to one of claims 1 to 5, characterized in that the brake (20) is a service brake and in the drive train additionally an emergency brake (4) is arranged.
    [7]
    7. Drive train according to claim 1, characterized in that the brake (20) in the drive train in front of the differential gear (14) is arranged.
    [8]
    8. Drive train according to claim 1 or 7, characterized in that in the drive train in front of the differential gear (14), a main gear (3) is arranged and that the brake (20) between the main gear (3) and the differential gear (14) is arranged.
    [9]
    9. Drive train according to claim 1, characterized in that the brake (20) is arranged in the drive train behind the differential gear (14).
    [10]
    10. Drive train according to claim 1, characterized in that the brake (20) in the drive train between the differential gear (14) and the generator (13) is arranged.
    [11]
    11. Drive train according to claim 1, characterized in that the brake (20) in the drive train on the side facing away from the differential gear (14) side of the generator (13) is arranged.
    [12]
    12. Drive train according to one of the claims 1 to 11, characterized in that the slope of a torque characteristic of the brake (20) in the range above the rated speed of the power generation plant is greater than the slope of a torque characteristic of the power plant.
    [13]
    13. Drive train according to one of claims 1 to 12, characterized in that the slope of a torque characteristic of the brake (20) in the region of the rated speed of the power generation plant is smaller than the slope of a torque characteristic of the power plant.
    [14]
    14. Drive train according to one of claims 1 to 13, characterized in that the slope of a torque characteristic of the 15/27 brake (20) cuts in the range above the rated speed of the power plant a torque characteristic of the power plant.
    [15]
    15. Drive train according to one of claims 1 to 14, characterized in that a torque characteristic of the brake (20) to the nominal torque of the power generation plant substantially parallel to a torque characteristic of the energy recovery system runs.
    [16]
    15. Drive train according to one of claims 1 to 14, characterized in that a torque characteristic of the brake (20) has a cubic shape.
    [17]
    17. Energy production plant, in particular wind turbine, with a drive train with a generator (13), characterized in that the drive train is designed according to one of claims 1 to 16.
    [18]
    18. A method of controlling the operation of a powertrain of a power plant with an electric machine (6, 16, 24) connected to a network (10, 19, 28) by means of a frequency converter (7, 8, 17, 25) with a DC intermediate circuit and optionally a transformer (9, 18, 27) connected to a power supply (10, 19, 28), characterized in that the brake (20) is an electrodynamic brake, which during the braking process from the DC link of the frequency converter (7, 8, 17, 25).
    [19]
    19. The method according to claim 18, characterized in that in the event of a power failure, power failure or emergency shutdown, the brake (20) is activated so that from the drive train to the rotor (1) acting torque over a period of at least 0.5 Seconds remains essentially constant.
    [20]
    20. The method according to claim 18 or 19, characterized in that from the drive train to a rotor (1) acting torque over a period of up to 7 seconds, preferably up to 5 seconds, more preferably up to 3 seconds, substantially 16 / 27 --- 1¾ remains constant.
    [21]
    21. The method according to any one of claims 18 to 20, characterized in that the braking torque of the brake (20) in a further period of 5 to 20 seconds, preferably from 10 to 15 seconds, is reduced to about zero.
    [22]
    22. The method according to any one of claims 18 to 20, characterized in that the rotational speed of a generator (6, 13, 24) of the drive train is maintained substantially in phase until a network return. 17/27
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    同族专利:
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    引用文献:
    公开号 | 申请日 | 公开日 | 申请人 | 专利标题
    DE19634464A1|1995-08-28|1997-04-03|Lothar Kloft|Eddy current retarder for wind power generator installation|
    WO2010108207A2|2009-03-26|2010-09-30|Gerald Hehenberger|Energy production plant, in particular a wind power station|
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    法律状态:
    2019-11-15| MM01| Lapse because of not paying annual fees|Effective date: 20190328 |
    优先权:
    申请号 | 申请日 | 专利标题
    ATA232/2013A|AT514170B1|2013-03-28|2013-03-28|Powertrain of an energy recovery plant and method of regulation|ATA232/2013A| AT514170B1|2013-03-28|2013-03-28|Powertrain of an energy recovery plant and method of regulation|
    DE102014104287.5A| DE102014104287A1|2013-03-28|2014-03-27|Powertrain of an energy recovery plant and method of regulation|
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