EP2412937A1 - Steam turbine and method for cooling same - Google Patents

Abstract

The turbine (1) has a flow duct (4) formed between a stator (2) and a rotor (3). Blades (33) of the rotor and guide vanes (23) of the stator are arranged alternately in the flow duct. A fresh steam feed line (5) feeds fresh steam into an inflow region (41) of the flow duct such that the fresh steam is circulated around the rotor blades and the guide vanes. A cooling steam feed line (6) feeds cooling steam into a region (34) of the rotor. A pressure compensation cross connection (7) is provided between the flow duct and the cooling steam feed line. An independent claim is also included for a method for cooling a steam turbine.

Description

The invention relates to a steam turbine according to the preamble of claim 1 and to a corresponding method for cooling such a steam turbine according to claim 6.

Steam turbines are operated with live steam, which may have a temperature of several hundred degrees, as a working medium. For this purpose, the live steam is flowed into a flow channel, which is formed between the rotor and stator, so that it flows around the projecting into this channel guide vanes of the stator and blades of the rotor. As a result, the live steam expands to a lower pressure and cools down. The thereby released thermal energy is converted into rotational energy of the rotor, which can be used to drive a rotor coupled to the generator or a working machine.

High outputs of the steam turbine require correspondingly high operating temperatures of the live steam and thus an increased thermal load of individual components of the steam turbine. However, these components, which are subject to particularly high thermal loads, must be sufficiently cooled in order to ensure the safe operation of the steam turbine.

From the EP 2 067 933 For this purpose, a device is known in which the steam turbine in addition to the live steam in addition cooling steam is supplied externally. Via a corresponding supply line to the outer housing of the stator of the turbine, a Außengehäusekühlbohrung, a flow space between the outer and inner casing of the stator and a Innengehäusekühlbohrung cooling steam is thus introduced into the particularly thermally stressed region of the steam turbine, here the thrust balance piston of the rotor so that it specifically cooled becomes. Additional sealing elements separate this cooling steam space from the adjacent live steam space. These sealing elements must be there On the one hand be as tight as possible, even to prevent a reverse flow of cooling steam in the live steam chamber even with a change in the steam conditions, as they occur during a load change. On the other hand, the sealing elements but must be leaking enough to ensure a sufficiently rapid pressure relief in the case of a turbine quick shutdown. These sealing elements must therefore be designed for both, but conflicting requirements.

Moreover, from the EP 2 067 933 a version is known in which an additional external cross-line between the external live steam and cooling steam supply line of the steam turbine is provided. This transverse line serves to additionally supply cooling steam to the live steam in the event of a sudden pressure drop in the live steam feed line in order thus to avoid an excessive differential pressure load between the region to be cooled and the inflow region of the flow channel.

The object of the invention is to provide an improved steam turbine and an improved method for cooling such a steam turbine.

This object is achieved with the steam turbine having the features of claim 1, and with the corresponding method having the features of claim 6.

According to the invention, it is provided that a portion of the live steam from the flow channel can thus be fed directly to the cooling steam by an additional pressure equalization cross-connection between the flow channel and the cooling steam supply. This leads to a thermodynamic coupling and thus to a steady pressure equalization between the live steam space and the cooling steam space of the turbine via this cross connection. The additional sealing elements which delimit the area subjected to high thermal stress, such as, for example, the thrust balance piston of the rotor engaging in the stator, thus do not have to be delimited from the area with live steam As high demands are made because the pressure difference between the two rooms is lower.

If one end of the pressure equalization transverse connection opens radially outward in the flow channel, the radial pressure balance downstream of a blade can be utilized for pressure equalization during operation of the turbine. Physically, in fact, a pressure difference with a higher static pressure on the radially outer side of the flow channel exists in the swirl-adhering flow generated in the flow channel. After a guide vane thus the stator inner housing is subjected to a higher pressure than the rotor. This higher pressure applied to the pressure equalization cross-connection also establishes a higher pressure in the cooling-steam space via the pressure-equalizing cross-connection directly. Thus, even with a load change during operation, there is no local reversal of the flow direction. In addition, in the case of a turbine rapid shutdown with the pressure equalization cross-connection, a space connection between live steam and cooling steam through which a cooling steam surplus can be emptied directly, so that the sealing elements are less stressed.

Preferably, the pressure equalization transverse connection is arranged in the inner housing of the stator and here in particular close to the inflow region of the flow channel, so that the locally highest pressure of the flow channel can be tapped. If the pressure equalization cross-connection also opens into the cooling steam feed close to the area subjected to high thermal stress, short passageways of the pressure-compensating cross-connection can be achieved.

The invention will now be explained by way of example by way of example. Shown is the section through a steam turbine 1, with a stator 2, with inner housing 21, with outer housing 22 and a rotor 3. Between the stator 2 and the rotor 3, a flow channel 4 is formed, in which in the axial direction alternately blade rows 33 of the rotor 3 and Guide vanes 23 of the stator 2 are arranged. Via a live steam feed 5, live steam is fed to an inflow region 41 of the flow channel 4. The so-streamed live steam then flows downstream in the flow channel 4, the rotor 33 and vane rows 23, expands and cools. The thermal energy released thereby causes the rotor 3 to rotate. By now rotating in the fixed stator 2 rotor 3 locally thermally highly loaded areas 34 can arise, which must be cooled. Such a region is for example the Schaubausgleichskolben formed on the rotor 35, which moves through the rotating rotor 3 in a corresponding recess of the stator 2.

For cooling such highly stressed regions 34, therefore, an additional cooling steam supply 6 is provided. The cooling steam supply 6 comprises in the present embodiment, an external supply line 61 from the outside to the outer housing 22, a Außengehäusekühlbohrung 62, a flow space 63 between the outer housing 22 and inner housing 21 and at least one Innengehäusekühlbohrung 64. Both the cooling steam supply and the live steam supply, as in the figure indicated, additional valves for controlling the respective amount of steam. In addition, additional (but not shown here) sealing elements are provided for the separation of the two steam rooms in the turbine 1 at the points at which the live steam space and the cooling steam space are particularly close to each other. Due to the pressure difference between cooling and live steam, however, particularly high demands must be placed on these sealing elements. On the other hand, the sealing elements must also be designed so that they are "permeable" in the case of an emergency shutdown to quickly reduce a cooling steam surplus.

In order to keep the requirements of such sealing elements as low as possible according to the invention therefore a pressure compensation transverse connection 7 between the flow channel 4 and the cooling steam supply 6 is provided. In the embodiment shown in the figure, this cross-connection 7 is close to Inflow 41, the live steam in the flow channel 4 and the thermally highly loaded zone 34 is provided. The pressure equalization transverse connection 7, which is formed, for example, as a bore in the inner housing 21 of the stator 2, allows a portion of the live steam from the flow channel 4 to be fed directly to the cooling steam. This creates a pressure equalization between live steam room and cooling steam space through this cross connection. At the same time, the cross-connection can be used in the case of an emergency shutdown as a "bypass" and thus dissipate excess coolant from the cooling steam space in the live steam space. Overall, so lower demands on the sealing elements can be made, which has a significant reduction in material costs result.

The present invention is not limited to the previously described embodiments. Rather, combinations, modifications or additions of individual features are conceivable that can lead to further possible embodiments of the inventive idea. Thus, the pressure equalization transverse connection could also lead directly into the area of high thermal stress flowed through by cooling steam. The part of the live steam from the flow channel would then be supplied to the cooling steam only in this area. As indicated in the figure, the pressure compensating transverse connection can consist of a radially and an axially aligned region, but it could also lead, as a straight bore, obliquely through the inner housing from the flow channel to the inner housing cooling bore.

Claims (7)

Steam turbine (1) with a stator (2) which comprises an inner (21) and an outer housing (22), a rotor (3), a flow channel (4) formed between the stator (2) and the rotor (3) the alternately rows of blades (33) of the rotor (3) and stator rows (23) of the stator (2) are arranged, a live steam supply (5) for supplying live steam in an inflow region (41) of the flow channel (4), so that the live steam the Rotor (33) and vanes (21) in the flow channel (4) can flow around and a cooling steam supply (6) for supplying cooling steam in a thermally highly stressed region (34) of the rotor (3) characterized by
a pressure equalization transverse connection (7) between the flow channel (4) and the cooling steam supply (6). Steam turbine (1) according to claim 1,
characterized in that the cooling steam supply (6) comprises a feed line (61) to the outer housing (22), an outer housing cooling bore (62), a flow space (63) between the outer and inner housings and at least one inner housing cooling bore (64) and the pressure equalization transverse connection (7). a bore in the inner housing (21) which extends from the flow channel (4) to the inner housing cooling bore (64). Steam turbine according to claim 1 or 2,
characterized in that pressure equalization transverse connection (7) attaches radially outward on the flow channel (4). Steam turbine according to one of claims 1 to 3,
characterized in that the pressure equalizing transverse connection (7) in the region of the inflow region (41) of the flow channel (4) and the thermally stressed region (34) in the inner housing (21) is formed. Steam turbine according to one of claims 1 to 4,
characterized in that the thermally stressed portion (34) is a thrust balance piston (35) of the rotor (3). Method for cooling a steam turbine (1), wherein the steam turbine (1) fresh steam for flowing through a flow channel (4) formed between a stator (2) and a rotor (3) and cooling steam for cooling a thermally stressed portion (34) of the rotor ( 3) is supplied,
characterized in that a part of the live steam from the flow channel (4) is supplied to the cooling steam. Method according to claim 6,
characterized in that the supply of live steam from the flow channel (4) in the region of the inflow region (41) of the flow channel (4) and the thermally stressed region (34) of the rotor (3) in the inner housing (21) of the stator (2) ,

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