Method for operating a power plant

Abstract

The invention relates to a method for operating a steam power plant, particularly a combined cycle power plant, which includes a gas turbine an a steam/water cycle with a heat recovery steam generator, through which the exhaust gases of the gas turbine flow, a water-cooled condenser, a feedwater pump and a steam turbine. A cooling water pump is provided for pumping cooling water through said water-cooled condenser. Evacuating means are connected to the water-cooled condenser for evacuating at least said water-cooled condenser. The method relates to a shut down and start-up of the power plant after the shutdown. The method includes: a) shut down of the steam turbine and gas turbine and/or a combustor of said gas turbine ; b) restoration of a good vacuum within the condenser by using said evacuating means; c) stopping said cooling water pump of said water-cooled condenser and said evacuating means, and filling up at least said condenser with steam up to slightly above atmospheric pressure; d) controlling the pressure with a flow of said cooling water; e) after a certain shut-down period starting the cooling water pump just before start-up of the plant; and f) starting the plant.

Claims

1. A method for operating a steam power plant, comprising a steam generator, a steam turbine and a steam/water cycle, at least consisting of a water-cooled condenser, a deaerator and a feedwater pump, whereby a cooling water pump is provided for pumping cooling water through said water-cooled condenser, and evacuating means are connected to said water-cooled condenser for evacuating at least said water-cooled condenser, said operating method being related to a shut down and start-up of said power plant after said shut down and comprising the steps of: a) shut down of the steam turbine; b) restoration of a good vacuum within the condenser by using said evacuating means; c) stopping said cooling water pump of said water-cooled condenser and said evacuating means, and filling up the vacuum portion of the steam/water cycle, at least said condenser, with steam up to slightly above atmospheric pressure; d) controlling the pressure with a flow of said cooling water; e) after a certain shut-down period starting the cooling water pump just before start-up of the plant; and f) starting the plant.

2. A method for operating a combined cycle power plant, comprising a gas turbine and a steam/water cycle with a heat recovery steam generator, through which the exhaust gases of the gas turbine flow, a water-cooled condenser, a feedwater pump and a steam turbine, whereby a cooling water pump is provided for pumping cooling water through said water-cooled condenser, and evacuating means are connected to said water-cooled condenser for evacuating at least said water-cooled condenser, said operating method being related to a shut down and start-up of said power plant after said shut down and comprising the steps of: a) shut down of the steam turbine and gas turbine and/or a combustor of said gas turbine ; b) restoration of a good vacuum within the condenser by using said evacuating means; c) stopping said cooling water pump of said water-cooled condenser and said evacuating means, and filling up the vacuum portion of the steam/water cycle, at least said condenser, with steam up to slightly above atmospheric pressure; d) controlling the pressure with a flow of said cooling water; e) after a certain shut-down period starting the cooling water pump just before start-up of the plant; and f) starting the plant.

3. The method according to claim 1, wherein the steam turbine comprises a low-pressure steam turbine, and the condenser and said low-pressure steam turbine are filled up with steam in step (c).

4. The method according to claim 1, wherein the steam for filling up said condenser is taken from the steam/water cycle.

5. The method according to claim 4, wherein the steam turbine has a steam-sealed gland, and gland steam is used for filling up said condenser.

6. The method according to claim 4, wherein the steam turbine has a low-pressure steam turbine with a steam bypass, and the steam for filling up the vacuum portion of the steam/water cycle, at least said condenser, is taken from the LP steam bypass.

7. The method according to claim 4, wherein the steam turbine has a low-pressure steam turbine with an auxiliary LP drum, and the steam for filling up the vacuum portion of the steam/water cycle, at least said condenser, is taken from the LP steam bypass.

8. The method according to claim 1, wherein at least the condenser has an insulation.

9. The method according to claim 1, further comprising a condenser bypass is used to control the pressure in the condenser.

10. The method according to claim 1, wherein the built up inversion layer on the hot well is used to avoid heat loss.

11. The method according to claim 1, wherein the ejector is started as soon as possible at startup procedure to extract the gases diffused into the steam.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) The present invention is now to be explained more closely by means of different embodiments and with reference to the attached drawings.

(2) FIG. 1 shows a simplified schematic diagram of a steam power plant, which can be used to practice the inventive operating method;

(3) FIG. 2 shows a schematic diagram of a combined cycle power plant, which can be used to practice the inventive operating method; and

(4) FIG. 3 shows various steps of a method according to an embodiment of the invention.

DETAILED DESCRIPTION

(5) FIG. 1 shows a simplified schematic diagram of a steam power plant, which can be used to practice the inventive operating method. The steam power plant of FIG. 1 comprises a steam turbine 17, 18, 19, a steam generator 16, a steam/water cycle 20 and an electric generator 15, driven by the steam turbine 17, 18, 19.

(6) Hot combustion gases of a fossil fuel flow through the steam generator 16 and deliver the energy for generating the steam. The steam drives a steam turbine comprising a high-pressure steam turbine 17, an intermediate-pressure steam turbine 18 and a low-pressure steam turbine 19.

(7) The steam exiting the low-pressure steam turbine 19 is condensed to water in a water-cooled condenser 21 and then pumped as feedwater back to the steam generator 16 by means of a feedwater pump 26. The condenser 21 is part of a cooling water circuit 23 containing the cooling water pump 22. The condenser 21 and other heat loosing components can have an insulation 24. The condenser 21 can be evacuated by means of evacuation pump 25. Furthermore, steam filling lines 27 may be provided to fill the condenser 21 with steam from a steam source within the steam/water cycle 20, in the example of FIG. 1 with steam sources situated at the high-pressure steam turbine 17 and intermediate-pressure steam turbine 18.

(8) After a shut-down of the steam turbine 17, 18, 19 at first a good vacuum has to be restored in the condenser 21 by means of the evacuation pump 25.

(9) Then, the condenser 21 and the low-pressure steam turbine 19 will be filled with steam from vacuum up to slightly above atmospheric pressure (approx. 1 bar) in a short time. This is to avoid any air leakage into the condenser 21 as soon as the evacuation pump 25 and cooling water pump 22 are shut down. The pressure is controlled with a flow of said cooling water. For this purpose a condenser bypass line 32 with a bypass valve 33 is installed in the cooling water circuit 23.

(10) Next, for restoration of vacuum before start up of the plant, the cooling water pump 22 will come into operation again and will establish full vacuum within the condenser 21 in a very short time.

(11) Finally, the plant can be started up.

(12) The steam source to heat up and fill the condenser 21 with steam may be the gland steam of a steam-sealed gland or the LP steam bypass system (not shown in the figure). Further steam sources to establish the 1 bar conditions in the condenser 21 for the overnight shut down could be high-pressure (HP), intermediate pressure (IP) process steam, auxiliary steam or boiler, etc. To lower the steam consumption the condenser 21 with condenser neck and the other heat loosing components could be insulated by means of an insulation 24.

(13) FIG. 2 shows schematically a diagram of a combined cycle power plant, which can be used to practice the inventive operating method. The combined cycle power plant 10 of FIG. 2 comprises a gas turbine 11 and a steam/water cycle 20, which are interconnected by using a heat recovery steam generator 16. The gas turbine 11 comprises a compressor 12, a combustor 13 and a turbine 14. The gas turbine 11 drives a first generator 15.

(14) The hot exhaust gases from the gas turbine 11 flow through the heat recovery steam generator 16, which is part of this steam/water cycle 20. Within the heat recovery steam generator 16 steam is generated, which drives a steam turbine comprising a high-pressure steam turbine 17, an intermediate-pressure steam turbine 18 and a low-pressure steam turbine 19. The steam turbine 17, 18, 19 drives a second electric generator 15.

(15) The steam exiting the low-pressure steam turbine 19 is condensed to water in a water-cooled condenser 21 and then pumped as feedwater back to the heat recovery steam generator 16 by means of a feedwater pump 26. The condenser 21 is part of the cooling water circuit 23 containing the cooling water pump 22. The condenser 21 can have an insulation 24 (dashed line in FIG. 2). The condenser 21 can be evacuated by means of vacuum pump 25. Furthermore, steam filling line 27 with a steam filling valve 28 may be provided to fill the condenser 21 with steam from a steam source within the steam/water cycle 20. In the example of FIG. 1 with a steam source is situated at the high-pressure steam turbine 17.

(16) Now, after a shut-down of the steam turbine 17, 18, 19 and gas turbine 11 and/or combustor 13 (where usually vacuum is fully or partial broken), at first a good vacuum has to be restored in the condenser 21 by means of the evacuation pump 25.

(17) Then, the condenser 21 and the low-pressure steam turbine 19 will be filled with steam from vacuum up to slightly above atmospheric pressure (approx. 1 bar) in a short time. This is to avoid any air leakage into the condenser 21 as soon as the evacuation pump 25 and cooling water pump 22 are shut down. The pressure is controlled with a flow of said cooling water.

(18) Next, for restoration of vacuum before start up of the plant 10, the cooling water pump 22 will come into operation again and will establish full vacuum within the condenser 21 in a very short time.

(19) Finally, the plant 10 can be started up.

(20) The steam source to heat up and fill the condenser 21 with steam may be the gland steam of a steam-sealed gland or the LP steam bypass system. Further steam sources to establish the 1 bar conditions in the condenser 21 for the overnight shut down could be high-pressure (HP), intermediate pressure (IP) process steam, auxiliary steam or boiler, etc. To lower the steam consumption the condenser 21 with condenser neck and the other heat loosing components could be insulated by means of an insulation 24.

(21) In comparison to other methods to keep a good vacuum available for a quick warm or hot start of the plant 10 the auxiliary power for running pumps during the overnight shut down is saved.

(22) The invention thus has the following advantages: No auxiliary consumption for pumps or heaters during stand-still; only an insulation 24 of the condenser 21 may be necessary. No air ingress during stand-still: avoids O.sub.2 and CO.sub.2 peaks in the condensate during start-up; less stand-still corrosion in the LP system and condenser, i.e. less iron content in the condensate; The use of LP steam for the initial condenser heat-up would advantageously take credit of the heat excess available in the cold part of the HRSG (helps to avoid blowing safety valves in the LP-Drum).

(23) The Quick Vacuum Restoration according to the invention can be for water-cooled steam turbine condensers.

(24) The Quick Vacuum Restoration according to the invention is a measure to shorten the start up time of the plant. This is an important market request for power plants with an over night shut down and daily start up of the plant.