EP1775430A1 - Steam power plant and method for retrofitting a steam power plant - Google Patents

Abstract

Steam generating power station (12) has a steam heater (14,14',22,22') for supplying compressed heat and a steam heater downstream. A additional turbine (30,34) is designed at 50 percent higher operational speed than normal speed rate of main turbine (18,24). The additional turbine is switched between the steam heater and main turbine, and which is arranged on additional drive shaft (32). An independent claim is also included for the method for retrofitting of steam generating power station.

Description

The invention relates to a steam power plant with at least one steam heater for providing compressed steam, a steam heater downstream, arranged on a main drive shaft and designed for operation with high pressure and / or medium pressure steam main turbine, as well as between the steam superheater and the main turbine connected and on a Additional drive shaft arranged additional turbine. The invention further relates to a method for retrofitting a steam power plant with at least one steam heater for providing compressed steam, and a steam turbine downstream, arranged on a main shaft and designed for operation with high pressure and / or medium pressure steam main turbine. The method includes the step of retrofitting the thermal power plant with an auxiliary turbine disposed on an auxiliary drive shaft. The above-mentioned main turbine designed for operation with high pressure and / or medium pressure steam can be designed as a separate high-pressure, as a separate medium-pressure or as a combined high-pressure / medium-pressure turbine. High-pressure turbines are usually designed for a temperature of 520 to 600 ° C and a pressure of 120 to 300 bar. By contrast, medium-pressure turbines are generally designed to hold 520 to 620 ° C hot steam at a pressure of 30 to 60 bar. The steam generator of the steam power plant can use various heat sources for steam generation, in particular the exhaust gas of a gas turbine. In this respect, the steam power plant can also be part of another power plant.

In order to achieve an increase in performance in steam power plants, the blading of the steam turbines to increase the internal efficiency is often replaced in the prior art. Also, an increase in performance is often due to reduction of collateral, ie usually by increasing pressure and / or Mass flow reached. In another known in the prior art method for retrofitting a steam power plant, an auxiliary turbine is connected on an auxiliary drive shaft between the steam heater and the main turbine. In this case, the main drive shaft is mechanically coupled to the auxiliary drive shaft for driving an electric generator in the rule.

An object of the invention is to improve a steam power plant of the type mentioned and a method for retrofitting a steam power plant of the type mentioned in that the performance and efficiency of the steam power plant can be further increased.

This object is achieved according to the invention with a generic steam power plant, in which the auxiliary turbine is designed to a relative to a rated speed of the main turbine by at least 50% higher operating speed. The object is further achieved by a generic method, in which the auxiliary turbine is designed to be at a rated speed of the main turbine by at least 50% higher operating speed.

By virtue of the solution according to the invention, the steam conditions for the additional turbine, which is designed in particular as a high-pressure or medium-pressure turbine, can be increased considerably. The relative to the rated speed of the main turbine by at least 50% higher operating speed of the auxiliary turbine allows efficiency-enhancing operation of the auxiliary turbine with steam conditions increased temperature and increased pressure. A conversion of these increased steam conditions into mechanical power can be done at the correspondingly high operating speed with increased efficiency. This increases the output power of the additional turbine. After passing through the auxiliary turbine, the vapor state advantageously has a vapor state which the main turbine is usually designed. That is, the power generated by the auxiliary turbine is available in addition to the power generated by the steam power plant prior to retrofitting with the auxiliary turbine.

Since the additional turbine is arranged on an auxiliary drive shaft, retrofitting of an existing steam power plant with the auxiliary turbine is possible without much effort. The main drive shaft of the existing steam power plant does not need to be modified. For arranged on the auxiliary drive shaft additional turbine only a suitable space in the steam power plant must be found and then the steam heater leaving the steam mass flow are passed through appropriate adaptation of pipelines through the auxiliary turbine to the main turbine.

In an advantageous embodiment of the steam power plant according to the invention, the operating speed of the auxiliary turbine with respect to the rated speed of the main turbine twice the value. In particular, the operating speed of the auxiliary turbine 80 to 120 Hz, preferably 100 Hz. Since the rated speed of the main turbine is half the operating speed of the auxiliary turbine, so in this case, the rated speed of the main turbine 40 to 60 Hz, preferably 50 Hz.

Advantageously, the additional turbine is designed for a steam temperature of 700 to 760 ° C. This means that the steam heater is also designed to produce a steam temperature of 700 to 760 ° C. Advantageously, the steam in the auxiliary turbine cools with appropriate expansion to 520 ° C to 620 ° C and is forwarded at this temperature to the main turbine. The said steam temperatures lead to a further improved efficiency and a further improved power output of the steam power plant.

In an advantageous embodiment, the auxiliary drive shaft is coupled to a high-speed generator. Furthermore, the thermal power plant has an electric speed converter for reducing the frequency of the AC voltage generated by the high-speed generator. Advantageously, a main generator is provided on the main drive shaft. The electric speed converter reduces the frequency of the AC voltage generated by the high speed generator coupled to the auxiliary drive shaft to the frequency of the AC electric current generated by the main drive shaft. This preferably has the usual mains frequency of 50 Hz. The alternating current generated by the auxiliary turbine can thus be fed into the power grid together with the alternating current generated by the main generator without further conversion effort.

In an alternative embodiment, the auxiliary drive shaft is coupled via a mechanical speed converter to the main drive shaft. In particular, the mechanical speed converter reduces the frequency of the auxiliary drive shaft to the frequency of the main drive shaft. The mechanical energy generated by the auxiliary turbine is thus transmitted to the shaft train of the main drive shaft. The electrical main generator connected to the main drive shaft thus also converts the mechanical energy generated by the auxiliary turbine into electrical energy. An additional generator does not have to be provided.

Advantageously, the steam heater is designed as a live steam generator, which in particular has a steam boiler. In a live steam generator, the aforementioned high steam conditions can be efficiently generated. Alternatively, the steam heater is designed as a reheater. With a reheater, steam that has already passed through a first turbine can be processed for feeding to the additional turbine according to the invention. Advantageously, the steam heater, in particular the steam generator, or the Reheater compared to conventional steam heaters or reheaters additional superheater surfaces on.

Particularly advantageous is the combined use of such live steam and reheaters.

In order to be able to supply the steam of the auxiliary turbine with as high a temperature as possible, it is advantageous if the additional turbine is arranged close to the steam heater, in particular on a steam boiler of the steam heater. This arrangement is particularly useful for supplying super-supercritical steam conditions to the auxiliary turbine. Furthermore, the respective length of fresh steam generator and reheater lines is advantageously reduced to a minimum. The remaining lines can be carried out conventionally.

In a further expedient embodiment of the main propulsion turbine are successively a reheater, another additional turbine and another main turbine, which are each designed in particular as a medium-pressure turbine, downstream, the further auxiliary turbine are arranged on the auxiliary drive shaft and the other main turbine on the main drive shaft. With this arrangement, a further Leistungsgrad- and increase in efficiency of the steam power plant can be achieved. The expanded steam leaving the first main turbine is restored by the reheater to a high vapor state, preferably at a temperature of about 720 ° C. When passing through the second auxiliary turbine, the auxiliary drive shaft is supplied with additional power, which increases the electric power output of the electric generator coupled thereto. Advantageously, there is also a low-pressure turbine on the main drive shaft.

In an advantageous embodiment of the method according to the invention, the steam heater with additional superheater surfaces retrofitted. In particular, this retrofitting is done with additional superheater surfaces in a steam generator designed as a steam generator. The thus retrofitted steam heater can thus produce higher steam conditions. This in turn allows for improved operation of the retrofitted with the auxiliary turbine steam power plant.

In a further advantageous embodiment of the method according to the invention, the rated speed of the auxiliary turbine relative to the rated speed of the main turbine twice the value, in particular 80 to 120 Hz, preferably this is 100 Hz. Furthermore, the auxiliary turbine is expediently designed for a steam temperature of 700 to 760 ° C. , In addition, advantageously, the steam power plant is retrofitted with a high-speed generator and an electric speed converter, coupled the fast-running generator to the auxiliary drive shaft, and coupled the electric speed converter to the high-speed generator for reducing the frequency of the alternating current generated by the high-speed generator. Furthermore, the steam power plant is expediently retrofitted with a mechanical speed converter and the auxiliary drive shaft coupled to the main drive shaft via the mechanical speed converter. In a further advantageous embodiment, the additional turbine is arranged near the steam heater, in particular on a steam boiler of the steam heater. In an embodiment which is furthermore expedient, a further additional turbine is arranged downstream of the steam power plant and arranged downstream of a further main turbine of the additional auxiliary turbine. The other main turbine and the additional auxiliary turbine are each designed as medium-pressure turbines, wherein the additional auxiliary turbine are arranged on the auxiliary drive shaft and the other main turbine on the main drive shaft. The advantages listed above with regard to the advantageous embodiments of the steam power plant according to the invention also relate to the corresponding advantageous Embodiments of the method according to the invention for retrofitting a steam power plant.

Fig. 1

eine schematische Ansicht eines Dampfkraftwerks vor der erfindungsgemäßen Nachrüstung, sowie

Fig. 2

eine schematische Ansicht eines erfindungsgemäß nachgerüsteten Dampfkraftwerks.

Hereinafter, an embodiment of a steam power plant according to the invention and an embodiment of the inventive method for retrofitting a steam power plant will be explained in more detail with reference to the accompanying schematic drawings. It shows:

Fig. 1

a schematic view of a steam power plant before retrofitting according to the invention, and

Fig. 2

a schematic view of a retrofitted according to the invention steam power plant.

FIG. 1 shows a conventional steam power plant 10 prior to retrofitting according to the invention, while FIG. 2 shows a steam power plant 12 retrofitted according to the invention or a corresponding newly produced steam power plant 12. The steam power plant 10 according to FIG. 1 is equipped with a steam generator 14 serving as steam heater. The live steam generator 14 is supplied with either low-temperature or liquid steam, which converts the live steam generator 14 into high-pressure, high-temperature steam and thus high-steam steam. The live steam is then fed via a steam line 16 to a first main turbine 18 designed as a high-pressure turbine, in which it expands under the drive of a main drive shaft 20 connected to the first main turbine 18.

The expanded and thus cooled steam is then fed to a reheater 22, wherein a repeated heating of the steam takes place. Subsequently, the steam is supplied via a further steam line 16 to a second main turbine 24 designed as a medium-pressure turbine. Thereafter, the steam expands again and transmits additional torque to the main turbine drive shaft 20. Upon exiting the second main turbine 24, the steam of a low-pressure turbine 26 is supplied, in which it further expands with further transmission of torque to the main drive shaft 20. To the main drive shaft 20, a main electric generator 28 is connected by means of which the mechanical energy of the main drive shaft 20 is converted into electrical energy.

The high-pressure, medium-pressure and low-pressure turbines used in the steam power plant 10 according to FIG. 1 are designed for steam conditions customary for such turbines. High-pressure turbines are usually designed for a temperature of 520 to 600 ° C and a pressure of 120 to 300 bar. Medium-pressure turbines are generally designed to hold 520 to 620 ° C hot steam at a pressure of 30 to 60 bar. Low-pressure turbines are usually designed for 4 to 10 bar pressure.

In Fig. 2, a steam power plant 12 is shown after retrofitting according to the invention to increase the power and efficiency of the steam power plant. Elements of the steam power plant 12 that correspond to corresponding elements of the steam power plant 10 shown in FIG. 1 are identified by the same reference numerals. With regard to their function, reference is made to the comments with respect to FIG. 1. The steam power plant 12 is compared to the steam power plant 10 initially equipped with a steam generator 14 downstream of the additional steam heater 14 'for additional heating of the live steam to about 700 ° C. In this case, the function of the additional steam heater 14 'can also be integrated into the main steam generator 14. For example, the steam generator 14 may be provided with additional superheater surfaces for higher steam conditions, or may be designed for higher steam conditions when the steam power plant shown in FIG. 2 is newly manufactured.

Furthermore, the steam power plant 12 is equipped with a arranged on an auxiliary drive shaft 32 first auxiliary turbine 30 or retrofitted. The first auxiliary turbine 30 is designed as a high pressure turbine designed to receive 700 ° C hot steam. In the first auxiliary turbine 30, the fresh steam supplied at a temperature of about 700 ° C. expands and cools down to 560 ° C. to 620 ° C. In this case, the first auxiliary turbine 30 drives an additional electric generator 36 via the auxiliary drive shaft 32. The expanded steam is then directed via a steam line 16 into the first main turbine 18. After appropriate expansion in the first main turbine 18, the steam is supplied to the reheater 22 and a downstream auxiliary reheater 22 '. As already explained with regard to the fresh steam generator 14 and the additional steam heater 14 ', the additional reheater 22' may also be functionally integrated into the reheater 22. This can also be accomplished here with additional superheater surfaces in the reheater 22.

After passing through the additional reheater 22 ', the steam is at a temperature of approximately 720 ° C. and is then introduced into a second auxiliary turbine 34, which is designed as a medium-pressure turbine and is designed for a steam temperature above 720 ° C. The second auxiliary turbine 34 is also arranged on the auxiliary drive shaft 32. The arrangement of a plurality of drive shafts according to the steam power plant 12 with the main drive shaft 20 and the auxiliary drive shaft 32 is also referred to as a multi-shaft arrangement. The second auxiliary turbine 34 exerts a further torque on the auxiliary drive shaft 32.

The first auxiliary turbine 30 and the second auxiliary turbine 34 are designed for a speed that is twice as high as the rated speed of the main turbines 18, 24 and 26. Preferably, the auxiliary drive shaft 32 is at a frequency of 100 Hz relative to a drive frequency of the main drive shaft 20 powered by 50 Hz. In the embodiment of the steam power plant 12 shown in FIG. 2, the additional electric generator 36 is coupled to the main electric generator 28 via an electric speed converter (not shown in the drawing). In another embodiment, not shown in the drawing, the auxiliary drive shaft 32 and the main drive shaft 20 may also be coupled by means of a mechanical speed converter (transmission). In this case, only one electrical generator is necessary to convert the mechanical energy into electrical current.

Claims (16)

Steam power plant (12) with at least one steam heater (14, 14 ', 22, 22') for providing compressed steam,
a the steam heater downstream,
arranged on a main drive shaft (20) and designed for operation with high-pressure and / or medium-pressure steam main turbine (18, 24) and
an auxiliary turbine (30, 34) connected between the steamer heaters (14, 14 ', 22, 22') and the main turbine (18, 24) and arranged on an auxiliary drive shaft (32),
characterized in that
the auxiliary turbine (30, 34) is designed to operate at a speed that is at least 50% higher than a rated speed of the main turbine (18, 24). Steam power plant according to claim 1,
characterized in that
the operating speed of the auxiliary turbine (30, 34) with respect to the rated speed of the main turbine (18, 24) has twice the value, in particular 80 to 120 Hz, preferably 100 Hz. Steam power plant according to claim 1 or 2,
characterized in that
the auxiliary turbine (30, 34) is designed for a steam temperature of 700 to 760 ° C. Steam power plant according to one of the preceding claims,
characterized in that
the auxiliary drive shaft (32) is coupled to a high-speed generator (36) and
the steam power plant (12) has an electric speed converter for reducing the frequency of the fast-running generator (36) generating AC voltage. Steam power plant according to one of claims 1 to 3,
characterized in that
the auxiliary drive shaft (32) is coupled to the main drive shaft (20) via a mechanical speed converter. Steam power plant according to one of the preceding claims,
characterized in that
the steam heater (14, 14 ', 22, 22') is designed as a live steam generator (14, 14 '), which in particular has a steam boiler. Steam power plant according to one of the preceding claims,
characterized in that
the auxiliary turbine (30, 34) near the steamer heater (14, 14 ', 22, 22'),
in particular on a steam boiler of the steam heater (14, 14 ', 22, 22') is arranged. Steam power plant according to one of the preceding claims,
characterized in that
the main turbine (18) successively a reheater (22, 22 '), a further auxiliary turbine (34) and another main turbine (24),
which are each designed in particular as a medium-pressure turbine, are connected downstream,
wherein the further auxiliary turbine (34) on the auxiliary drive shaft (32) and the other main turbine (24) on the main drive shaft (20) are arranged. A method for retrofitting a steam power plant (10) with at least one steam heater (14, 22) for providing compressed steam and
a main turbine (18, 24) arranged downstream of the steam heater (14, 22) and arranged on a main drive shaft (20) and designed for operation with high-pressure and / or medium-pressure steam,
with the step of retrofitting the steam power plant (10) with an auxiliary turbine (30, 34) arranged on an auxiliary drive shaft (32),
wherein the auxiliary turbine (30, 34) is connected between the steam heater (14, 22) and the main turbine (18, 24),
characterized in that
the auxiliary turbine (30, 34) is designed to operate at a speed that is at least 50% higher than a rated speed of the main turbine (18, 24). Method according to claim 9,
characterized in that
the operating speed of the auxiliary turbine (30, 34) compared to the rated speed of the main turbine (18, 24) has twice the value,
in particular 80 to 120 Hz, preferably 100 Hz. Method according to claim 9 or 10,
marked by
the step of retrofitting the steamer heater (14, 22) with additional superheater surfaces (14 ', 22'). Method according to one of claims 9 to 11,
characterized in that
the auxiliary turbine (30, 34) is designed for a steam temperature of 700 to 760 ° C. Method according to one of claims 9 to 12,
marked by
retrofitting the steam power plant (10) with a high-speed generator (36) and an electric speed converter, coupling the high-speed generator (36) to the auxiliary drive shaft (32)
and coupling the electric speed converter to the high speed generator (36) to reduce the frequency of the high speed generator (36) generating AC voltage. Method according to one of claims 9 to 13,
marked by
retrofitting the steam power plant (10) with a mechanical speed converter and coupling the auxiliary drive shaft (32) with the main drive shaft (20) via the mechanical speed converter. Method according to one of claims 9 to 14,
characterized in that
the auxiliary turbine (30, 34) near the steam heater (14, 22), in particular on a steam boiler of the steam heater (14, 22) is arranged. Method according to one of claims 9 to 15,
marked by
a further auxiliary turbine (34) arranged downstream of a reheater (22) of the steam power plant and a further main turbine (24) connected downstream thereof, which in each case are in particular designed as a medium-pressure turbine,
wherein the further auxiliary turbine (34) on the auxiliary drive shaft (32) and the other main turbine (24) on the main drive shaft (20) are arranged.

Images