The invention relates to a steam turbine unit comprising a steam turbine which has 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, and furthermore is designed with a suction device for sucking cooling fluid out of the turbine housing, wherein at least one cooling fluid inlet is provided which is closeable and openable by a closure member, is arranged upstream of the exhaust steam region—with respect to the flow direction of action steam flowing through the turbine housing during normal power operation—and through which, after a power cut-off, cooling fluid for cooling to a temperature below the operating temperature can be introduced into the turbine housing, wherein the steam turbine unit furthermore comprises a valve through which the cooling fluid flows, wherein the valve has a drainage device for draining the valve, wherein the drainage device comprises a drainage line.
In a steam turbine, in particular a high pressure turbine or an intermediate pressure turbine with upstream resuperheating, temperatures of over 500° C. occur during a power operation. During such a power operation, which may last for some weeks or months, the turbine housing and also the turbine rotor and other turbine components, such as live steam valve, quick closure valve, turbine blades etc. are heated to a high temperature. After the entire steam turbine unit is shut down, the turbine rotor of a turbine can continue to be rotated at a reduced speed by means of a rotational device for a predetermined period of time and the steam atmosphere can be evaluated via an evacuation device. In order to be able to carry out maintenance or checking work and possible retrofitting work as soon as possible after the steam turbine has been shut down, it may be desirable under some circumstances to cool the steam turbine as rapidly as possible with predetermined limits for expansion differences occurring between turbine rotor and, for example, turbine housing being observed.
For this purpose, it has proven successful to put what is referred to as forced cooling into service. In this case, a cooling fluid is passed through the steam turbine via a suction device and introduction of air and, as a result, forced cooling is achieved. The procedure here is as follows: in the forced cooling situation, the exhaust steam region is coupled in terms of flow to a suction device and, at the live steam valve, the supply of cooling fluid is permitted via a plug or a small housing opening. The removal of the plug or the production of a small housing opening is comparatively awkward and requires a large amount of time. Furthermore, a live steam valve, because of its design, has to have a correspondingly small opening. Furthermore, a special tool is required for releasing the plug or the small housing opening.
The invention intends to provide a remedy for this and to specify an option as to how a cooling fluid can be supplied more simply for the forced cooling.
This object is achieved by a steam turbine unit comprising a steam turbine which has 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, and furthermore is designed with a suction device for sucking cooling fluid out of the turbine housing, wherein at least one cooling fluid inlet is provided which is closeable and openable by a closure member, is arranged upstream of the exhaust steam region—with respect to the flow direction of action steam flowing through the turbine housing during normal power operation—and through which, after a power cut-off, cooling fluid for cooling to a temperature below the operating temperature can be introduced into the turbine housing, wherein the steam turbine unit furthermore comprises a valve through which the cooling fluid flows, wherein the valve has a drainage device for draining the valve, wherein the drainage device comprises a drainage line, wherein the drainage device has a junction which is connected in terms of flow to the cooling fluid inlet.
Furthermore, the object is achieved by a method for cooling a steam turbine having a turbine housing, in which, after a power cut-off, a cooling fluid inlet is connected in terms of flow to the turbine housing, and cooling fluid, in particular air, flowing through the cooling fluid inlet is conducted, while at the same time absorbing heat, through the turbine housing by means of a suction device in the direction of the action steam flowing through the steam turbine during the normal power operation, wherein the cooling fluid flows through a valve, characterized in that the valve has a drainage device through which the cooling fluid flows.
The invention therefore pursues the route of realizing the supply of air not via the plug or the small housing opening, but rather via an additional connection, which can be shut off, on the drainage line. Drainage lines are customarily arranged at a geodetically low point of the valve, wherein most valves have such a drainage line. According to the invention, it is now proposed to arrange a separate branch on the valve drain and to permit the supply of cooling air via said branch.
The awkward removal of the plug or the production of a small housing opening on the valve is therefore entirely dispensed with. Furthermore, no special tool for releasing the plug is required.
Advantageous developments are specified in the dependent claims.
In a first advantageous development, a cooling fluid line through which the cooling fluid flows and is sucked through the steam turbine via the suction device and leads to effective cooling is connected via the junction.
In an advantageous manner, the closure member is arranged in the cooling fluid line, wherein, advantageously, a second closure member is arranged in the cooling fluid line.
A second branch is arranged between the first closure member and the second closure member of the cooling fluid line, wherein the second branch is connected in terms of flow to a second drainage line, and a second drainage unit or a steam trap for draining the cooling fluid is arranged in said second drainage line.
In an advantageous manner, the second drainage line is connected in terms of flow to a condenser. The water which accumulates in the steam trap is therefore effectively conducted away.
The above-described properties, features and advantages of this invention and the manner in which they are achieved will become clearer and more clearly comprehensible in conjunction with the description below of the exemplary embodiments which are explained in more detail in conjunction with the drawings.
Exemplary embodiments of the invention are described below with reference to the drawings. The latter are not intended to illustrate the exemplary embodiments to scale; rather, the drawing where useful for the explanation is realized in schematized and/or slightly blurred form. With regard to additions to the teaching which is clearly visible in the drawing, reference is made to the relevant prior art.
In the drawings:
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.
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.
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.
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.
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.
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.
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
In a virtually identical manner, the intermediate pressure partial turbine 23 is likewise supplied with cooling medium. The cooling medium may be cooling air.
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.
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.
Number | Date | Country | Kind |
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14159049.7 | Mar 2014 | EP | regional |
This application is the US National Stage of International Application No. PCT/EP2015/051660 filed Jan. 28, 2015, and claims the benefit thereof. The International Application claims the benefit of European Application No. EP14159049 filed Mar. 12, 2014. All of the applications are incorporated by reference herein in their entirety.
Filing Document | Filing Date | Country | Kind |
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PCT/EP2015/051660 | 1/28/2015 | WO | 00 |