EP2511485A1 - Turbomachine, Steam Turbine plant, and Method for heating a steam turbine shaft - Google Patents

Abstract

The turbo-machine has a rotatably mounted shaft (10) inside the housing (8,9), where the shaft has a thermally stressed area. A unit (20) is provided for supplying a hot steam to the thermally highly stressed area. The housing has an outer housing that is arranged outside an inner housing. The shaft has a relief groove (15) with a smaller diameter, where the unit is designed such that the hot steam is passed through the relief groove. The shaft is designed as double-flow, where the relief groove is arranged in an inlet area (7) that is formed for supplying the steam. Independent claims are included for the following: (1) a steam turbine plant with a steam generator; and (2) a method for warming a steam turbine shaft.

Description

The invention relates to a turbomachine comprising a housing and a rotatably mounted within the housing shaft, wherein the shaft has a region which is thermally stressed. Furthermore, the invention relates to a steam turbine plant and a method for heating a steam turbine shaft.

Under a turbomachine, for example, a steam turbine is understood. During operation of a steam turbine, a live steam with comparatively high steam parameters, such as pressure and temperature, flows into an inflow region of the steam turbine. Usually, a steam turbine is subdivided into a high-pressure turbine part, medium-pressure turbine part and low-pressure part turbine. The high-pressure turbine section experiences a live steam with the highest steam parameters. Steam turbines are used inter alia for municipal power generation, to the steam turbine, an electric generator is connected, which is connected to an electrical consumer network. Steam turbine plants are characterized by high availability, which means that a steam turbine plant is in a state of continuous operation. This is partly because the heating of a steam turbine takes a comparatively long time, since a steam turbine is made of thick-walled materials. Thus, during a warm-up phase, temperature gradients arise within the thick-walled components. In a continuous operation, the temperatures are almost constant. This means that the service life of the components can be extended if the temperature changes during transient operation are kept to a minimum. If the load is changed in a steam turbine plant, this load change leads to a change in temperature in the case of throttling the turbine inlet valves. This is especially the case with steam turbines, the be operated at a fixed pressure, which are used in particular in nuclear power plants. The temperature change causes a temperature difference in the thick-walled components as a result of the temperature transient. Such temperature differences lead to elongation fatigue fatigue and thereby limit the life of the steam turbine as a whole. Due to the increasing share of regenerative energies and the resulting temporal fluctuations in power generation and demand, the demands on load changes of nuclear power plants are increasing. These load changes pose challenges to the amount of load change as a whole, as well as the rate of load change.

The number of load changes is an important output for the design of the steam turbine. Depending on material characteristics, the permissible limits for component temperature differences are taken into account. High load cycles lead to small permissible temperature differences and thus ultimately to low load change speeds and start times. It may be that a steam turbine shaft must be replaced prematurely, if higher load change speeds are desired with the same number of load changes.

It would be desirable to further develop a steam turbine such that the temperature differences are reduced with load changes.

At this point, the invention begins, whose task is to specify a steam turbine, which has lower temperature differences at a load change.

The object is achieved by a turbomachine comprising a housing and a rotatably mounted within the housing shaft, wherein the shaft has a region which is thermally stressed, wherein means are provided for supplying hot steam to the thermally highly stressed area. The object is further achieved by a steam turbine plant with a steam turbine, a steam generator, a live steam control valve, a live steam quick-closing valve, wherein a steam generated in the steam generator live steam through the live steam control valve and the live steam quick-closing valve is flown into the steam turbine, wherein a Branch, which is fluidically connected to the means for supplying hot steam, wherein the branch is fluidly connected to the steam generator.

Furthermore, the object is achieved by a method for heating a steam turbine shaft, wherein the steam turbine shaft has a thermally loaded area and this area is traversed by an unthrottled steam from a live steam line.

In conventional operation, changes in temperature cause changes in the temperature due to throttling of the steam. When the load drops, the temperature drops and the load rises again to the initial value. With the invention, the temperature is kept constant by the throttling for the highly loaded area is virtually bypassed. The advantage is that a complete temperature cycle of waste and recovery is prevented. Thus, not only the load drop, but also the entire load change is affected.

The invention is based on the idea that a temperature difference in a thick-walled component of a steam turbine can be limited by the fact that this thermally highly loaded area is flown with hot steam. This thermally highly stressed area is thermally stressed during a continuous operation by the flow of live steam. In case of a load drop, part of the thermal load due to the live steam is eliminated. A cooling of the thick-walled component would be the result, with too rapid cooling leads to temperature differences that are undesirable. By flowing with a hot steam shortly after the load drop, a change in the temperature and thus a temperature difference avoided, which leads to an overall lifetime of the thick-walled component is extended. Thus, an essential idea of the invention is that after a load drop, a thermally loaded component of the steam turbine is flowed through with a hot steam, thereby avoiding a temperature difference.

A load dump or load drop is a special form of load reduction.

In the dependent claims advantageous developments are given.

Thus, the turbomachine is further developed in an advantageous development such that the turbomachine is designed as a steam turbine and the housing has an inner housing and an outer housing arranged around the inner housing. Thus, the invention is oriented to use in a high-pressure turbine section or medium-pressure turbine section. Nevertheless, an application of the invention is also possible in a low-pressure turbine part.

In a further advantageous embodiment, the shaft has a relief groove with a smaller diameter, wherein the means is designed such that the hot steam is guided to the relief groove. A relief groove in a shaft is an area that is characterized by a smaller diameter than the rest of the shaft. The shaft usually includes a flow channel-like region, are provided in the grooves for turbine blades. This area is subject to different thermal loads. Thus, in the entrance area of this flow channel, the shaft is subjected to a higher thermal load than the rear outflow area of the flow channel. Particularly in the front inflow area, the shaft is particularly heavily loaded. Therefore, a relief groove is arranged in the shaft in the front region.

Furthermore, it should be noted that the highest loaded area is the first blade groove.

In a further advantageous development, the shaft is designed to be double-flowed and the relief groove is arranged in an inflow region, the inflow region being designed to supply live steam. In addition to an application in the single-flow area, the invention is also possible in a steam turbine with a twin-flow design. Thus, the variable use of the invention is significantly increased.

In a further advantageous development, an inflow ring is arranged above the relief groove, which is formed such that the live steam is not guided to the relief groove. An inflow ring is characterized in that it is arranged around the shaft, in particular around the relief groove, and keeps the live steam from flowing directly to the shaft, in particular to the relief groove. This means that the live steam is directed almost directly to the first turbine blades in the flow channel.

In a particularly advantageous development, the means for supplying hot steam is designed such that the hot steam flows between the inflow ring and the relief groove.

During a load change, as it were, the thermal load from the temperature changes caused by throttling of the live steam to the inflow area is eliminated. A lower thermal load of the inflow of the shaft is therefore the result. According to the invention, it is now proposed that between the inflow ring and the relief groove, a hot steam with corresponding steam parameters is flowed through which experiences no temperature change due to throttling. The hot steam must therefore have steam parameters that result in a thermodynamic situation that is comparable to the situation when live steam flows into the turbomachine.

For this purpose, the invention proposes to remove unthrottled live steam after the steam generator in a steam turbine plant and to flow into the area between the relief groove and the inflow.

In an advantageous development, a seal between the inflow ring and the shaft is arranged. This seal can be realized according to the invention by a labyrinth or brush seal. The advantage here is that the hot steam that flows in between the relief groove and the inflow ring can flow out of this area more poorly and thus ensures an additional temperature increase and thus better heating of the shaft via the supplied friction power. The goal would be to avoid premixing with live steam, thereby allowing a targeted heating of the compensation groove.

In a further advantageous development, the means for supplying hot steam is conducted in a vapor-tight manner through the outer housing and the inner housing. This ensures that no hot steam is lost on the way to the area between the relief groove and the inlet ring. The invention can thus be referred to as an active heater, which is used in the thermally highly stressed area. The supply of hot steam in this area between inflow and relief groove is variably controllable via a valve.

The steam turbine plant is characterized essentially by the fact that after the live steam generator, a live steam control valve and a live steam quick-acting valve is arranged in the live steam line, wherein the live steam leads via the live steam line into the turbomachine into an inflow region.

According to the invention, a heating line is branched off from this steam line, the steam-tight by the outside and Inner housing is guided and opens into a region between the relief groove and inflow.

In an advantageous development, the diversion between the live steam quick-closing valve and the live steam control valve is arranged.

In a further advantageous development, means such as a valve for regulating the flow rate, with which the flow rate of the hot steam can be regulated, are arranged in the branch.

The inventive method for heating a steam turbine shaft is characterized in particular by the fact that the thermally loaded area of the steam turbine shaft is flowed through with an unthrottled steam from a live steam line during a load drop.

Thus, the inventive idea is pursued here, to compensate for the elimination of the thermal stress as a result of a load change by deliberately supplying hot steam from the main steam line.

Figur 1

eine schematische Übersicht einer Dampfkraftanlage,

Figur 2

eine schematische Übersicht eines Querschnitts einer Dampfturbine,

Figur 3

eine Schnittansicht eines Teils einer Dampfturbine.

In the following, a preferred embodiment of the invention will be explained in more detail with reference to the accompanying schematic drawing. Show it:

FIG. 1

a schematic overview of a steam power plant,

FIG. 2

a schematic overview of a cross section of a steam turbine,

FIG. 3

a sectional view of a part of a steam turbine.

The FIG. 1 shows a schematic overview of a steam turbine plant 1, which is through a steam generator 2, arranged from the steam generator 2 main steam line 3, arranged in the main steam line 3 quick-closing valve 4, a fluidically with the main steam line 3 connected control valve 5 and a steam turbine 6 characterized. The main steam line 3 opens into an inflow region 7 of the steam turbine 6.

The in the FIG. 1 illustrated steam turbine 6 comprises substantially an outer housing 8 and an inner housing 9 and a rotatably mounted within the outer 8 and inner housing 9 shaft 10. The shaft 10 includes turbine blades disposed substantially on the shaft surface. In the inner housing 9 turbine blades are also arranged as turbine vanes, with the turbine blades and vanes, a flow channel 11 is formed. The in the FIG. 1 selected steam turbine 6 comprises two flow channels 11, since it is a double-flow embodiment of a steam turbine 6. This means that after the inflow region 7, the incoming fresh steam divides into a left-hand flood 12 and a right-hand flood 13. The live steam here cools off in the left-hand flow 12 and in the right-hand flow 13, so that, in particular in the inflow region 7, the shaft 10 is subjected to particularly high thermal stress. The steam turbine 6 therefore has an inlet ring 14 arranged around the shaft 10. The shaft 10 further has a relief groove 15, which has a smaller diameter than the shaft 10 in the flow channel 11. During operation, therefore, the live steam first flows onto the inflow ring 14 and not onto the shaft surface in the relief groove 15. Nevertheless, the area around the relief groove 15 heats up during operation to a comparatively high operating temperature. If a load drop occurs, the thermal load is reduced in the inflow region 7, which causes the temperature in the relief groove 15 is automatically reduced.

But this would lead to temperature differences that are undesirable. Therefore, a branch 16 is additionally introduced, which leads to an additional heating line 17. The heating line 17 is fluidically connected on the one hand with the steam generator 2 and with the relief groove 15. The means that located in the heating line 17 live steam flows as hot steam into the relief groove 15 and there prevents a cooling due to the load drop cooling and thus ultimately prevents a temperature difference.

In the heating line 17, a valve 18 is arranged, which is simply opened in the event of a load drop. Thus, unthrottled live steam is flowed through in the region between the inflow ring 14 and the relief groove 15. This type of heating can be switched off at low Einströmdrücken if the pressure difference across the inflow ring 14 exceeds a limit to be set without changing the stress on the original driving style.

This avoids the temporary drop in temperature during load changes as a result of load loss due to active heating. The resulting reduction of temperature differences can significantly increase the allowable number as well as the allowable amplitude of load changes without having to replace the shaft before the specified life has expired. This improves overall operational flexibility. Another advantage is that due to the reduced stress strain of the relief groove 15 it can be cut deeper and thus the notch effect of the first blade groove is reduced.

The turbomachine 6 designed as a steam turbine 6 accordingly comprises a housing 8, 9 and a shaft 10 rotatably mounted inside the housing 8, 9, the shaft 10 having a region 19 which is thermally stressed, means 20 for supplying hot steam to the thermal highly loaded area 19 are formed.

The FIG. 2 shows a part of a cross-sectional view of a turbomachine. To see is a part of the outer housing 8, the inner housing 9 and the shaft 10. Furthermore, the Inflow ring 14 and the means 20 for supplying hot steam.

The FIG. 3 shows a cross-sectional view of a part of the steam turbine 1. The inflow ring 14 and the relief groove 15 are formed such that a portion 21 is formed therebetween. In this area 21 flows hot steam, which leads to the heating of the shaft 10 at a load reduction.

Claims (17)

Turbomachine comprising a housing (8, 9) and a shaft (10) rotatably mounted within the housing (8, 9), the shaft (10) having a region which is thermally stressed,
marked by
Means (20) for supplying hot steam to the high thermal stress area. Turbomachine according to claim 1,
wherein the turbomachine is designed as a steam turbine. Turbomachine according to claim 1 or 2,
wherein the housing has an inner housing (9) and an outer housing (8) arranged around the inner housing (9). Turbomachine according to one of the preceding claims,
wherein the shaft (10) has a relief groove (15) with a smaller diameter and the means (20) is formed such that the hot steam leads to the relief groove (15). Turbomachine according to claim 4,
wherein the shaft (10) is formed in two columns and the relief groove (15) in the inflow region (7) is arranged, wherein the inflow region (7) is designed for supplying live steam. Turbomachine according to claim 4 or 5,
wherein over the relief groove (15) an inflow ring (14) is arranged, which is designed such that the live steam does not lead to the relief groove (15). Turbomachine according to claim 6,
wherein the means (20) for supplying hot steam is formed such that the hot steam flows between the inflow ring (14) and the relief groove (15). Turbomachine according to claim 6 or 7,
wherein a seal between the inflow ring (14) and the shaft (10) is arranged. Turbomachine according to claim 8,
wherein the seal is formed as a labyrinth or brush seal. Turbomachine according to one of claims 3 to 9, wherein the means (20) for supplying hot steam is guided in a vapor-tight manner through the outer housing (8) and the inner housing (9). Steam turbine plant with a steam turbine according to one of claims 1 to 10,
a steam generator (2),
a live steam control valve (5),
a live steam quick-acting valve (4),
wherein a steam generated in the steam generator (2) by the live steam control valve (5) and the live steam quick-closing valve (4) can be flowed into the steam turbine,
marked by
a branch (16) fluidly connected to the means (20) for supplying hot steam,
wherein the branch (16) is fluidically connected to the steam generator (2). Steam turbine plant according to claim 11,
wherein the branch (16) between the live steam control valve (5) and the live steam quick-closing valve (4) is arranged. Steam turbine plant according to claim 11 or 12,
wherein between the branch (16) and the means (20) for supplying hot steam, a valve (10) is arranged. Method for heating a steam turbine shaft (10),
wherein the steam turbine shaft (10) has a thermally loaded area and this area is flowed with an unthrottled steam from a live steam line. Method according to claim 14,
wherein the unthrottled steam is supplied between an inflow ring (14) and a relief groove (15) of the shaft (10). Method according to claim 14 or 15,
wherein the unthrottled steam vapor-tight through an outer housing (8) and an inner housing (9) of the steam turbine (6) is guided. Method according to one of claims 14 to 16,
wherein the unthrottled steam after a load drop of the steam turbine (6) is supplied.

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