DE102010039870A1 - Steam power plant - Google Patents

Abstract

The invention relates to a steam power plant (1) with a main turbo set (2), a feed water pump (17) for pumping feed water into a boiler (8), a feed pump drive turbine (18) for driving the feed water pump (17), the feed pump The drive turbine (18) is designed as a steam turbine, the live steam side (19) of which is fluidically connected to a steam supply (9) from the main turbine set (2), and a further feed water pump (170) is arranged parallel to the feed water pump (17).

Description

The invention relates to a steam power plant according to the preamble of claim 1.

In steam power plants or in power plant processes feedwater is used, which is transferred in a steam generator in compressed and high-temperature steam and then thermally converted in a steam main turbo set. The feed water is pumped by means of a feedwater pump against the resistance of the live steam pressure in the boiler or steam generator. Often, this feed water pump is driven by an additional steam turbine, which is therefore also referred to as feed pump drive turbine (SPAT). In conventional power plant processes, the feed pump drive turbine is fed from a tap of the main steam turbine (at a pressure level between 10 and 15 bar) and then expanded to a condenser level.

In the design of this type of feedwater pump drives but must be taken into account that the feedwater pump in extreme cases requires a 20% to 30% above normal operation power requirements and thus must have power reserves. This increased power requirement must be provided by the feed pump power turbine. For this purpose, a corresponding reserve is taken into account or kept in reserve during the construction or during ongoing operation of the steam power plant for the feed pump drive turbine.

However, the provision of such power reserves for the feedwater pump by the feed pump drive turbine means that in normal operation - where these reserves are not needed - this feed pump drive turbine must be throttled accordingly. However, this throttling causes a deterioration of the overall efficiency of the steam power plant in normal operation.

The object of the invention is to provide a steam power plant, which overcomes the disadvantage described above.

This object is achieved by a steam power plant according to claim 1.

Characterized in that in a steam power plant with a main turbo set, a feedwater pump for pumping feedwater into a boiler, a feed pump drive turbine for driving the feedwater pump, wherein the feed pump drive turbine is designed as a steam turbine whose live steam side is fluidly connected to a steam supply from the main turbo set , A further feedwater pump is arranged parallel to the previous feedwater pump, the previous feedwater pump for a power level for normal operation and the other feedwater pump for power reserves can be designed and available. The steam power plant can be driven in optimal efficiency, since in normal operation no throttling of the feedwater turbine is more necessary.

Optimum overall efficiency is achieved when the feedwater pump pumps at nearly 100% of the boiler output, preferably 70% to 90% of the required feedwater quantity, and the additional feedwater pump is sized in accordance with the required power reserves beyond that power. Thus, the additional feed water pump can complement the pump performance for the entire performance spectrum of the system - from the partial load to the overload - as needed.

If the additional feedwater pump is driven independently of the main turbine set by a separate drive, in particular by an electric motor, it is possible to react to fluctuations in output particularly quickly and flexibly and without any additional additional adjustments to the actual steam power plant components of the main turbocharger set.

The invention will now be explained by way of example with reference to the following figures. Show it:

1 a steam power plant according to the prior art;

2 a structure of a steam power plant with inventive feed water pump assembly.

1 shows a steam power plant 1 according to the prior art. The steam power plant 1 includes a main turbo set 2 that a high pressure turbine part 3 , and here a first medium-pressure turbine section 4 , a second medium-pressure turbine section 5 as well as a low pressure turbine part 6 includes. The high-pressure turbine part 3 is via a main steam line 7 with a steam generator or boiler 8th supplied with live steam. The one from the high pressure turbine part 3 outgoing steam is in a cold reheater line 9 to a first reheater 10 guided. In the first reheater 10 the steam is overheated and then over a hot reheater line 11 to the first medium-pressure turbine section 4 guided. The from the first medium-pressure turbine section 4 outgoing steam is via another cold reheater line 12 in a second reheater 13 guided. This Steam is in turn overheated and over another hot reheater line 14 to the second medium-pressure turbine section 5 guided. The from the second medium-pressure turbine section 5 outgoing steam relaxes in a low-pressure turbine section 6 and then flows into a main condenser 15 , At the same time the main turbo set is driving 2 an electric generator 28 to generate electrical energy.

In the main capacitor 15 condenses the relaxed steam to water and from there, if necessary, via other components to a feedwater pump 17 guided. Through the feedwater pump 17 the water is against the live steam pressure in the steam generator or boiler 8th pressed. The feed water pump is driven by a feed pump drive turbine (SPAT), which in the tapped version shown here is also called a tuning turbine. The feed pump drive turbine 18 is designed as a steam turbine and is fresh steam side 19 via a throttle body 20 with the cold reheater line 9 fluidically connected. The steam of the in the cold reheater line 9 located cold reheater steam relaxed in the feed pump drive turbine 18 and drives over a rotor, not shown 21 the feedwater pump 17 at. The feed pump drive turbine 18 also has a tap 22 on, from the steam to a preheater 23 is guided and condensed, wherein the feed water is preheated. The condensate then flows from the preheater 23 over a second line 24 to a preheater or degasser 25 , The output side exhaust steam 26 flows through an exhaust steam line 27 also to the preheater 25 and warms up the feed water.

The throttle body 20 is throttled in the prior art for a power or speed control in normal operation. For example, efficiency deviations of the feedwater pump or individual turbines, which may occur due to aging effects over the operating life of the system, or even increasing Schwuckfähigkeitsabweichungen the main turbine can be compensated by a corresponding withdrawal of the throttling. The size of the possible adjustment range depends on the dimensioning of the turbine and the required power reserves.

2 shows one too 1 similar embodiment of a steam power plant 1 , here with a main turbo set 2 that a high pressure turbine part 3 and a medium pressure turbine section 4 ' and a feed water circuit with several preheaters 8th' . 23 ' and 23 '' , as well as the feed water pump 17 that feed water over this preheater into the boiler 8th inflated.

According to the invention is now parallel to the feedwater pump here 17 another feedwater pump 170 with its own drive 171 intended. The previous feedwater pump 17 will be as in relation to 1 described by the feed pump drive turbine 18 driven as T-turbine in the usual way. This feed pump drive turbine 18 is now dimensioned and thus designed so that the feedwater pump 17 at approx. 100% of the boiler output of the boiler 8th , Pumps 70% to 90% of the required feed water quantity. This feedwater pump 17 thus forms the "main boiler feed water pump" for pumping the amount of feed water needed in normal operation. The exact dimensioning of the value, which is optimal for a plant, is determined in the context of a total plant optimization, since it is ultimately dependent on the load profile of the respective steam power plant.

The additional feedwater pump 170 that the feedwater pump 17 is connected in parallel, is in the present embodiment of an electric motor 171 self-sufficient driven. It is dimensioned so that it can complement the missing pump power of the main boiler feed water pump over the entire power spectrum of the steam power plant. In sum, the two feedwater pumps 17 and 170 so dimensioned that they can meet all requirements for maximum peak loads required for the feedwater quantities. Throttling the drive of the main boiler feed water pump for holding power reserves is therefore no longer necessary.

By dividing the pump work on two units, here the feedwater pump 17 as a main load pump for normal operation and the parallel arranged additional feedwater pump 170 With its own drive as a pump for extreme cases, the advantage of a tuning turbine driven pump can be maximally utilized. The tuning turbine 18 as drive for the main feedwater pump 17 can be driven as far as possible in normal operating conditions in the optimal efficiency range. The second, here electrically operated feedwater pump 170 Adopts all other control tasks that go beyond normal load operation and possibly also the power-intensive startup procedure.

As a result of the arrangement according to the invention, virtually all the power requirements beyond normal operation are transferred from the feedwater pump driven by the SPAT or tuning turbine to the pump connected in parallel. Thus, the SPAT or tuning turbine can be driven over wide load ranges with fully open valves and thus without throttle losses.

The steam power plant thus arranged according to the invention is superior to the state of the art both in terms of the component stress, the efficiency and the operation. This makes it particularly suitable for use in future, efficiency-critical large-scale power plants with single or double reheat.

In relation to 2 described embodiment of a steam power plant according to the invention is of course the same in the 1 illustrated embodiment or any other system design without limitation applicable. The present invention is thus not limited to the embodiments described above. Rather, combinations, modifications or additions of individual features are conceivable that can lead to further possible embodiments of the inventive idea. For example, instead of the electric motor for driving the other feedwater pump, any other drive is conceivable. In addition, in addition to the in 1 and 2 illustrated component arrangements of the components of the steam power plant and other inventive arrangements conceivable as long as two or even more feedwater pumps are arranged and designed in parallel so that one of the feedwater pump is driven as a main pump of a SPAT or tuning turbine of the steam power plant and that the SPAT or In normal operation, the tuning turbine can be driven over wide load ranges with fully opened valves and thus without throttling.

Claims (3)

Steam power plant ( 1 ) with a main turbo set ( 2 ), a feedwater pump ( 17 ) for pumping feedwater into a boiler ( 8th ), a feed pump drive turbine ( 18 ) for driving the feed water pump ( 17 ), wherein the feed pump drive turbine ( 18 ) is designed as a steam turbine whose live steam side ( 19 ) with a steam supply ( 9 ) from the main turboset ( 2 ) is fluidically connected, characterized in that a further feedwater pump ( 170 ) parallel to the feedwater pump ( 17 ) is arranged. Steam power plant according to claim 1, characterized in that the feedwater pump ( 17 ) is dimensioned to pump 70% to 90% of the amount of feed water at almost 100% boiler output, and the further feed water pump ( 170 ) is dimensioned for the power reserve exceeding this power. Steam power plant according to claim 1 or 2, characterized in that the further feedwater pump ( 170 ) is driven autonomously by an electric motor.

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