EP3443660A1 - Installation and method for generating a three-phase ac voltage to be fed into a power supply system - Google Patents

Abstract

The invention relates to an installation for generating a three-phase AC voltage to be fed into a power supply system, having at least one turbine, at least one three-phase generator driven with the turbine, wherein a generator rotor of the three-phase generator is coupled to a turbine rotor of the turbine in a rotationally fixed manner, at least one transformer which is electrically connected to the three-phase generator on the output side and can be used to convert a first three-phase AC voltage which is generated by the three-phase generator and has a first voltage level and a first frequency into a second three-phase AC voltage having a second voltage level, which is lower than the first voltage level, and the first frequency, and at least one frequency converter which is electrically connected to the transformer on the output side and can be used to supply a rotor winding of the generator rotor with a third three-phase AC voltage and can be used to convert the second three-phase AC voltage having the second voltage level and the first frequency into the third three-phase AC voltage having the second voltage level and a second frequency which is lower than the first frequency, wherein the frequency converter is designed or can be controlled and/or regulated in such a manner that the second frequency corresponds to a difference between a mains frequency of the power supply system and the first frequency.

Description

description

Plant and method for generating a three-phase alternating voltage to be fed into a power grid

The invention relates to a system for generating a three-phase alternating voltage to be fed into a power network, comprising at least one turbine and at least one driven with the turbine alternator, wherein a Genera- torläufer the alternator rotatably coupled to a turbine runner ^¬ turbine.

Furthermore, the invention relates to a method for generating a fed into a power grid three-phase alternating voltage using at least one turbine and at least one driven with the turbine Drehstromgene ^¬ generator, wherein a generator rotor of the alternator is rotatably coupled to a turbine rotor of the turbine. Systems for generating a three-phase AC voltage and for supplying a power network with the three-phase AC voltage are well known and are used in power plants. Such a system comprises at least one turbine, for example a gas turbine of a gas and steam turbine power plant or a gas turbine power plant or a steam turbine, and at least one turbine generator driven three-phase generator, in particular turbogenerator. A turbine rotor of the turbine is conventionally rigidly connected to a generator rotor of the alternator. In order to generate by a rotation of the turbine rotor, a three-phase AC voltage with a common power frequency of 50 Hz or 60 Hz with the alternator and to be able to feed into the power grid, so the turbine rotor must therefore rotate conventionally with a frequency equal to 50 Hz or 60 Hz , As the power and efficiency of gas turbines with egg ^¬ ner operating frequency of 50 Hz (50Hz gas turbines) are larger than the corresponding 60Hz gas turbine, there is an interest, 50Hz gas turbine and for supply of Stromnet- zen with a mains frequency of 60 Hz (60Hz power supply). For example, due to the scaling approach to design, the performance of the largest 50Hz gas turbine is 44% greater than that of the largest 60Hz gas turbine. In general, with 50 Hz gas turbines, because of the lower rotational speed, an overall higher power limit than with 60 Hz gas turbines can be assumed, since the centrifugal forces acting on the turbine rotor blades can be controlled even with correspondingly longer turbine blades. The efficiency advantage of a 50 Hz gas turbine variant over a 60 Hz gas turbine variant lies with scaled gas turbines (ie one turbine variant was derived from a base turbine variant via scaling factors) at about 0.3%, in particular by the smaller gap losses in the 50 Hz gas turbine variant.

An object of the invention is the applicability of turbines, particularly gas turbines, whose operating frequency is less than a line frequency of a power grid, chen to enable electrical power to Ver ^¬ provide the power system. Another object of the invention is to improve a frequency support operation of a system for generating a three-phase alternating voltage to be fed into a power grid. A plant according to the invention for generating a fed into a current ^¬ mains three-phase alternating voltage comprising at least one turbine and at least one driven by the turbine alternator, wherein a generator rotor of the alternator is non-rotatably coupled to a turbine rotor of the turbine. According to the invention the plant comprises we ^¬ nigstens with an output side electrically connected to the Drehstromge ^¬ erator transformer, with a first three-phase AC voltage generated by the alternator a first voltage level and a first frequency into a second three-phase AC voltage having a second voltage level, which is lower than the first voltage level, and the first frequency is convertible. Furthermore, the system comprises at least one output side electrically connected to the output side

Transformer connected frequency converter, via which a rotor winding of the generator rotor with a third three ^¬ is phase AC voltage supplied and to which the second three-phase alternating voltage with the second voltage level and the first frequency in the third three-phase AC voltage with the second voltage level and a second frequency lower than the first Frequency is convertible. The frequency converter is designed or controllable and / or regulated such that the second frequency corresponds to a difference between a mains frequency of the power network and the first frequency.

Is the frequency of rotation of the turbine runner, and thus the genes ^¬ ratorläufers, smaller than the respective mains frequency of the power grid to be supplied, the first frequency of the first three-phase AC voltage generated by the alternator is lower than the mains frequency. In order to be able to generate a three-phase alternating voltage with the mains frequency with the three-phase generator, the rotor winding of the generator output is not supplied, as conventionally, with a DC voltage, but with a three-phase alternating voltage with the second frequency, wherein the second frequency of the respective difference between the mains frequency of the mains and the first frequency. As a result, a magnetic field is generated between the generator rotor and a generator stator of the three-phase generator which rotates at the mains frequency. A stator winding of the generator stand thus sees a magnetic field which rotates with the mains frequency, whereby a three-phase alternating voltage is induced at the mains frequency in the stator winding.

At a rotational frequency of the generator rotor, for example in the amount of 50 Hz, between the generator rotor and the generator neratorständer by a suitable choice of the second frequency of the third three-phase AC voltage rotating at a rotational frequency in the amount of 60 Hz magnetic field ^{ausgebil ¬} det. As a result, a three-phase alternating voltage having a frequency of 60 Hz is induced in the stator winding. As a result, a 60 Hz three-phase alternating voltage is applied to a machine transformer via which the three-phase generator is connected to the power network to be supplied, in order to be able to provide it with a corresponding power to a 60 Hz power network. Consequently, it is possible with the system according to the invention, with a turbine whose Turbinenlauferdrehfrequenz is smaller than the mains frequency of the power grid to feed a three-phase AC voltage with the grid frequency in the power grid.

As a result, a higher specific power can be achieved ^¬ the.

By supplying the rotor winding of the generator rotor with the third three-phase alternating voltage with the second frequency, therefore, the stator winding of the generator stator can see a magnetic field which rotates with the mains frequency. By means of a suitable choice of the second frequency, a frequency support by the system according to the invention can thereby be ensured independently of the rotational frequency of the generator rotor. In particular, the system according to the invention can offer a frequency support in a much broader frequency band than conventional systems. Moreover, the design of the components of the system according to the invention does not have to be such that the components of the system must be able to fulfill a specific frequency support band. Instead, the components can be designed for a specific operating point, in which in particular the system has a high efficiency and a high durability. Thus, it is possible with the invention to provide a system with an improved frequency support operation. Beispielswei ^¬ se have connected turbines provide more power at low mains frequency in order to support the grid frequency. When the rotational speed of the turbine runner or neratorläufers, due to the falling mains frequency, but also decreases the performance. This can be prevented with the erfindungsge ^¬ MAESSEN plant since the turbine can be decoupled via the rotary ^¬ current generator-inverter assembly from the mains frequency and as such may continue to realize their full potential.

Deviations of the rotational frequency of the generator rotor or of the turbine rotor from the mains frequency of the power network can be compensated by supplying the rotor winding of the generator rotor with the third three-phase alternating voltage with the second voltage level and the second frequency. In this way, by means of the three-phase generator, a three-phase alternating voltage with the mains frequency can be generated, even if the rotational frequency of the generator rotor differs from the mains frequency. Therefore, it is not necessary to vary the rotational speed of the turbine rotor or of the generator rotor rotatably connected thereto, as is customary, in order to be able to adapt the frequency of the three-phase alternating voltage generated by the three-phase generator to the mains frequency. Rather, the conditioning, and can their components, such as the turbine and the alternator designed for egg ^¬ NEN optimum operating point, and during the genann ^¬ th approximation at the operating point are maintained, which increases the efficiency of the system as a whole.

According to the invention, for example, a 50 Hz gas turbine whose turbine rotor is rigidly or non-rotatably connected to the generator rotor of a 50 Hz three-phase generator can be used to supply a 60 Hz power grid. The assembly formed in the ^¬ sem case from the 50 Hz AC generator, the transformer and the frequency converter can thus be according to the invention driven by a 50Hz gas turbine and feed a three-phase alternating voltage with a frequency of 60 Hz in a 60 Hz mains.

The performance and efficiency of such a system are significant over a conventional 60Hz gas turbine unit. higher. For example, since the maximum power of Größ ^¬ th 50Hz gas turbine is greater by 44% than the maximum Leis ^¬ tung the largest 60Hz gas turbine, larger 60Hz power plants may be built with fewer blocks. For example, can be realized with two 50Hz gas turbine CCPs by the invention power plants, which have so far been realized with three 60Hz gas turbine CCP lines. This eliminates the need for an entire gas and steam pipeline consisting of the gas turbine, geno, clutch, boilers, steam turbines and control technology, which leads to enormous cost savings. At the 50Hz

Turbines themselves can also be observed a corresponding reduction in specific costs, since the 50Hz turbine version of the 60Hz turbine version is usually derived by scaling and thereby increase the cost far less than the performance. This is enough space to compensate for the additional costs in particular ^¬ sondere caused by the drive.

The alternator includes a three-phase stator and a three-phase generator rotor. The three-phase stator is preferably designed for the generation of a three-phase alternating voltage with the mains frequency, for example 60 Hz, a power grid and connected via a machine transformer directly to the power grid. The three-phase stator can be designed in a usual form for synchronous generators design with a laminated stator unit and arranged thereon, three-phase two-layer stator winding. The voltage of the stator winding can be in a customary for the particular application size, for example, at 22 kV for a 60Hz application.

The alternator rotor is coupled directly to the turbine rotor of the turbine. The generator rotor can be designed with a laminated rotor unit and a three-phase rotor winding arranged thereon. The three-phase Läu ^¬ ferwicklung can be interconnected in the star. The height of the second voltage may be about 5 kV. The three phases of the rotor winding are electrically connected with slip rings on one ner rotor shaft of the generator rotor connected. On the

Slip rings can run a three-phase brush system, which can be made up of several carbon brushes per phase and mounted on a standing brush apparatus. Can tensystem about Bürs- the third three-phase voltage of the inverter on the item under three-phase brush apparatus to the rotor winding of the rotating generator rotor übertra ^¬ gen. The frequency converter can be electrically connected on the output side to the three-phase brushing apparatus. As a result, the rotor winding can be supplied, for example, with a 5 kV / l OHz three-phase system. The frequency converter can be constructed, for example, as a converter with a constant voltage intermediate circuit.

The system according to the invention can also be used when the speed of the turbine is to be selected free of the usual mains frequencies in the amount of 50 Hz and 60 Hz, so as to further increase the maximum power of the turbine. In particular, the system according to the invention can be applied to turbines with any operating speed and three-phase networks of any mains frequency. This allows an optimal design of the turbine with regard to maximum power and maximum efficiency. For example, a 45Hz gas turbine whose maximum power exceeds that of a 50Hz gas turbine will feed a 60Hz three-phase AC voltage into a 60Hz power grid by increasing the second frequency in the output circuit of the frequency converter. Also, a 45Hz gas turbine with the inventive system with appropriate design of the components and a suitable choice of the second frequency can also feed a 50Hz three-phase AC voltage in a 50Hz power grid. According to the invention, large gas turbines can be combined with a three-phase transformer-to-frequency converter configuration which allows gas turbines to be supplied to a power grid at a speed different from the grid frequency to join. With a three-phase generator according to the invention, for example, a 60 Hz three-phase system can be generated when driven by a 50 Hz gas turbine, whereby 50 Hz Gasturbines can be applied to the 60 Hz market. The performance and efficiency of such a configuration are increased over a 60Hz gas turbine engine.

Considering this cost and efficiency situation, it is possible to dispense basically with the 60Hz product line for large gas and steam turbines, as the 50Hz product line can replace the 60Hz product line for higher power, lower specific cost and improved efficiency , Moreover, there are synergies in research and development and in the supply chain (higher quantity, etc.), resulting in internal Kos ^¬ teneinsparungen in three-digit million euro range. This applies to turbines still to be developed as well as to the existing portfolio. For the latter, even the larger positive effects are to be expected.

For example, consider a 2 + 1 CCG configuration where two 5000F gas turbines and one 60Hz steam turbine each with their conventional air-cooled alternators are powered by two 400 OF gas turbines and one 50Hz steam turbine each with the alternator. Transformer frequency converter assembly replaced, the power increases by about 190 MW. The absolute package costs for the gas turbines, the steam turbine, the three-phase generators and component auxiliary systems remain the same, even considering relatively high costs

Frequency converter costs of about 50 € / kW. Furthermore, specific package costs decrease by more than 25%. In addition, the overall samtanlagenwirkungsgrad (CHP) increases by 0.6%, with the already to ^¬ sätzlichen, conservative determined,

Frequency converter losses of 0.2% are taken into account. Fer ^¬ ner of benefits with respect to synergies in research and development and the supply of gas turbines with reduced operating frequency greater than other from a decision winding-derived frames, since these are independently developed gas turbine types, which can hardly benefit from each other in this regard. Preferably, the system comprises at least a three-phase

Capacitor battery, which is connected in parallel to an output ^{circuit of} the frequency ^¬ converter. The three-phase

Capacitor battery provides a reactive power for the Läu ^¬ ferwicklung. This reduces the electrical current to be supplied by the frequency converter, which in turn reduces the size of the frequency converter. In particular ^¬ sondere it is due to the presence of

Capacitor battery makes it possible not to drive all the power of the alternator, but only about 20% of this power through the frequency converter, resulting in a corresponding reduction in the cost of the inverter and to improve the overall efficiency of the arrangement of the alternator and the frequency converter. The overall somewhat poorer efficiency of this arrangement over a simple three-phase generator can be overcompensated by the improved efficiency of the driving turbine, in particular with reduced operating frequency. The generator voltage can nevertheless be of a conventional order of magnitude.

The system preferably comprises at least one communication ^¬ technically connected to the frequency converter control and / or control electronics, which is adapted to capture a momenta ^¬ ne difference between the mains frequency of the power grid and the first frequency and to drive the frequency converter as a function of the instantaneous difference. With the control and / or regulating electronics, the frequency converter can thus be controlled and / or regulated as a function of the detected instantaneous difference between the mains frequency of the power grid and the first frequency. The instantaneous frequency and the instantaneous power ^¬ first frequency can be detected by a sensor and the control and / or control electronics are fed for evaluation. Is according to an inventive method for generating a to be fed into a power grid three-phase alternating voltage using at least one turbine and at least one driven by the turbine alternator, wherein a generator rotor of the alternator-rotatably coupled to a turbine rotor of the turbine is a rotor ^¬ winding of the generator rotor with a Three-phase change ^¬ voltage supplied with a frequency corresponding to a difference between a mains frequency of the power network and a rotational frequency of the generator rotor.

With the method are the ge above with respect to the plant ^¬ called advantages connected accordingly. In particular, the system according to one of its embodiments or any combination of at least two of these embodiments can be used together to carry out the method. In this respect, advantageous embodiments of the system may be advantageous embodiments of the method, even if it is not explicitly referred to in the following.

Preferably, the three-phase AC voltage is generated by converting a three-phase AC voltage generated by the AC generator. For this purpose, the transformer-frequency converter arrangement of the system according to the invention can be used, which is associated with the abovementioned advantages.

In the following, the invention will be explained by way of example with reference to the attached FIGURE on the basis of a preferred embodiment, the following being shown

Features taken both individually, as well as in different combinations with each other can represent a further developing or advantageous aspect of the invention. It shows :

Fig. 1 is a schematic representation of a Ausführungsbei ^¬ game for a system according to the invention. Fig. 1 shows a schematic representation of an execution ^¬ be injected example of an inventive system 1 for generating ei ^¬ ner into a power grid 2 three-phase AC voltage.

The plant 1 comprises a turbine 3 in the form of a 50 Hz gas turbine and a driven with the turbine 3 alternator 4. The alternator 4 comprises a three-phase stator 5 in the form of a 60Hz three-phase stator and a generator rotor 6. The generator rotor 6 of the alternator 4 is rotatably on coupled an unshown turbine ^¬ runner of the turbine. 3 The alternator 4 is connected via a circuit breaker 7 and a machine transformer 8 to the power grid 2.

The plant 1 further comprises an output side elekt ^¬ driven connected to the alternator 4 transformer 9, with the first three-phase AC voltage generated by the alternator 4 with a first voltage level and a first frequency to a second three-phase alternating voltage to a second voltage level which is less than the first voltage level, and the first frequency is convertible. In addition, the system 1 comprises an output side electrically connected to the transformer 9 frequency converter 10, via which a rotor winding of the Generatorläu ^¬ fers 6, not shown, can be supplied with a third three-phase alternating voltage and with the second three-phase alternating voltage with the second voltage level and the first frequency in the third Three-phase AC voltage with the second voltage level and a second frequency, which is lower than the first frequency, is convertible. The frequency converter 10 is designed or controllable and / or regulated such that the second frequency corresponds to a difference between a mains frequency of the power network 2 and the first frequency. The three phases of the rotor winding of the generator rotor 6 are electrically connected to ungetigte slip rings on a rotor shaft 13 of the generator rotor 6. On the slip rings a not shown, three-phase Bürs- runs orb that is constructed from a plurality of carbon brushes, not shown, per phase and in a stationary brush apparatus 14 mon ^¬ advantage. About the brush system and the standing three-phase brush apparatus 14, the third three-phase ^¬ voltage is transmitted from the frequency converter 10 to the rotor winding of the rotating generator rotor 6.

Furthermore, Appendix 1 comprises a three-phase

Capacitor battery 11, which is connected in parallel to a not shown gear from ^¬ circuit of the inverter 10 degrees.

Furthermore, the system 1 includes a communications technology with the frequency converter 10 connected control and / or regulating electronics 12, which is adapted to detect a momentary difference between the mains frequency of the power network 2 and the first frequency and to drive the frequency converter 10 as a function of the instantaneous difference.

Although the invention in detail by the preferred embodiment has been illustrated and described in detail, the invention is not limited by the disclosed ^¬ example and other variations can be derived therefrom by the skilled artisan without departing from the scope of the invention.

Claims

claims

1. Plant (1) for generating a three-phase alternating voltage to be fed into a power network (2), comprising at least one turbine (3) and at least one three-phase generator (4) driven by the turbine (3), wherein a generator rotor (6) of the three-phase generator (4 ) is rotationally fixedly coupled to a turbine runner of the turbine (3),

 marked by

at least one on the output side electrically connected to the rotary ^¬ current generator (4) transformer (9), with one of the three-phase generator (4) generated first three-phase alternating voltage having a first voltage level and a first frequency in a second three-phase AC voltage having a second voltage level, which is less than the first voltage level is, and the first frequency is convertible, at least one output side electrically connected to the Trans ^¬ formator (9) frequency converter (10) via which a rotor winding of the generator rotor (6) can be supplied with a third three-phase AC voltage and with the second three-phase alternating voltage with the second voltage level and the first frequency in the third ^¬ three-phase AC voltage to the second voltage level and a second frequency that is lower than the first frequency, is convertible,

 wherein the frequency converter (10) is designed or controllable and / or regulated such that the second frequency corresponds to a difference between a mains frequency of the power network (2) and the first frequency.

2. Plant (1) according to claim 1,

comprising at least one three-phase capacitor bank (11), which is connected in parallel to an output circuit of the frequency converter (10).

3. Plant (1) according to claim 1 or 2,

 comprising at least one control and / or regulating electronics (12) connected in terms of communication technology with the frequency converter (10), which is set up to detect a momentary difference between the mains frequency of the power network (2) and the first frequency and to drive the frequency converter (10). to control as a function of the instantaneous difference.

4. A method for generating a three-phase alternating voltage to be fed into a power network using at least one turbine and at least one three-phase generator driven by the turbine;

 wherein a generator rotor (6) of the three-phase generator (4) is non-rotatably coupled to a turbine rotor of the turbine (3),

 characterized in that

 a first three-phase alternating voltage generated by the three-phase generator (4) having a first voltage level and a first frequency by means of a transformer (9) electrically connected to the three-phase generator (4) on the output side into a second three-phase alternating voltage having a second voltage level lower than the first voltage level, and the first frequency is converted,

 a rotor winding of the generator rotor (6) is supplied with a third three-phase alternating voltage by means of a frequency converter (10) electrically connected to the transformer (9) on the output side,

 the second three-phase alternating voltage having the second voltage level and the first frequency is converted by means of the frequency converter (10) into the third three-phase alternating voltage having the second voltage level and a second frequency which is lower than the first frequency, and the third three-phase alternating voltage by means of the frequency converter (10) is generated such that the second frequency of a difference between a network frequency of

 Power supply (2) and a rotational frequency of the generator rotor (6) corresponds.