EP2791576A2

EP2791576A2 - Auxiliary steam generator system for a power plant

Info

Publication number: EP2791576A2
Application number: EP12809644.3A
Authority: EP
Inventors: Heiner Edelmann; Mark Reissig; Marc Sattelberger; Andre Schrief
Original assignee: Siemens AG
Current assignee: Siemens AG
Priority date: 2012-01-19
Filing date: 2012-12-04
Publication date: 2014-10-22
Also published as: WO2013107557A3; CN104302975B; JP2015510574A; US9494054B2; US20150000276A1; WO2013107557A2; JP6069359B2; CN104302975A; KR20140123048A

Abstract

The invention relates to an auxiliary steam generator system (1) for a power plant, comprising a water-steam circuit (2), which has a condensate line (3) and a feed-water line (16), wherein a condensate pump (4) is connected in the condensate line (3) and a feed-water pump (5) is connected in the feed-water line (16), and wherein a pressure accumulating vessel (6) is connected between the condensate pump (4) and the feed-water pump (5), and wherein a feed-water take-off line (8) is connected to the water-steam circuit (2) at a branch-off point after the pressure accumulating vessel (6). According to the invention, the feed-water take-off line (8) is connected to the pressure accumulating vessel (6) and a heating device (9) is connected in the feed-water take-off line (8).

Description

description

Auxiliary Steam Generator System for a Power Plant Conventional Power Plant with a Water Steam -

For additional processes, special operating modes or operating states, the circuit requires additional steam, which under certain circumstances can not be provided by the actual steam generation process. These special operating states include in particular transient operating states, the

Standstill, partial load operation or the startup and shutdown process. Thus, auxiliary steam is required, for example, in the case of a standstill for pressure maintenance or for keeping the feedwater tank warm, as well as for steaming the steam turbine. The steam which can be generated by the actual steam generation process can under certain circumstances be used for the

Pressure maintenance of the feedwater tank, or the operation of other auxiliary systems of the power plant not, or not completely sufficient.

To counteract this problem, additional auxiliary steam generators are integrated in the water-steam circuit of the conventional power plant according to the prior art. These auxiliary steam generators are fossil-fired boilers, so-called auxiliary steam boilers. They are usually operated with gas or oil, or with other fossil fuels.

Such auxiliary steam generator provide in the construction of power plants, in particular by the complex and complex circuit of the auxiliary steam generator in the water-steam -

Circuit and with the auxiliary steam systems a high investment dar. Due to the complex interconnection they have a large space requirement. In addition, they require additional approval during construction. Since the auxiliary steam generators are provided in particular for the special operation, they are not required in normal operation of the power plant, but still cause running costs or efficiency losses, as they are electrically, or via steam from the water-steam cycle the power plant must be kept warm. They also cause regular and not insignificant maintenance costs.

The object of the invention is to provide an auxiliary steam generator system, by which the disadvantages of the prior art are avoided, and can be reduced drastically, especially the installation costs. In addition, it is an object of the invention to provide a method for auxiliary steam generation, by which the disadvantages of the prior art are avoided.

The object of the invention directed to the provision of an auxiliary steam generator system is solved by the features of apparatus claim 1. It is proposed an auxiliary steam generator system for a power plant comprising a water-steam cycle with a condensate line, wherein in the condensate line a condensate pump and in the feed water line a feedwater pump are connected. Furthermore, see in the lines between the condensate pump and the feedwater pump, a pressure storage tank connected, and connected to the pressure storage tank to the water-steam cycle at a branch point, a feedwater discharge line. According to the invention, the feedwater discharge line is now connected to the pressure storage container, and a heating device is connected in the feedwater withdrawal line.

As a pressure storage tank, the feedwater tank of the power plant is provided, which thus fulfills the function of storing condensate or feed water for the water-steam cycle, and also to supply steam or saturated steam for the supply of the power plant with auxiliary steam. The heating device is designed so that the feed water can be heated by this, so that steam can be generated in the pressure storage container after corresponding reduction in pressure.

By the invention it is achieved that the feedwater tank, or accumulator tank, even in special operating conditions can be maintained at a necessary pressure or at the appropriate temperature without sufficient process steam, without an additional auxiliary steam generator is needed. As a result, the feedwater tank is designed as a thermal store ("Ruths store"), for which purpose the feedwater tank may be designed to be larger, in accordance with the increased requirements, than without the function of additional pressure storage This reduces the space required for the auxiliary systems, while at the same time reducing the energy consumption of a conventional auxiliary boiler by keeping it warm electrically or by steam As the feed water tank is now also used as an energy storage system, the feed water tank is therefore already warm, which means that additional systems and lines for keeping warm can be dispensed with. In addition, since complexity is reduced by the invention, maintenance costs are reduced and availability greatly increased.

The stored in the accumulator tank steam can also be used advantageously for the supply of auxiliary steam consumers. For this purpose, the power plant comprises further auxiliary steam consumers, the pressure storage tank being connected to the auxiliary steam consumers via a steam line.

The steam parameters in the pressure storage tank, such as the steam pressure and the steam temperature, are adjusted accordingly to the auxiliary steam consumers to be supplied. The setting is made by means of heating, condensate feed or feedwater pump, and / or throttle valves. In an advantageous further development of the auxiliary steam generator system is in the feedwater discharge line between the heater and the pressure accumulator container, a pressure-holding valve connected by which the pressure between the heater and the pressure-holding valve is increased so far that the operating pressure is sufficiently far from the vapor pressure of the medium at the respective operating temperature.

In a preferred embodiment of the Hilfsdampferzeugersys- tems the feedwater discharge line is connected to the condensate line of the water-steam cycle, and in the feedwater discharge line upstream of the heating device, a circulation pump is connected. Through the circulation pump, the steam parameters can be adjusted indirectly through the flow rate, the heating and according to the Druckreduzierventilstellung. Depending on the design of the power plant, it may also be advantageous if the feedwater discharge line is connected to a removal point of the feed pump or behind the feedwater pump. This requires specially configured feedwater pumps. In a particularly advantageous embodiment of the auxiliary steam generator system, the heating device is electric.

The invention makes it possible, in particular, to reduce the installation costs of a power station, since an otherwise expensive and expensive auxiliary steam generator can be dispensed with by using an electrically heated heating device for the auxiliary steam generator. If the invention is used in a solar power plant, the use of an electric heating device can result in a completely "regenerative energy production." Since the electrically heated heating device operates without emissions, a lower licensing cost for solar power plants can be expected Auxiliary steam generation does not require a fuel system for storing and distributing the fuel.

The auxiliary steam generator system is advantageously used in a gas and steam turbine power plant. But in other fossil-fired steam power plants, the advantages the auxiliary steam generator system can be used. Particularly advantageous is the auxiliary steam generator system in a CSP (Concentrating Solar Power) steam power plant with solar heated steam generation used.

The object of the invention directed to a process for auxiliary steam generation is solved by the features of process claim 9. The process for auxiliary steam generation in a power plant process thereby provides a reservoir connected in a water-steam cycle, into the condensate from the water vapor Cycle is promoted. The condensate is stored in the memory, mixed and degassed, and then discharged as feed water from the memory, and subtracted a partial flow of the discharged feedwater. According to the invention, the partial flow is then heated in a heating process, and fed back into the storage. The storage tank corresponds to a collection tank for feedwater, in which a volume of liquid for the water-steam cycle can be temporarily stored. The collection tank also serves as a buffer for the feed water. The partial flow is heated to temperatures at a sufficient distance below the boiling point or above the boiling point. The return of the heated partial flow into the reservoir increases the pressure in the reservoir. As a result, the accumulator can also be used as an accumulator for process steam.

Since an additional pressure accumulator for process steam and an otherwise expensive and expensive auxiliary steam generator can therefore be dispensed with, the process according to the invention, in particular the installation costs of a power plant process, can be reduced. In addition, the auxiliary steam generation process can be realized much less complex by the method according to the invention. In an advantageous For this purpose, steam is withdrawn from the storage tank and fed to an auxiliary steam process of the power plant process. The steam can be generated by various methods. In a preferred embodiment, the partial flow of the feedwater is first heated in the heating process to just below the boiling point of the feedwater, and promoted and evaporated in the memory under the relaxation of the feedwater. The distance of the temperature to which the feed water is heated up to the boiling point is sufficiently large, so that there is still no evaporation prior to introduction into the memory. It is advantageous if the heated feed water is conveyed by a pumping process in the memory. The pumping process consists in particular of a circulation pump and possibly valves.

In an alternative embodiment, the partial flow of feed water is heated in the heating process to the boiling point or boiling point of the feed water, forming steam under pressure build-up and promoting the steam in the reservoir utilizing the density difference between steam and feed water. On an additional pump can be omitted here.

It is particularly advantageous if the partial flow of the feedwater in the heating device is heated electrically. As a result, an emission-free steam generation can be realized.

The method for auxiliary steam generation is advantageously operated when the power plant is in non-stationary operating states at standstill or in partial load operation or in startup / shutdown operation in order to supply the power plant process with sufficient auxiliary steam. The power plant process preferably comprises a gas and steam turbine process with a water-steam cycle, the process is integrated for auxiliary steam generation in the water-steam cycle of the gas and steam turbine process.

Alternatively, the power plant process is a CSP steam power plant process with a solar heated steam generation process, with the process of auxiliary steam generation integrated into the water-steam cycle of the CSP steam power plant process. Hereinafter, embodiments of the invention will be explained in more detail by way of examples. It shows:

1 shows an auxiliary steam generator system for a power plant, 2 shows a process for auxiliary steam generation for a

Power plant process.

In FIG 1, an auxiliary steam generator system 1 is shown, as it may be integrated into a fossil-fueled power plant or a solar power plant. The power plant comprises a water-steam cycle 2 of which only the section of the condensate line 3 is shown here.

In the condensate line 3 are essentially a condensate pump 4, a pressure storage tank 6 and in the feed water pipe 16 is a feedwater pump 5 is connected. By the condensate pump 4 condensate is conveyed into the pressure storage tank 6. In the accumulator tank, the condensate is degassed, mixed and stored before it is pumped through the feedwater pump 5 back in through the feedwater line 16 into the water-steam cycle 2.

According to the invention, a feedwater discharge line 8 is now provided which is connected at a branching point 7 to the feedwater line 16 between the pressure storage container 6 and the feedwater pump 5. Not shown here is an alternative embodiment in which the feedwater discharge line device 8 is connected directly to the feedwater pump 5 or after the feedwater pump 5.

The feedwater discharge line 8 connects the feedwater line 16 to the accumulator tank 6. A circulation pump 13 and a heating device 9 are essentially connected in the feedwater discharge line 8. By the heater 9, the withdrawn partial flow of the feedwater is heated. In addition, valves for controlling the partial flow are connected in the feedwater discharge line 8. Between the heater 9 and the accumulator tank 6, a pressure valve 12 is connected, by which the pressure in the accumulator tank is kept adjustable. By the separate circulation pump 13, the accumulator tank 6 is taken from a lot of feed water, brought to pressure, heated in an electric heater 9 to a sufficient distance from the boiling temperature and

Finally, via a pressure valve 12 and a Regelarma- tur relaxed in the accumulator tank. By the relaxation of the heated and under higher pressure feed water to the pressure of the accumulator tank 6 is a partial evaporation. After the circulating pump 13, a return line 14 is connected to the feedwater discharge line 8. By the circulation pump 13 and the minimum quantity line of the circulation pump 14, a circuit is thus created by which a circulation of the feedwater is made possible.

To the accumulator tank 6, a steam line 11 is connected to the discharge of steam. The steam line 11 connects the accumulator tank 6 with a Hilfsdampf- consumer 10. For controlling or throttling of steam is in the steam line 11, a motor or pneumatically operated control valve is connected. The auxiliary steam consumers thus obtain the required auxiliary steam exclusively from the pressure storage tank 6. The section of the condensate line 3 of the water-steam cycle 2 also has a compensation line 15, which the condensate the portion 3 of the condensate between the condensate 4 and the accumulator tank 6 with the portion of the feedwater discharge line 8 between the accumulator tank 6 and the circulation pump thirteenth combines. In the compensation line, a motor or pneumatically operated control valve may be connected.

2 shows a method for auxiliary steam generation, as it may be integrated into a fossil-fueled power plant process or a solar power plant process. Shown here is a section of the water-steam circuit 2 for feed water 24 in the form of condensate 23, as obtained after condensation in the power plant process.

The method essentially comprises a reservoir 22 and a heating process 26. The reservoir 22 is first supplied with condensate 23 from the water-steam circuit 2. In the memory 22, the condensate 23 and feed water 24 is stored, mixed and degassed. It is then discharged again and passed into the water-steam circuit 2 for evaporation.

From the discharged feed water 24, a partial stream 25 is now withdrawn, and fed to the heating process 26. In the heating process, the feedwater 24 is heated and returned to the reservoir 22. In order to convey the partial flow 25 back into the storage 22, a pumping process 29 is provided.

By heating the feed water 24 in the heating process 26, a steam 27 is generated in the memory 22, which can now be supplied from the memory 22 to an auxiliary steam process.

By providing steam 27 from the reservoir 22 can be dispensed with additional fossil-fired auxiliary steam generator.

Claims

claims

Auxiliary steam generator system (1) for a power plant, comprising a water-steam circuit (2), comprising a condensate line (3) and a feed water line (16), wherein in the condensate line (3) a condensate pump (4), and in the feed water line (16) a feedwater pump (5) are connected, and wherein between the condensate pump (4) and the feedwater pump (5), an accumulator tank (6) is connected, and wherein the water-steam cycle (2) after the pressure storage tank (6) at a branch point (7) a feedwater discharge line (8) is connected, characterized in that the feedwater discharge line (8) to the pressure storage tank (6) is connected, and in that in the feedwater discharge line (8) has a heating device (9) is switched.

2. auxiliary steam generator system (1) according to claim 1,

comprising an auxiliary steam consumer (10), wherein the pressure storage container (6) via a steam line (11) with the auxiliary steam consumers (10) is connected.

3. auxiliary steam generator system (1) according to claim 1 or 2, characterized in that in the feedwater discharge line (8) between the heating device (9) and the accumulator tank (6), a pressure holding valve (12) is connected by the in the accumulator tank (6). a vapor pressure (13) is adjustable.

4. auxiliary steam generator system (1) according to one of claims 1 to 3, characterized in that the feedwater discharge line (8) to the feedwater line (16) of the water-steam circuit (2) is connected, and in that the feedwater discharge line (8) the heating device (9) is connected to a circulating pump (13).

5. auxiliary steam generator system (1) according to one of claims 1 to 3, characterized in that the feedwater discharge line (8) at a removal point (7) of the feedwater pump (5) is connected.

6. auxiliary steam generator system (1) according to one of claims 1 to 5, characterized in that the heating device (9) is electric.

7. auxiliary steam generator system (1) according to one of claims 1 to 6,

characterized by the application in a gas and steam power plant.

8. auxiliary steam generator system (1) according to one of claims 1 to 6,

characterized by application in a CSP

Steam power plant with solar heated steam generation.

9. A process for auxiliary steam generation (20) in a power plant process (21) with a in a water-steam circuit (2) connected memory (22), in the condensate

(23) from the water-steam circuit (2) is conveyed, and the condensate (23) is stored in the memory (2), mixed and degassed, and then the condensate (23) as feed water (24) from the memory (2) and a partial flow (25) of the discharged feed water (24) is withdrawn, wherein the partial flow (25) is heated in a heating process (26), and the heated partial flow (25) is returned to the memory (22).

10. The method of claim 9, wherein steam (27) is withdrawn from the reservoir (22), and an auxiliary steam process (28) of the power plant process (21) is supplied.

11. The method according to any one of claims 9 or 10, wherein the partial flow (25) of the feedwater (24) in the heating process (26) is heated to a sufficient distance below the boiling point of the feedwater (24), and in the memory (22 ) is promoted and evaporated under the relaxation of the partial flow (25) of the feedwater (24).

12. The method of claim 11, wherein the heated feed water is delivered to the reservoir (22) by a pumping process (29).

13. The method according to any one of claims 9 or 10, wherein the partial flow (25) of the feedwater (24) in the heating process (26) to the boiling point, wherein steam (27) is formed under pressure build-up, and the steam (27). in the reservoir (22) by utilizing the density difference between steam (27) and feed water (24) is promoted.

14. The method according to any one of claims 9 to 13, wherein the

Partial flow (25) of the feedwater (24) in the heating process (26) is electrically heated.

15. The method according to claim 9, wherein the method for auxiliary steam generation is operated when the power plant process is in non-stationary operating states, at standstill, at start-up and shut-down or in part-load operation in order to prevent the power plant process. 21) with steam (27) to supply.

16. The method according to any one of claims 9 to 15, wherein the power plant process (21) comprises a gas and steam turbine process with a water-steam cycle, wherein the method for auxiliary steam generation is integrated into the water-steam cycle of the gas and steam turbine process ,

17. The method according to claim 9, wherein the power plant process is a CSP steam power plant process with a solar-heated steam generation process, the process for generating auxiliary steam in the water-steam

Integrated cycle of the CSP steam power plant process.