Method for cooling down a steam turbine

Abstract

A steam-turbine unit has a steam turbine and an option for cooling the steam turbine by forced cooling, wherein cooling air is drawn through the steam turbine via a suction device and a drainage line of the live-steam valve is used as the access option.

Claims

1. A steam turbine unit comprising: a steam turbine which comprises a steam inlet region, an exhaust steam region and a blading region which is surrounded by a turbine housing and is arranged axially in between, a cooling fluid inlet which is closeable and openable by a closure member, and which is arranged upstream of the exhaust steam region with respect to a flow direction of steam, a valve comprising a steam inlet and a steam outlet, and a drainage device comprising: a junction that is disposed downstream of the steam inlet and upstream of the steam turbine; and a drainage device line that connects the junction to the cooling fluid inlet and to a drain, wherein during normal power operation the steam flows through the valve, through the junction, and into the steam turbine, and the drainage device line leads drainage from the junction toward the drain in a drainage direction, and wherein during a cooling operation cooling fluid flows from the cooling fluid inlet, through the drainage device line in a direction opposite the drainage direction, to the junction, and then to the steam turbine.

2. The steam turbine unit as claimed in claim 1, further comprising a cooling fluid line from the cooling fluid inlet to the drainage device line through which the cooling fluid flows.

3. The steam turbine unit as claimed in claim 2, wherein the closure member is arranged in the cooling fluid line.

4. The steam turbine unit as claimed in claim 2, wherein a second closure member is arranged in the cooling fluid line.

5. The steam turbine unit as claimed in claim 4, wherein, between the closure member and the second closure member, the cooling fluid line comprises a second junction.

6. The steam turbine unit as claimed in claim 5, wherein the second junction is connected in terms of flow to a second drainage line, and a second drainage device or a steam trap for draining the cooling fluid line is arranged in said second drainage line.

7. The steam turbine unit as claimed in claim 6, wherein the second drainage line is connected in terms of flow to a condenser.

8. A method for cooling the steam turbine unit of claim 1, the method comprising: after a power cut-off, performing a cooling operation by conducting the cooling fluid flowing through the cooling fluid inlet, through the drainage device line in the direction opposite the drainage direction, through the junction, and then through the steam turbine while at the same time absorbing heat, through the turbine housing.

9. The method as claimed in claim 8, wherein the cooling fluid flows via a closure member in a cooling fluid line that connects the cooling fluid inlet to the drainage device line.

10. The method as claimed in claim 9, further comprising: arranging a second closure member in the cooling fluid line, and wherein the cooling fluid line between the closure member and the second closure member comprises a second junction, arranging a second drainage device or steam trap in a second drainage line which is connected in terms of flow to the second junction.

11. The method as claimed in claim 10, wherein the closure member and the second closure member comprise limit switches, and starting of the steam turbine is possible only with closure member closed and second closure member closed.

12. The method as claimed in claim 8, wherein the cooling fluid comprises air.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) In the drawings:

(2) FIG. 1 shows a schematic illustration of the forced cooling,

(3) FIG. 2 shows a steam turbine unit, and

(4) FIG. 3 shows a cross-sectional view of a valve.

DETAILED DESCRIPTION OF INVENTION

(5) FIG. 1 shows a schematic illustration of part of a steam turbine unit 1. Live steam flows via a steam generator (not illustrated specifically) into a first steam line 2 through a quick closure valve 3 and an adjusting valve 4. After the adjusting valve 4, the steam flows via a second steam line 5 into a steam turbine 6. The steam flows here into a steam inlet region (not illustrated specifically) and flows from an exhaust steam region out of the steam turbine 6 via a third steam line 7. The third steam line 7 is connected in terms of flow to a condenser 8, wherein a further valve 9 is arranged in the third steam line 7. The condenser 8 is connected in terms of flow via a line 10 to a suction device 11. Furthermore, a cooling fluid line 12 is arranged on the quick closing valve 3 or adjusting valve 4. A closure member 13 is arranged in the cooling fluid line 12.

(6) During the forced cooling, the closure member 13 is opened and a cooling medium, such as, for example, cooling air, passes via the cooling fluid line 12 through the quick closing valve 3 or adjusting valve 4 into the second steam line 5 and from there into the blading region of the steam turbine 6. This forced flow takes place by the fact that the valve 9 is opened and a forced flow is achieved via the suction device 11.

(7) FIG. 2 shows an expanded steam turbine unit 14. Live steam is produced here in a steam generator 15 and is supplied to a high pressure partial turbine 16 via a first live steam line 45. In the first live steam line 45, a first valve 17 and a second valve 18 are arranged successively. The live steam generated in the steam generator 15 flows here via the first live steam line 45 and the first valve 17 and second valve 18 into the high pressure partial turbine 16 and from there via an exhaust steam region and a first exhaust steam line 19 into the resuperheater of the steam generator 15.

(8) In the steam generator 15, the steam flowing out of the high pressure partial turbine 16 is resuperheated, i.e. brought to a higher temperature, in a resuperheater 15b and is conducted via a hot superheater line 20 and a first intermediate pressure valve 21 and a second intermediate pressure valve 22 into an intermediate pressure partial turbine 23. The first intermediate pressure valve 21 is designed as a quick closing valve. The second intermediate pressure valve 22 is designed as a control valve.

(9) The steam flowing out of the immediate pressure partial turbine 23 flows via an overflow line 24 into a low pressure partial turbine 26. The low-pressure partial turbine 26 is supplied with additional steam via an additional line 27 and an additional valve 28. The steam flowing out of the low pressure partial turbine 26 passes into a condenser 29 and condenses there to form water.

(10) A junction 30 is arranged between the first valve 17 and the second valve 18. The first valve 17 is designed as a quick closing valve. The second valve 18 is designed as a control valve. A branch line 31 which leads into a drainage line 32 is arranged at said junction 30. The branch line 31 furthermore has a flange 33. A cooling fluid line 34 is coupled to said flange 33. A closure member which has a first closure member 35 and a second closure member 36 is arranged in said cooling fluid line 34. A second junction 37 is arranged between the first closure member 35 and the second closure member 36, wherein the second junction 37 is connected to a further branch line 38. A steam trap 39 for draining the steam in the further branch line 38 is arranged in said further branch line 38.

(11) The hot superheater line 20 is of virtually identical design to the junction 30. A separate description has therefore been omitted, and the reference signs adopted for the forced cooling components located in the hot superheater line 20.

(12) During normal operation, the steam flows into the high pressure partial turbine 16 via the first live steam line 45, wherein drainage is carried out via the junction 30 and the drainage line 32. The first closure member 35 and the second closure member 36 are closed here.

(13) In the case of forced cooling, a supply of cooling medium to the first closure member 35 is permitted, wherein the first closure member 35 and the second closure member 36 are opened. The cooling medium may be cooling air. A double shut-off with intermediate low point drainage is referred to here. The double shut-off can either be integrated in a fully automized manner into the turbine process control technique or operated manually. In the second case, the double shut-off has to be provided with limit switches. It can thus be ensured that the starting of the steam turbine 6 takes place only when the fittings are closed. For the sake of clarity, the suction device 11 is not illustrated in FIG. 2. The suction device 11 would be coupled to the first closure member.

(14) In a virtually identical manner, the intermediate pressure partial turbine 23 is likewise supplied with cooling medium. The cooling medium may be cooling air.

(15) FIG. 3 shows a cross-sectional view of a valve 40, which can be designed, for example, as second valve 18 or first valve 17. The valve 40 comprises a valve housing 41 and a valve cone (not illustrated specifically).

(16) Steam flows via a valve inlet 42 through the valve 40 and passes via the valve outlet 43 to the high pressure partial turbine 16 or low pressure partial turbine 23. A drain 44 is arranged at a geodetically favorable location. Said drain 44 is connected to a drainage line 46. A flange 33 to which the cooling fluid line 34 is connected is arranged in said drainage line 46.

(17) Although the invention has been illustrated in more detail and described in detail by the preferred exemplary embodiment, the invention is not restricted by the disclosed examples and a person skilled in the art may derive other variations therefrom without departing from the scope of protection of the invention.