EP2657467A1 - Forced cooling for steam turbine assemblies - Google Patents

Abstract

The turbine plant (3) has a suction fan (6) coupled to a turbine outlet (5) or to a turbine inlet (4) of a turbine (29), where a process gas (15), particularly a water vapor, is flown in a flow direction (27) of the turbine inlet to the turbine outlet. A cooling medium (7) aspirated in the turbine is sucked by the suction fan over the turbine inlet in the process gas flow direction. The cooling medium is sucked over the turbine outlet against the process gas flow direction. The suction fan is coupled to the turbine outlet, particularly with an exhaust channel (9) at the turbine outlet. An independent claim is included for a method for cooling a turbine plant.

Description

The invention relates to a turbine plant, in particular a steam turbine plant, and a method for cooling a turbine plant, in particular a steam turbine plant.

Steam power plants or thermal power plants are widely known, for example from http://de.wikipedia.org/wiki/Dampfkraftwerk (available on 24.04.2012).

A steam power plant is a type of power plant for power generation from fossil fuels, in which a thermal energy of water vapor in a mostly multi-section steam turbine ( http://de.wikipedia.org/wiki/Dampfturbine , available on 24.04.2012) implemented in kinetic energy and continues to be converted into electrical energy in a generator.

In such a steam power plant, a fuel, for example coal, burned in a burner chamber, whereby heat is released.

The thus released heat is absorbed by a water tube boiler, shortly steam generator, and converts there fed, previously purified and treated (feed) water in steam / high pressure steam. By further heating the steam / high pressure steam in a superheater, the temperature and specific volume of the steam increase.

The generated high-pressure steam continues - via an inflow side, ie a so-called live steam side, short FD side, or a local supply line (FD supply line) - in a high pressure part of the steam turbine (high-pressure turbine) and performs there under relaxation and cooling mechanical work.

To achieve a high overall efficiency of the steam is after leaving the high-pressure part - over the exhaust steam side or a local Abdampfableitung - returned to the steam generator and reheated.

The (temporarily) superheated steam is introduced via an inflow side, i. here a so-called hot Zwischenüberhitzungsseite, short HZÜ side, or a local supply line (HZÜ supply line) - a medium-pressure section of the steam turbine (medium-pressure turbine) again fed and performs more mechanical work with further relaxation and cooling.

After leaving the medium-pressure section via the exhaust steam side or a local Abdampfableitung the steam flows - via an overflow - in a low-pressure part of the steam turbine (low pressure turbine section), where further mechanical work is done under relaxation and cooling to Abdampfdruck level.

By coupled to the steam turbine generator, the mechanical power is then converted into electrical power, which is fed in the form of electric power in a power grid.

The exhaust steam from the steam turbine or from the low-pressure turbine section flows via the exhaust steam side or a local Abdampfableitung in a condenser, where it condenses by heat transfer to the environment and collects as liquid water.

Through a condensate pump and a preheater through the water is temporarily stored in a feedwater tank and then fed via a feed pump to the boiler again, whereby a (water-steam) cycle of the steam power plant is closed.

A distinction is made between different types of steam power plants, such as coal-fired power plants, oil-fired power plants or gas-and-steam combined cycle power plants (Combined cycle power plants), according to their different types of steam generation or fuel for steam generation.

For example, a coal-fired power plant is a special form of steam power plant in which coal is used as the main fuel for steam generation. Such coal-fired power plants are known for lignite as well as hard coal.

In addition to the steam power plants also gas power plants or gas turbine power plants are known (http://de.wikipedia.org/wiki/Gasturbinenkraftwerk, available on 24.04.2012).

Such a gas turbine power plant is a power plant operated with petroleum products or with combustible gases, such as natural gas. These gases are in this case the fuel for a gas turbine (http://de.wikipedia.org/wiki/Gasturbine, available on 24.04.2012)), which in turn drives the coupled generator.

A combined cycle power plant is described in http://de.wikipedia.org/wiki/Gas- and-Dampf-Kombikraftwerk (available on 24.04.2012).

Such a combined cycle power plant is a power plant in which the principles of the gas power plant and the steam power plant are combined. The gas turbine serves as a heat source for a downstream waste heat boiler, which in turn acts as a steam generator for the steam turbine.

Work such as maintenance or repair work on a turbine of a power plant, such as on a steam turbine of a steam power plant, can be carried out only after a shutdown of a rotary operation of the turbine. This requires a shaft train The turbine of temperatures of about 600 ° C to be cooled below 100 ° C.

The steam turbine cools provisionally - without external intervention - in about 8 days or about 200 hours to less than 100 ° C or in about 6 days or about 150 hours to below 150 ° C from. The latter time represents the earliest possibility to shut down the shaft train or the shaft of the steam turbine, but this must then be further rotated by hand to avoid thermal, restricting the rotation deformations on rotating parts of the shaft train.

Even though gas turbines cool down faster than steam turbines due to their lower material compared to steam turbines, cooling times without external intervention are still high there.

In order to shorten revision times, it is desirable to minimize the cooling times of a turbine, such as a steam turbine but also a gas turbine or its sub-turbines, while maintaining permissible cooling rates.

In order to minimize these substantial cooling times, especially in steam turbines, a so-called forced cooling method is used (Forced Cooling of Steam Turbines, Performance Enhancement - Steam Turbine, Answers for Energy, Siemens AG, 2009).

In this Forced Cooling ambient air is sucked or blown as a cooling medium through the steam turbine or through their sub-turbines in a steam turbine - instead of the (high-pressure) steam - in its operational flow direction.

As - the suction flow through the steam turbine initiating - pressure sink is used in the forced cooling of the steam turbine downstream condenser, in its interior by means of vacuum pumps, for example by Elmo pumps, a negative pressure relative to the ambient air is generated (evacuation of the capacitor).

In order to ensure a cooling as possible of all hot steam turbine components, the ambient air must be able to act on all steam-carrying components of the steam turbine.

For this purpose, the ambient air - sucked in via the vacuum prevailing in the evacuated condenser - flows in via (Fön-) connection between quick-acting and control valves on the FD side and HZÜ side or the local FD or HZÜ supply line, respectively. whereby the cooling medium - then sucked by the negative pressure in the condenser - flows through the steam turbine or its sub-turbines in the operational flow direction of the steam.

Due to the cooling effect of the ambient air, the steam turbine or its components is cooled, thereby achieving a faster cooling of the steam turbine components.

Since permissible cooling gradients in the steam turbine components must not be exceeded, which could otherwise lead to component damage, the amount of ambient air drawn in via the pressure sink in the evacuated condenser must be regulated. As control organs serve this purpose, the control valves on the supply lines.

A disadvantage of the known forced cooling is the obligatory presence of the capacitor for generating the pressure sink or the suction flow of the cooling medium.

Meanwhile, however, increasingly steam turbine plants are realized with steam turbines without a low-pressure turbine part and then without a condenser, the steam turbines operate in a counter-pressure operation. In such back pressure steam turbine plants without a condenser, for example in counter-pressure steam power plants for seawater desalination plants, is the known forced cooling not applicable or are no other solutions known for forced cooling.

The invention has for its object to overcome the disadvantages and limitations of the prior art in a maintenance or overhaul of a power plant or a turbine, in particular a steam power plant or a steam turbine, in particular a counter-pressure steam power plant or a counter-pressure steam turbine without a condenser.

The invention is also based on the object, disadvantages and limitations in the prior art in cooling the power plant or the turbine, in particular a back pressure steam power plant or a back pressure steam turbine without a condenser, in particular in the case of turning off the rotary operation of the turbine to overcome.

The object is achieved by a turbine plant, in particular a steam turbine plant, and by the method for cooling a turbine plant, in particular a steam turbine plant, with the features according to the respective independent claim.

The turbine system relating to the invention has a turbine through which a process gas can flow during the operation of the turbine system in a flow direction from a turbine inlet to a turbine outlet.

According to the invention, it is provided that a suction fan is coupled to the turbine inlet or to the turbine outlet of the turbine.

Using this inventively provided, coupled to the turbine suction blower is by means of the - coupled to the turbine outlet - suction blown over the turbine inlet into the turbine sucked cooling medium in the operating process gas flow direction through the turbine or is a means of - with the turbine inlet coupled - Suction blower via the turbine outlet sucked into the turbine cooling medium against the operating process gas flow direction through the turbine blown.

According to the method for cooling a turbine system with a turbine, which is traversed by a process gas in operation in a flow direction from a turbine inlet to a turbine outlet, a cooling medium is sucked using a coupled with the turbine inlet or with the turbine outlet suction fan in the turbine and sucked in or against the operational process gas flow direction through the turbine, whereby the turbine is cooled by the cooling medium.

Expressed differently or simplified, the invention realized - in a turbine - by means of - coupled to the turbine inlet or with the turbine outlet - suction blower a pressure sink at the turbine inlet or at the turbine outlet.

Initiated by the pressure sink creates a suction flow in or against the process gas flow through the turbine through which a cooling medium - sucked on - in relation to the coupling side of the suction fan - respective other end of the turbine - is sucked in or against the process gas flow direction through the turbine. The turbine is cooled by the cooling medium sucked through the turbine.

The invention thus proves to be considerably advantageous in many respects.

By sucked through the turbine by the suction flow - in or against the process gas flow direction - all the steam-carrying components of the turbine are acted upon - and thus ensures a cooling of all hot components of the turbine. This achieves efficient, effective and rapid cooling of the turbine.

Thus, the invention can be used to minimize the cooling times of a turbine, such as a steam turbine, but also of a gas turbine or its partial turbines. Revision times or downtimes of turbines or turbines can be shortened - and thus costs can be saved.

In particular, can be realized by the invention - when using the suction fan according to the invention for the realization of a pressure sink at the inlet or outlet of the turbine - the forced cooling even in turbines or turbine systems without a condenser or without low pressure turbine parts and without a condenser.

Thus, it is possible by the invention, the forced cooling also in known back-pressure steam turbine plants, which operate without a condenser or which without low pressure turbine parts and without capacitor, whereby these systems can be cooled faster and local inspection times and downtime can be shortened.

Preferred developments of the invention will become apparent from the dependent claims. The developments described relate both to the turbine system and to the method for cooling a turbine system.

According to a preferred development, the suction fan is coupled to the turbine outlet, in particular to an exhaust steam duct at the turbine outlet. Here, the - then - sucked through the turbine inlet into the turbine cooling medium in the operating process gas flow direction through the turbine is sucked. In particular, the coupling of the suction fan to the Abdampfkanal is structurally easy to implement.

According to a further preferred embodiment, it is provided that the suction fan with the turbine inlet, in particular with a live steam / HZÜ / Überströmzuleitung at the turbine inlet, is coupled. For example, the suction fan may be connected to a local Fönstutzen.

In this case - then - sucked into the turbine via the turbine outlet cooling medium against the operating process gas flow direction through the turbine sucked.

A suction flow of the cooling medium through the turbine against the operational process gas flow direction proves to be particularly advantageous because the cooling medium enters the turbine on the "cold side". This results in lower - and less component burdening - cooling gradients in the turbine components, as at entry of the cooling medium on the "hot side" of the turbine.

Furthermore, in the case of multi-part turbines, which then usually have one (or more in each case) high-pressure and medium-pressure and / or low-pressure turbine part, it can also be provided that the suction fan is coupled to the high-pressure turbine part, medium-pressure turbine part and / or low-pressure part turbine of the turbine is. Several suction fans for several such sub-turbines can be provided.

Thus, it can also be provided here that - depending on the realization of the pressure sink (by the suction fan) on a Abdampf- (turbine outlet) or supply or live steam side (turbine inlet) of such a turbine part - the suction fan with a Abdampfkanal or a live steam / HZÜ- / Überströmzuleitung the high-pressure turbine section, the medium-pressure turbine section and / or the low-pressure turbine section is coupled.

According to another preferred embodiment, it is provided that the cooling medium is ambient air. This is readily available and available to a sufficient extent and at applicable temperatures.

The cooling medium, in particular the ambient air, can flow into the turbine or sub-turbine via a connecting piece connected to the turbine, for example a blow-by nozzle on the live-steam side or HZ-side of the turbine or sub-turbine.

In particular, the inflow of the cooling medium into the turbine using a valve is preferably controllable, controllable and / or controllable. Thereby, i. By controlling an amount of cooling medium entering the turbine or sub-turbine, it can be ensured that permissible cooling-down gradients are not exceeded. As a control member, a control valve can be used.

Here, i. For controlling the amount of the cooling medium, the valve, for example, the control valve, can be arranged at any point in the cooling medium section, for example, at the Sauggebläseeintritt.

According to a particularly preferred development, the inflow of the cooling medium into the turbine or sub-turbine via a - on the live steam or HZÜ side of the turbine or turbine part - between valves, for example, between a quick-closing and a control valve, arranged Fönstutzen. About the control valve, the amount of the inflowing cooling medium can be controlled, regulated and / or controlled so as not to exceed allowable Abkühlgradienten at the turbine components.

According to another preferred embodiment, the process gas is water vapor. That is, the turbine is a steam turbine or the plant is a steam turbine plant.

Furthermore, here the turbine or steam turbine may be a multi-part turbine or steam turbine. This can - one or more - have partial turbines, such as high-pressure, medium-pressure and / or low-pressure turbine parts. Particularly preferably, the turbine plant is a steam turbine plant without a condenser, for example a counterpressure steam turbine plant without a low-pressure turbine section and without a condenser. Through the use of the invention - here - by the present invention used suction fan - a - otherwise non-existent - pressure sink is provided, whereby even in such a steam turbine without a condenser, the forced cooling is possible. A shortening of downtime even in such a steam turbine without a condenser is thus only possible by the invention.

The forced cooling according to the invention-by means of the pressure sink realized via the suction fan and the cooling medium flow through the turbine or sub-turbine initiated thereby-can be realized separately for one or in each case several sub-turbines-by a plurality of separate cooling medium flows and correspondingly more suction blowers-or else for several consecutive sub-turbines - with a common cooling medium flow - together by means of a single suction fan.

In a further preferred embodiment, a thermal protection or overheating protection for the suction fan is provided.

A suction fan, as used in the invention, is in its outlet temperature, i. in the temperature of the medium blown out by the suction fan, for example to 150 ° C. This is - respectively - and the inlet temperature of the sucked by the suction fan medium is limited, for example - assuming warming of the suction fan flowing through medium by 30 ° C - to 120 ° C.

In order to realize the thermal protection of the suction fan, it may be provided that a further cooling medium feed, for example a bypass or bypass nozzle, is mounted on or in the region of the inlet of the suction fan, via which further cooling medium, for example also ambient air, is admixable with the cooling medium emerging from the turbine and drawn into the suction fan. Also, a temperature sensor may be arranged at the fan outlet, by means of which the temperature of the emerging from the suction fan medium is measured.

If this bypass is also provided with a control valve, the admixture of the further cooling medium to the emerging from the turbine and sucked into the suction fan cooling medium, in particular taking into account the measured fan outlet temperature, controlled, controllable and / or controllably mixed - and so on Overheating of the suction fan can be prevented.

Also, the control, control and / or regulation of the admixture and / or the amount of the further cooling medium by means of a three-way mixer at the merger of the further cooling medium and the emerging from the turbine and sucked into the suction fan cooling medium.

Also, the admixture of the further cooling medium can be controlled, regulated and / or controlled by a turbine temperature and / or by the temperature of the cooling medium sucked in by the suction fan and / or by the temperature of the admixed further cooling medium.

At the beginning of Forced Cooling, only a small amount of cooling medium guided through the turbine is required to maintain the max. permissible cooling rate or to achieve the allowable cooling gradient of the turbine components. This small amount of cooling medium is also strongly heated by the still highly heated turbine at this time - by heat exchange with the very hot turbine components.

In order to cool then at this time very hot, flowing out of the turbine cooling medium and a permissible for the suction fan inlet temperature or outlet temperature To bring, the further cooling medium, for example, again ambient air, is added via the bypass.

As the turbine temperature decreases, the amount of cooling medium is increased by the turbine, at the same time reducing the admixture of additional cooling medium.

Thus, overheating of the suction fan - while "exhaustion of the maximum cooling rates of the turbine components" - can be effectively prevented.

The medium exiting the aspirator, i. The Sauggebläseabluft, - can be derived - on minimized flow path to avoid pressure losses - in an environment. As a result, a heating of a turbine hall receiving machine hall can be avoided.

Furthermore, it can also be provided to carry out a steam precooling of the process gas, for example a steam injection cooling in the process gas, before the forced cooling according to the invention.

The previously given description of advantageous embodiments of the invention contains numerous features, which are given in the individual subclaims partially summarized in several. However, those skilled in the art will conveniently consider these features individually and summarize them to meaningful further combinations.

In the figures, embodiments of the invention are shown, which are explained in more detail below. The same reference numerals in the figures designate technically identical elements.

FIG 1

einen Ausschnitt aus einem Wasser-Dampf-Kreislauf bei einem Dampfkraftwerk mit einer Dampfturbinenanlage für ein Forced Cooling gemäß einem Ausführungsbeispiel der Erfindung,

FIG 2

einen Ausschnitt aus einem Wasser-Dampf-Kreislauf bei einem Dampfkraftwerk mit einer Dampfturbinenanlage für ein Forced Cooling gemäß einem weiteren Ausführungsbeispiel der Erfindung,

FIG 3

eine Konzept-Darstellung eines thermischen Schutzes eines Sauggebläses einer Dampfturbinenanlage für ein Forced Cooling gemäß einem Ausführungsbeispiel der Erfindung,

FIG 4

eine Darstellung von Massenströmen eines Kühlmediums durch die Turbine und eines weiteren Kühlmediums durch einen Bypass bei einem Forced Cooling bei einer Dampfturbinenanlage gemäß einem Ausführungsbeispiel der Erfindung,

FIG 5

eine Darstellung eines Forced Cooling bzw. einer Kühlung einer Turbine bei einer Dampfturbinenanlage gemäß einem Ausführungsbeispiel der Erfindung.

Show it:

FIG. 1

a section of a water-steam cycle at a steam power plant with a steam turbine plant for a forced cooling according to an embodiment of the invention,

FIG. 2

a detail of a water-steam cycle in a steam power plant with a steam turbine plant for a forced cooling according to another embodiment of the invention,

FIG. 3

a concept representation of a thermal protection of a suction fan of a steam turbine plant for a forced cooling according to an embodiment of the invention,

FIG. 4

a representation of mass flows of a cooling medium through the turbine and a further cooling medium through a bypass in a forced cooling in a steam turbine plant according to an embodiment of the invention,

FIG. 5

a representation of a forced cooling or cooling of a turbine in a steam turbine plant according to an embodiment of the invention.

Exemplary embodiments: Forced cooling in steam turbine plants without condensers or in steam power plants with steam turbine plants without condensers (FIGS. 1 to 5)

FIG. 1 shows a section of a water-steam cycle 2 in a steam power plant 1 with a steam turbine plant 3 without a condenser.

Via a supply line 30 - in operation of the steam power plant 1 - hot, heated by a steam generator and a superheater further heated steam / high-pressure steam 15, hereinafter referred to only as process gas 15 flows through a turbine inlet 4 on a live steam side 13 of the steam turbine 29 in this , flows through the steam turbine 29 in the process gas flow direction 27 and performs there or while doing relaxation and cooling mechanical work.

By a coupled to the steam turbine 29 generator (not shown), the mechanical power is then converted into electrical power, which is fed in the form of electrical current in a power grid.

The relaxed process gas 15 exits on the exhaust steam side 31 of the steam turbine 29 via a turbine outlet 5 there - in the form of a Ausverdampfstutzens 9 - from the steam turbine 29 and flows through an exhaust steam line 9 back to the steam generator, whereby the water-steam cycle 2 is closed ,

The control of the inflow or outflow of the process gas 15 into and away from the steam turbine 29 is effected by means of valves 12, 11 arranged in the supply line, i. a quick-closing valve 12 and a control valve 11, and a flap 33 arranged in the exhaust steam line 9.

Work, such as maintenance or inspection work on the steam turbine 29 can be performed only after switching off a rotary operation of the steam turbine 29. For this purpose, a shaft train (not shown) of the steam turbine 3 must be cooled down from operating temperatures of approximately 600 ° C. to below 100 ° C.

This cooling down would - without external intervention - take several days, i. about 8 days, and extend the entire downtime of the steam power plant 1 by this period.

In order to reduce these downtimes or to shorten the cooling down phase, a forced cooling is used in the steam turbine system 3 or in the steam turbine 29.

In this Forced Cooling ( FIG. 5 , 100) is in the steam turbine 29 - instead of the process gas 15 - ambient air 7 as Cooling medium 7 from the environment 14 sucked into the steam turbine ( FIG. 5 , 110) and the ambient air 7 in the operational process gas flow direction 27 (in this case also the cooling medium flow direction 28) are sucked through the steam turbine 29 (FIG. FIG. 5 , 120) so as to cool ( FIG. 5 , 130) as far as possible to ensure all hot steam turbine components.

To generate a necessary, the suction flow of the cooling medium 7 in the steam turbine 29 and in operational process gas flow direction 27 (in this case, cooling medium flow direction 28) by the steam turbine 29 initiating negative pressure (pressure drop) is how FIG. 1 shows, a suction fan 6 at the steam turbine exhaust side 31 on a suction line (when forced cooling open) between the turbine outlet 5 and a flap 33 (closed when forced cooling) connected.

The entry of the cooling medium 7 or the ambient air 7 into the steam turbine 29 takes place via a Fönstutzen 10 between the quick-closing valve 12 (closed forced cooling) and the control valve 11 (partially opened during forced cooling) on the live steam side 13 of the steam turbine. 3

Due to the cooling effect of the ambient air 7 - when the steam turbine 29 flows through in the cooling medium flow direction 28 (in this case also operational process gas flow direction 27) - the steam turbine 29 or its components is cooled, thereby achieving a faster cooling of the steam turbine components.

The ambient air 7 taken in by the suction fan 6 - in the operational process gas flow direction 27 or cooling medium flow direction 28 through the steam turbine 29 - is discharged back into the environment 14 as a suction fan discharge air 20.

Since permitted cooling gradients may not be exceeded in the steam turbine components, which would otherwise lead to component damage could lead, the amount of sucked ambient air 7 is regulated. As a control element serves the control valve 11 at the turbine inlet 4 (on the live steam side 13).

FIG. 2 also shows a section of a water-steam cycle 2 in a steam power plant 1 with a steam turbine plant 3 without a condenser.

Here, too, flows via a supply line 30 - during operation of the steam power plant 1 - hot, heated by a steam generator and a superheater further heated steam / high-pressure steam 15 or process gas 15 via a turbine inlet 4 on a live steam side 13 of the steam turbine 29 in this, flows through the Steam turbine 29 in the process gas flow direction 27 and performs there or thereby under relaxation and cooling mechanical work.

The relaxed process gas 15 exits on the exhaust steam side 31 of the steam turbine 29 via a turbine outlet 5 there - in the form of a Ausverdampfstutzens 9 - from the steam turbine 29 and flows through an exhaust steam line 9 back to the steam generator, whereby the water-steam cycle 2 is closed ,

The control or control of the inflow or outflow of the process gas 15 in and / or away from the steam turbine 29 also takes place here by means of valves 12, 11 arranged in the supply line, i. a quick-closing valve 12 and a control valve 11, and a flap 33 arranged in the exhaust steam line 9.

In order to reduce the downtime or to shorten the Abkkühlphase here, a forced cooling is used in the steam turbine plant 3 and the steam turbine 29.

In this Forced Cooling ( FIG. 5 , 100) is in the steam turbine 29 - instead of the process gas 15 - ambient air 7 as Cooling medium 7 from the environment 14 sucked into the steam turbine ( FIG. 5 , 110) and the ambient air 7 are sucked against the operational process gas flow direction 27 in the cooling medium flow direction 28 through the steam turbine 29 (FIG. FIG. 5 , 120), so - also - a cooling ( FIG. 5 , 130) as far as possible to ensure all hot steam turbine components.

To generate a necessary, the suction flow of the cooling medium 7 into the steam turbine 29 and against the operational process gas flow direction 27 and the cooling medium flow direction 28 by the steam turbine 29 initiating negative pressure (pressure sink) is how FIG. 2 shows a suction fan 6 - in this case - connected to the steam turbine live steam side 13 to a Fönstutzen 10 between the quick-closing valve 12 (closed when forced cooling) and the control valve 11 (when forced cooling open).

The entry of the cooling medium 7 or the ambient air 7 - from the environment 14 - into the steam turbine 29 takes place via a control valve 35 (partially opened during forced cooling) suction line 34 (when forced cooling open) between the turbine outlet 5 and a quick-closing valve 33rd (closed for forced cooling).

By the cooling effect of the ambient air 7 - when the steam turbine 29 flows through in the cooling medium flow direction 28 or against the operating process gas flow direction 27), the steam turbine 29 or its components is cooled, thereby achieving faster cooling of the steam turbine components.

The ambient air 7 sucked in by the suction fan 6 - contrary to the operational process gas flow direction 27 or in the cooling medium flow direction 28 through the steam turbine 29 - is released again into the environment 14 as a suction fan discharge air 20.

Since permissible cooling gradients in the steam turbine components may not be exceeded here either, which could otherwise lead to component damage, the amount of sucked ambient air 7 is regulated. As a control element serves the control valve 35 in the suction line 34 at the turbine outlet 5 (on the exhaust steam side 31).

As an alternative to this, the control can take place via the control valve 11 on the steam-steam live steam side 13-in the absence of the control valve 35 in the suction line 34.

Next to this, ie for controlling the sucked ambient air 7 in the forced cooling after FIG. 2 , as in the case of forced cooling FIG. 1 , the regulation of the ambient air 7 by means of a separate, in the suction line 34 (at FIG. 1 ) or in the line 30 ( FIG. 2 ) take place at Sauggebläseeintritt 16 arranged control valve. Here is then in the control of the ambient air 7 by means of the separate control valve, the control valve 11 (at FIG. 1 ) or the control valve 35 (at FIG. 2 ) always open.

FIG. 3 shows a concept representation of a thermal protection of the suction fan 6 of the steam turbine plant 3 after the FIG. 1 or FIG. 2 ,

The suction fan 6 is limited in the temperature of its Sauggebläseabluft 20, for example, to 150 ° C. This is - respectively - the (Sauggebläse-) inlet temperature of the aspirated by the suction fan 6 medium 36 is limited, for example - assuming warming of the suction fan flowing through medium by 30 ° C - to 120 ° C.

In order not to exceed this maximum permissible Sauggebläseablufttemperatur or Sauggebläseeintrittstemperatur - the supply line 30 of the suction fan 6 - in the region of the Sauggebläseseintritts 16 - with the thermal protection - with a bypass 17, ie a further cooling medium supply 17, provided.

About this bypass 17 is - by means of the suction fan 6 and (quantity) adjustable via a arranged in the bypass 17 control valve 18 - via a supply line 30 from the environment 14 more ambient air 8 - as a further cooling medium 8 - sucked and - via the turbine outlet. 4 (see. FIG. 1 ) or the turbine inlet 5 (see. FIG. 2 ) - from the steam turbine 29 in the cooling medium flow direction 28 exiting ambient air 7 - to the cooling - added 140.

Alternatively, the control of the amount of the further cooling medium 8 and the mixture or the admixture 140 of the further cooling medium 8 and / or to the ambient air 7 by means of a three-way mixer at the junction of the further cooling medium 8 and the ambient air 7 done.

This ambient air mixture 36 is sucked into the suction fan 6 via the suction fan inlet 16 - and leaves the suction fan 6 - as Sauggebläseabluft 20 - via a discharge line 30 on the exhaust side 37 in the environment 14th

By means of a temperature sensor 19, which is arranged in the region of the discharge line 30 of the Sauggebläseabluft 20, the temperature of the Sauggebläseabluft 20 is measured.

A control unit 22 regulates the control valve 17 as a function of the measured suction fan outlet temperature and a suction fan motor 21 which drives the suction fan 6.

FIG. 4 shows in a coordinate representation (abscissa 23 [time t], ordinate 24 [mass flows ms]) the course of the mass flows ms 25, 26 of the ambient air 7 through the steam turbine 29 and the admixed ambient air 8 through the bypass 17 in the forced cooling to Thermal protection of the suction fan 6.

At the beginning of forced cooling, there is only a small, minimum amount of (cool) ambient air passed through the steam turbine 29 7 required or permissible to avoid the max. permissible cooling rate or to achieve the allowable cooling gradient of the turbine components.

This small amount of ambient air 7 is also heated by the still highly heated steam turbine 29 at this time - by heat exchange with the very hot turbine components.

In order to cool the then at this time very hot, flowing out of the steam turbine 29 ambient air 7 to the suction fan 6 permissible Sauggebläseablufttemperatur, via the bypass 17 and regulated by the control valve 18, the further ambient air 8 mixed in maximum amount.

With - over the time t - decreasing steam turbine temperature, the amount of ambient air 7 is continuously increased by the steam turbine 29 (see. FIG. 4 , Curve 26), at the same time the amount of further ambient air 8 is continuously reduced (see. FIG. 4 Curve 25) until, at the end of the forced cooling, the admixed amount of further ambient air 8 is reduced to its minimum amount or the amount of ambient air 7 is increased by the steam turbine 29 to its maximum amount.

The mixture 36 - from ambient air 7 through the steam turbine 29 and from ambient air 8 through the bypass 17 - has at any time during the forced cooling when entering the suction fan 6 a permissible Sauggebläseeintrittstemperatur or respectively permissible Sauggebläseablufttemperatur.

Thus, overheating of the suction fan 6 - while "exhaustion of the maximum cooling rates of the turbine components" - effectively prevented.

Although the invention has been illustrated and described in detail by the preferred embodiment, the invention is not limited by the disclosed example and other variations can be derived therefrom by those skilled in the art without departing from the scope of the invention.

Claims (15)

Turbine plant (3) having a turbine (29) which can be flowed through by a process gas (15) in operation in a flow direction (27) from a turbine inlet (4) to a turbine outlet (5)
characterized in that
a suction fan (6) is coupled to the turbine outlet (5) using a cooling medium (7) drawn into the turbine (29) through the suction fan (6) via the turbine inlet (4) in the process gas flow direction (27) through the turbine (29) is sucked, or that with the turbine inlet (4) a suction fan (6) is coupled, using a via the turbine outlet (5) into the turbine (29) sucked in cooling medium (7) against the process gas flow direction (27) the turbine (29) is sucked. Turbine plant (3) according to at least one of the preceding claims, characterized in that
the suction fan (6) is coupled to the turbine outlet (5), in particular to an exhaust steam duct (9) at the turbine outlet (5), wherein the cooling medium (7) sucked into the turbine (29) via the turbine inlet (4) operational process gas flow direction (27) through the turbine (29) is sucked. Turbine plant (3) according to at least one of the preceding claims, characterized in that
the suction fan (6) is coupled to the turbine inlet (4), in particular to a live steam / HZÜ / overflow supply line (13) at the turbine inlet (4), which is sucked into the turbine (29) via the turbine outlet (5) Cooling medium (7) against the operational process gas flow direction (27) through the turbine (29) is sucked. Turbine plant (3) according to at least one of the preceding claims, characterized in that
the suction fan (6) with a high-pressure turbine section, medium-pressure turbine section and / or low-pressure section turbine (29) of the turbine (29), in particular with a Abdampfkanal (9) or a live steam / HZÜ / Überströmzuleitung (13) of the high-pressure turbine section, the medium-pressure turbine section and / or the low pressure turbine part (29) is coupled. Turbine plant (3) according to at least one of the preceding claims, characterized in that
the cooling medium (7) is ambient air, in particular whose inflow into the turbine (29) can be controlled, regulated and / or controlled by using a valve (12, 11). Turbine plant (3) according to at least one of the preceding claims, characterized in that the process gas (15) is a water vapor. Turbine plant (3) according to at least one of the preceding claims, characterized in that the turbine (29), in particular between valves (12, 11) arranged, Fönstutzen (10), in particular arranged on the turbine inlet (4), via which the cooling medium (7), in particular controlled, regulated and / or controlled by means of at least one of the valves (12, 11), using the suction fan (6) in the turbine (29) is sucked. Turbine plant (3) according to at least one of the preceding claims, characterized by a further, at an inlet (16) of the suction fan (6) arranged cooling medium supply (17), in particular a bypass (17), via which a further cooling medium (8) from the the turbine (29) emerging and in the suction fan (6) sucked in cooling medium (7) is admixed. Turbine plant (3) according to at least one of the preceding claims, characterized in that
the turbine (29) a steam turbine, in particular a multi-part steam turbine without a low-pressure turbine part, or a partial turbine of a steam turbine, in particular a multi-part steam turbine without a low-pressure turbine part is. Method (100) for cooling a turbine installation (3) with a turbine (29), which is flowed through by a process gas (15) in operation in a flow direction (27) from a turbine inlet (4) to a turbine outlet (5) a cooling medium (7) is sucked into the turbine (29) using a suction fan (6) coupled to the turbine inlet (4) or to the turbine outlet (5) and into or against the operational process gas flow direction (27) through the turbine (29) is sucked (120), whereby the turbine (29) is cooled by the cooling medium (7) (130). Method (100) for cooling a turbine installation (3) according to at least one of the preceding method claims, in which the cooling medium (7) is arranged in a supply line (13) via a blower neck (10), in particular between valves (12, 11) Turbine (29), in particular in a feed line (13) on a live steam side (FD side) of a turbine high-pressure turbine part or in a hot reheat side (HZÜ) side of a medium-pressure turbine part of the turbine, is sucked into the turbine (110). Method (100) for cooling a turbine installation (3) according to at least the preceding method claim, in which by using at least one of the valves (12, 11), in particular a quick-closing (11) and / or control valve (12), sucking ( 110) of the cooling medium (7) in the turbine (29) controlled, controlled and / or regulated. Method (100) for cooling a turbine plant (3) according to at least one of the preceding method claims, in which the cooling medium (7) sucked into the suction fan (6) before entry into the suction fan (6), a further cooling medium (8), in particular ambient air , is added (140). Method (100) for cooling a turbine installation (3) according to at least the preceding method claim, in which the admixture (140) of the further cooling medium (8) is controlled, regulated and / or controlled, in particular using a control valve (18) in particular that the admixture (140) depends on a turbine temperature and / or on the temperature of the cooling medium (7) sucked in by the suction fan (6) and / or on the temperature of the admixed further cooling medium (8) and / or the temperature of the Suction fan (8) blown cooling medium mixture (20) takes place. Method (100) for cooling a turbine installation (3) according to at least one of the preceding claims, used in a turbine installation (3) without a condenser, in particular in a back-pressure turbine installation (3).

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