EP2126291A2 - Method for operating a gas and steam turbine plant and a gas and steam turbine plant for this purpose - Google Patents

Abstract

The invention relates to a method for operating a gas and steam turbine plant (1), according to which the flue gas (R) that escapes from a gas turbine (2) is conducted through a waste gas steam generator (20) and according to which a flow medium that is used to drive a steam turbine (12) is conducted in a flow medium circuit (16) that comprises a number of pressure stages (40, 92, 100). At least one of the pressure stages (100) has an evaporator circuit (94) with a steam collection drum (48) that has a number of downpipes (102) connected to the steam collection drum (48) and a number of rising pipes (104) downstream of the downpipes (102) that are likewise connected to the steam collection drum (48) and are heated by the flue gas (R) in the waste heat steam generator (20). The aim of the invention is to adapt the operation in a particularly flexible manner to different requirements whilst guaranteeing a high degree of reliability and operational safety and to permit a particularly cost-effective design of the components of the relevant evaporator circuit (94). To achieve this, the height of the fluid column formed by the flow medium in the downpipes (102) that are connected to the steam collection drum (48) is monitored and a transient dry operation of the evaporator circuit (94) can thus be detected and safeguarded against.

Description

description

Method for operating a gas and steam turbine plant and designed for this purpose gas and steam turbine plant

The invention relates to a method for operating a gas and steam turbine plant, in which the flue gas emerging from a gas turbine is passed through a heat recovery steam generator and in which a fluid used for driving a steam turbine is guided in a fluid circuit comprising a number of pressure stages at least one of the pressure stages has an evaporator circulation with a steam drum, with a number of downpipes connected to the steam drum and with a number of downcomers connected downstream, also connected to the steam drum and heated by the flue gas in the heat recovery steam generator risers. The invention further relates to a gas and steam turbine plant designed for such an operating method.

In a gas and steam turbine plant contained in the relaxed working fluid or flue gas from the gas turbine heat for the evaporation of a fluid, usually water used. The (water) steam thus generated is then used to drive a steam turbine. The heat transfer takes place in a waste gas steam boiler or waste heat steam generator downstream of the gas turbine on the flue gas side, in which heating surfaces in the form of tubes or tube bundles are arranged, in which the fluid to be vaporized is led. These heating surfaces are usually part of a steam turbine and a downstream her strömungsmittelsei- downstream capacitor fluid circuit, z. B. a water-steam cycle, wherein the emerging from the steam turbine expanded fluid after its condensation in the condenser is again fed to the heating surfaces of the heat recovery steam generator. In addition to the evaporator heating surfaces in the heat recovery steam generator also other heating surfaces, in particular for preheating the Condensate or feed water or overheating of the generated steam, be provided. Furthermore, in the heat recovery steam generator also an additional firing, z. For example, a furnace may be integrated to either raise the temperature of the flue gas above the level present at its exit from the gas turbine, or to maintain steam production in the heat recovery steam boiler when the gas turbine is decoupled or shut down (so-called oil operation) ).

Usually, the fluid circuit comprises several, for example three, pressure stages, each with its own evaporator section. A design and design concept for such an evaporator section which has proved its worth because of its comparatively simple structure and its relatively simple operability is based on the natural circulation principle, at least in the area of subcritical vapor pressures. In this case, a steam drum arranged above the flue gas flow channel of the heat recovery steam generator, which is sometimes also referred to as "top drum", serves as a reservoir for the condensate or feed water, which may be supplied by the condensate or feed water pump and possibly preheated by a condensate preheater or an economizer During operation, driven by its own weight or by the hydrostatic pressure of the water column, a portion of the water supply continuously sinks down through unheated downcomers connected to the bottom or bottom of the steam drum via an intermediate manifold, sometimes referred to as a "bottom drum is called, the sunken water is distributed to a number of parallel and connected to heating surfaces, distributed by the heat contained in the flue gas and / or heated by the radiant heat generated by an additional burner of the heat recovery steam riser, in de NEN the desired evaporation takes place. The heating surfaces formed from the riser tubes can be part of the enclosure wall of the heat recovery steam boiler or in the manner of Schottheizflächen within the of the Surrounding wall enclosed flue gas flow channel may be arranged.

Due to its reduced density relative to the liquid state of aggregation, the water-vapor mixture produced in the riser pipes by (partial) evaporation of the water rises and finally re-enters the steam drum above the liquid level, whereby the evaporator circulation is closed. In the steam drum, the water-steam separation, which is also referred to as phase separation, takes place; the water vapor present above the water level under saturated steam conditions is withdrawn via a steam extraction line connected to the top of the steam drum and, if necessary, overheating of its further use, eg. B. for driving a steam turbine supplied.

Evaporator stages based on the forced circulation principle have a similar structure, but still have a circulating pump connected to the evaporator loop, which supports or forces the circulation of the water or of the water / steam mixture.

Due to the limited thermal load capacity of the commonly used pipe wall materials for the heating pipes and risers is to ensure in accordance with the prior state of science and technology necessarily that when operating a gas and steam turbine plant of the type mentioned above, the risers of each evaporator stage in all operating conditions sufficiently fluid , usually water or water-steam mixture, are supplied. The aim is to ensure a certain minimum cooling of the pipe walls as a result of the heat transfer from the pipe inner wall surface to the partially evaporating fluid and thus to avoid any damage to the evaporator circulation and associated operational hazards. In other words: so-called dry operation of the evaporator or operation with lowered water level, in which the liquid column in the steam drum and in the steam drum attached to it closed downpipes sinks to a level below the connection of the downpipes or even the downpipes and their downstream riser pipes are completely "dry" so that virtually no fluid flows through it is to be avoided under all circumstances.

Such considerations are also based on the previously applied, internationally valid regulations DIN EN 12952, according to Part 1 for "water tube boiler with a volume of more than 2 liters for the production of steam and / or hot water with an allowable pressure of more than 0.5 bar and a temperature of more than 110 ⁰ C ", which, in accordance with Part 7, sets the minimum permissible water level in the steam drum to" 150 mm above the highest heated point of the drum and the highest connection of the downpipes to the boiler drum ". The internationally accepted successor standards DIN IEC 61508 and DIN IEC 61511, which were introduced in Germany in 2002, no longer expressly contain such detailed requirements, but the security requirements specified therein have generally not fallen by any means despite more flexible frameworks.

In order to comply with the said minimum fill levels of liquid fluid in the steam drum also z. B. in fast load changes of the heat recovery steam generator or about to be able to guarantee in case of unforeseen interruption or lockout of feed water supply and in particular in the latter case, the residual heat in the system in a safe and material-saving manner can perform the volume of the steam drum and the In normal operation, the amount of fluid (feed water) stored in it is usually comparatively large, taking into account a "safety surcharge." However, this is associated with a correspondingly high production outlay and thus also high production costs.

In accordance with the particular relevance attached to maintaining the minimum water level in the steam drum, In the case of existing systems, a triple redundant measurement or monitoring of the current fill level height related to the drum base or to the upper edge of the downpipes continues, which requires a relatively complex design of the associated safety-related devices. Once a two-by-three selection from the three level measurements, a drop in water level below a predetermined threshold, e.g. B. 150 mm according to DIN EN 12952, signaled by the safety system, a further supply of hot gas turbine exhaust gases is prevented in the heat recovery steam generator, z. B. by rapid shutdown of the gas turbine, or by the exhaust gases in a bypass chimney, ie bypassing the heat recovery steam generator, are bypassed by pressing a corresponding flap. However, in the interest of the highest possible availability of such an emergency shutdown is extremely undesirable.

In addition, the current compliance with the medium pressure drum (MD drum) and low pressure drum (LP drum) levels above the minimum oil level requires complex inlet temperature control for the economizers of the high and medium pressure systems and the condensate preheater. Changes in stationary conditions due to different operating conditions in oil operation result in internal heat shifts in the heat recovery steam generator, which influence the heat absorption of the medium-pressure and low-pressure evaporator. This can, for example, cause fluctuations in the drum water levels of the MD and ND drum and an unintentionally high pressure increase in the LP drum. In order to be able to keep these fluctuations within the required operating limits, the quantities of water must additionally be superimposed accordingly via the HP and MD economizer bypass valves, which requires increased control effort.

Finally, the currently required compliance with the minimum water level in the LP steam drum, especially in the case of the Writing DE 100 04 178 C1 detailed manner of driving "Sleeping Mode", in which, for example, during a quick shutdown of the steam turbine of the HD steam generated in the HD stage is bypassed via a bypass line directly into the condenser (diverter), while a targeted pressure shift and a shift in heat dissipation and Aufaufmeähme in heat recovery steam generator, the production of MD and LP steam to be brought to a standstill, at additional cost due to a comparatively large dimensioned LP steam drum The drop in water level in the LP drum at one

The fact that the steam turbine shuts down is especially drastic here due to the deliberately induced increase in pressure in the LP system. Contrary to the original orientation of the concept can therefore not be completely dispensed with in practice on a Niederdruckumleitsta- tion, which reduces the drop in water level at a quick closing of the steam turbine accordingly.

The invention is therefore based on the object of specifying a method for operating a gas and steam turbine plant of the type mentioned, which is particularly flexible adaptable to various operating conditions of the system with high reliability and high operational safety, and a particularly cost-effective design of the components respective evaporator circulation possible. Furthermore, a suitable for carrying out the process gas and steam turbine plant should be specified.

With regard to the method, the object is achieved by monitoring the height of the liquid column formed by the flow medium in the downpipes connected to the steam drum.

The invention is based on the consideration that due to the advances recently achieved in material technology and material development for evaporator heating tubes contrary to the hitherto represented in the professional world interpretation of a gas and steam turbine plant both in technical is also feasible in practice under the given economic boundary conditions, in which, at least temporarily, during special operating conditions, a partial or complete drying operation of an evaporator circuit, ie a drop in the liquid level in the downpipes below the level of the steam drum, is tolerable.

In order to avoid permanent material damage and associated operational hazards, on the one hand the arranged in the flow channel of the heat recovery steam riser or the heating surfaces formed from them should be designed in terms of their temperature resistance to the usually occurring during system operation flue gas temperatures in the region of their installation position For example, 300 ⁰ C in a MD evaporator or 200 ⁰ C in a LP evaporator. The hitherto always existing cooling by the fluid normally carried in the pipes should therefore no longer be included in the temperature design for a possible dry operation. Such requirements are readily met by a variety of the skilled man known steels, the temperature limit is partly over 400 ⁰ C and their use can be justified in economic terms.

On the other hand, the hitherto customary monitoring and safeguarding concept for such a combined cycle power plant and in particular for those evaporator circuits in which a temporary dry running is considered, consistently to the previous design principles changed thermal loads and threats to the structural integrity the evaporator components are adapted. As a central input for the associated monitoring system and for deciding on the type and extent of security measures to be initiated, a measured variable should first be recorded which reliably provides information about an incipient dry operation as well as about its "extent". For this reason, in accordance with the concept presented here, the measurement of the fill level of the liquid column formed by the liquid flow medium within the downpipes of the evaporator circuit is provided above and beyond the hitherto customary level measurement in the steam drum. In other words, the measuring device not only provides information as to whether the liquid level drops below a minimum level in the steam drum or below the level of the downpipe connections, but quantifies this state even more closely by detecting at least one further height level or a plurality of discrete height measuring points. te monitored within the downpipe and dissolving metrologically. Of course, a continuous or quasi-continuous measurement of the level height can be provided in the downpipe, expediently with the arranged at the lower end of the manifold manifold as a reference point.

If several downcomers are connected to the steam drum and connected in the manner of a flow-side parallel connection with a common manifold, adjusts itself in accordance with the principle of communicating tubes usually in all downpipes the same level height, so that advantageously only the level in one of the tubes must be monitored ,

In an advantageous embodiment, the temperature of the flue gas is also monitored in the riser, wherein in an operating condition with a lying below the connection to the steam drum liquid level in the downcomers a safety measure is initiated as soon as the temperature of the flue gas in the downstream of the downcomers risers exceeds a predetermined limit.

In this way, therefore, especially in an operating state associated with a particularly high risk situation, with a potentially imminent or already occurring dry operation or with a reduced flow rate. mean throughput monitors the heating temperature acting from outside on the riser pipes and triggers a safety reaction when exceeding a critically regarded value. In this case, in particular, a cascade of staggered limit values can also be defined, whereby, when a first limit value is exceeded, a relatively "mild" countermeasure is initially introduced, but increasingly more drastic countermeasures upon further increase in temperature.

Advantageously, the respective temperature limit value is predefined as a function of the liquid level in the downpipes determined by measurement, so that the cooling influence of the remaining quantity of the flow medium passing through the downstream riser pipes is adequately determined when deciding the type and time of initiation Safety measures can be taken into account.

A first, relatively mild safety measure preferably consists in opening a bypass line of a condensate preheater or upstream feed water preheater upstream of the evaporator circuit, in order to generally exceed the flow rate during various load change states, in particular when the gas and steam turbine system is started up or shut down permissible flue gas temperatures in front of the relevant evaporators. If the regular operation is then resumed and steam is again generated in the relevant evaporator stage, then the respective evaporator system is filled with hot water from the upstream economizer (at

MD evaporator) or from the condensate preheater (for LP evaporator). By deliberately closing the cold condensate preheater bypass or the economizer bypass, the respective heating temperature is increased and steam production is initiated again.

Especially with a three-pressure system with a condensate preheater, a condensate preheater downstream MD Eco- nomizer for the feed water of the MD evaporator and an MD economizer downstream HD economizer for the feed water of the HD stage leads to the opening of the condensate preheater bypass line or the bypass line of the MD economizer in the standard case that, as in DE 100 04 187 Cl described, the HD evaporator flue gas side of the MD evaporator and this in turn upstream of the LP evaporator, to the advantageous side effect that now the evaporator circulation of the HD stage is supplied with comparatively cooler feed water, so that the flue gas of the Gas turbine is already withdrawn in the inlet region of the heat recovery steam generator comparatively much heat. The temperature load in the area of the MD and ND heating surfaces, which is already moderate in comparison with the high-pressure stage, is thereby reduced particularly quickly and effectively when required. Especially with such an effective, if necessary activatable safety measure, a temporary drying of the MD and / or LP evaporator circulation can therefore be tolerated particularly well.

Advantageously, both the height of the liquid column in the downpipes of the MD and / or the LP evaporator and the respective flue gas temperature are monitored, with a possible overload state of one of the two pressure levels on the basis of the two associated parameters fill level and flue gas temperature on Installation location of the heating surfaces is derived. When establishing temperature limits for the initiation of safety measures, both the spatially varying heating profile and possibly a different material selection and temperature design for the various evaporator circuits are expediently taken into account.

Another, more drastic security measure may be to initiate a power reduction or an emergency shutdown of the gas turbine or, for. B. by pressing a bypass valve, passing the flue gas leaving the gas turbine at least partially on the heat recovery steam generator. With regard to the device, the object mentioned above is achieved by a gas and steam turbine plant, in which a level measuring device for measuring the height of the fluid column formed by the flow medium in the connected to the steam drum downcomers signal output side with a monitoring and control device for the gas and Steam turbine plant is connected.

Advantageously, the monitoring and control device is further connected on the signal input side with a temperature measuring device monitoring the temperature of the flue gas in the region of the riser tubes and configured to introduce a safety measure in an operating state with a liquid level in the downpipes below the connection to the steam drum, as soon as the temperature measured by the temperature measuring device exceeds a predetermined limit.

The advantages achieved with the invention consist in particular in the fact that the consistent design of the system architecture and the associated safeguarding and monitoring systems make it possible, in the case of a gas and steam turbine plant with a heat recovery steam generator, to use an evaporator system based on the natural circulation principle, in particular dere the MD and / or the LP evaporator system, safe to operate at a water level far below the currently set minimum water level or the heating surfaces even dry, without having to stop the operation of the heat recovery steam generator or the gas turbine. In particular, it is possible to set flexible minimum water levels in the respective evaporator circulation as a function of certain operating modes without loss of security.

It can be demonstrated that such a concept also meets or exceeds the safety standards set by the new standards DIN IEC 61508 and DIN IEC 61511. The risk of rapid shutdown of the heat recovery steam generator when the steam turbine control valves or during rapid load changes namely drops significantly when the water level in the evaporator circuit can safely fall below the drum level. This further increases the availability of the gas and steam turbine plant, especially in the case of fast launches, which are becoming increasingly important in order to compensate for short-term fluctuations in demand and supply in the power grid. Especially in gas and steam turbine plants without bypass-chimney flap, a lower risk of rapid shut-down of the heat recovery steam generator results in lower loads and thus less equivalent operating hours for the gas turbine. This allows the maintenance intervals at the gas turbine can be extended while maintaining the same level of safety.

In addition, the inventive concept enables a more cost-effective design and construction of components of the evaporator system that are usually particularly expensive in terms of production costs, since in particular the MD and LP steam drums can be made more compact than hitherto necessary. This is of particular relevance in the context of the mode of operation "Sleeping Mode" explained above with the elimination of the low-pressure diverter station for the LP evaporator, since the drum magnification otherwise required for carrying out this mode of operation can now be correspondingly smaller or even completely eliminated the control engineering effort to maintain the Kondensatvorwärmer- and economizer inlet temperatures in oil operation less than before.

With a corresponding modification and adaptation, the concept presented here can also be used in gas and steam turbine plants with evaporator stages based on the forced circulation principle.

An embodiment of the invention will be described with reference to a

Drawing explained in more detail. In each case they show schematically: 1 shows a gas and steam turbine plant, and FIG 2 a detail of FIG 1, wherein in the interest of better visibility of essential components of the gas and steam turbine plant some details have been omitted from Figure 1 or shown in graphically slightly modified form.

Identical parts are provided in both figures with the same reference numerals.

The gas and steam turbine plant 1 according to FIG. 1 comprises a gas turbine plant Ia and a steam turbine plant Ib.

The gas turbine plant Ia comprises a gas turbine 2 with coupled air compressor 4 and a combustion chamber 6 upstream of the gas turbine 2, in which fuel B is burned while supplying compressed air from the air compressor 4 to the working medium or fuel gas A for the gas turbine 2. The gas turbine 2 and the air compressor 4 and a generator 8 sit on a common turbine shaft 10.

The steam turbine plant Ib comprises a steam turbine 12 with a coupled generator 14 and in a formed as a water-steam circuit fluid circuit 16 a steam turbine 12 downstream of the condenser 18 and a

Heat recovery steam generator 20. The steam turbine 12 has a first pressure stage or a high-pressure part 12a and a second pressure stage or a medium-pressure part 12b and a third pressure stage or a low-pressure part 12c, which drive the generator 14 via a common turbine shaft 22.

For supplying relaxed in the gas turbine 2 working fluid or flue gas R in the heat recovery steam generator 20, an exhaust pipe 24 to the heat recovery steam generator 20 is connected on the input side. The expanded flue gas R from the gas turbine 2 leaves the heat recovery steam generator 20 on the output side in the direction of a fireplace, not shown. The heat recovery steam generator 20 comprises, as heating surfaces, a condensate preheater 26, which is fed on the input side with condensate K from the condenser 18 via a condensate line 28, into which a condensate pump 30 is connected. The condensate preheater 26 is guided on the output side to the suction side of a feedwater pump 34. For bypassing the condensate preheater 26 as required, it is bridged with a bypass line 36 into which a motor-actuated valve 38 is connected.

The feedwater pump 34 is formed in the embodiment as a high-pressure feed pump with medium pressure extraction. It brings the condensate K to a pressure level suitable for a high pressure section 40 of the fluid circuit 16 assigned to the high pressure section 12a of the steam turbine 12. The guided through the feedwater pump condensate K, which is referred to as the feed water S on the pressure side of the feedwater pump 34 is supplied to a feedwater heater 42 with medium pressure. This is the output side connected to a medium-pressure steam drum 44. Analogously, the condensate preheater 26 is connected on the output side via a motor-actuatable valve 46 to a low-pressure steam drum 48.

The medium-pressure steam drum 44 is connected to a medium-pressure evaporator 50 arranged in the heat-recovery steam generator 20 to form a medium-pressure evaporator circulation 52. The evaporator circuit 52 comprises a number of only schematically indicated in FIG 1, outside of the heated flue gas R flow channel of the heat recovery steam generator 20 down- fenden downspouts 54, which are connected at their upper end respectively to the bottom of the steam drum 44 and at its lower end in lead a distributor collector not shown here. A multiplicity of riser pipes 56 bundled with waste heat steam generator 20 are fed with liquid fluid, in this case water, from the steam drum 44 or from the downpipes 54, which partially evaporates when flowing through the riser pipes 56 , while up rises and enters the steam drum 44 again as a water-steam mixture.

On the steam side, a medium-pressure superheater 58 is connected to the medium-pressure steam drum 44 and, on the output side, is connected to an exhaust steam line 62 connecting the high-pressure part 12a on the output side to a reheater 60. The reheater 60, in turn, is connected on the output side via a steam line 64, into which a motor-actuatable valve 66 is connected, to the central-pressure part 12b of the steam turbine 12.

On the high pressure side, the feedwater pump 34 is led to a high pressure steam drum 72 via a first high pressure economizer 68 and a second high pressure economizer 70 upstream of the feed water side and downstream of the waste heat steam generator 20 on the flue gas side. The high pressure steam drum 72 is in turn connected to a high pressure evaporator 74 disposed in the heat recovery steam generator 20 to form an evaporator circuit 80 comprising a number of downcomers 76 and risers 78. For discharging live steam F, the high-pressure steam drum 72 is connected to a high-pressure superheater 82 arranged in the heat recovery steam generator 20, which is connected on the output side to the high-pressure part 12a of the steam turbine 12 via a live steam line 84 to a motor-actuated valve 86. The first high-pressure economizer 68 is also bridged with a bypass line 88, into which in turn a motor-operated valve 90 is connected.

The feedwater preheater 42 and the medium-pressure evaporator 50 and the medium-pressure superheater 58, together with the reheater 60 and the medium-pressure part 12b of the steam turbine 12, the intermediate pressure stage 92 of the formed as a water-steam cycle fluid circuit 16. Analog forms in the heat recovery steam generator 20th arranged and to form an evaporator circuit 94 with the low-pressure steam drum 48 connected low-pressure evaporator 96 together with a low-pressure superheater 98 connected to the low-pressure steam drum 48 and the low-pressure part 12c of the steam turbine 12 the low-pressure stage 100 of the fluid circuit 16. Analogous to the high-pressure Verdampfer- 80 and the medium-pressure evaporator circuit 52, the low-pressure evaporator circuit 94 is made of a Number of downpipes 102 connected to the steam drum 48 and a number of riser tubes 104 downstream of the latter. On the output side, the low-pressure superheater 98 is connected to the inlet of the low-pressure part 12 c of the steam turbine 12 via a steam line 106 into which a motor-actuated valve 108 is connected.

For bypassing or diverting the high-pressure part 12a of the steam turbine 12 on demand, the live steam line 84 connecting the high-pressure superheater 82 to the high-pressure part 12a is connected directly to the condenser 18 via a steam line 110 into which a motor-actuated valve 112 is connected. In this case, the steam line 110 serving as a high-pressure bypass is connected in the flow direction of the live steam F upstream of the valve 86 to the main steam line 84.

In order to enable a flexible adaptation of the mode of operation to different requirements with a particularly low design and manufacturing effort, the combined cycle power plant 1 is designed such that the level of liquid fluid in the downpipes 54, 102 of the medium pressure evaporator circuit 52 and of the low-pressure evaporator circuit 94 may at least temporarily drop below the level of the connection to the respective steam drum 44, 48, if necessary, up to a complete dry operation of the evaporator circuit 52 or 94.

For this purpose, the tube wall material of the downpipes 54, 102 downstream of the downcomers, convectively heated by contact with the flue gas R risers 56, 104 is selected in each case with respect to its temperature resistance such that its temperature limit above the in this Be rich of the heat recovery steam generator 20 normally present or maximum expected temperature of the flue gas R is. For example, the temperature of the flue gas R in the region of the medium-pressure evaporator 50 under ordinary circumstances about 300 ⁰ C, in the region of the low-pressure evaporator 96 around 200 ⁰ C. If, for example, the risers 56 of the medium-pressure evaporator 50 to a continuous temperature of about 400 ⁰ C and the risers 104 of the low-pressure evaporator 96 are designed for a continuous temperature resistance of about 300 C, so there are usually sufficient safety reserves available to a temporary drying, z. B. during startup or shutdown of the gas and steam turbines plant 1 or during rapid load changes to tolerate. In particular, the medium-pressure steam drum 44 and the low-pressure steam drum 48 can thus be made particularly compact, since the volume of liquid held to date with fluid to compensate for different steam production rates and ensure continuous feeding of the risers 56, 104 can be relatively small.

However, in order to be able to react adequately even in the case of unforeseen temperature peaks during an imminent or already occurring dry operation of the medium-pressure evaporator circulation 52 and / or the low-pressure evaporator circulation 94 by the introduction of safety measures, the gas and steam turbine plant 1 with a monitoring and control system designed specifically to monitor and control such operating conditions. In particular, the

Medium pressure evaporator circuit 52 and the low pressure evaporator circuit 94 independently monitored in the manner to be described below.

The monitoring of the low-pressure evaporator circuit 94 is as follows: In addition to the hitherto customary monitoring of the water level in the low-pressure steam drum 48, schematically indicated in Figure 2 by the double arrow 114, is now a filling level monitoring is provided, which also includes the downpipes 102 connected to the low-pressure steam drum 48, indicated here schematically by the double arrow 116. A fill-level measuring device (not shown here) thus measures the height of the water column at the lowest point of the downpipes 102, which extends into the steam drum 48 during normal operation of the gas and steam turbine plant 1, but during special situations now also - as described above - can fall below the height level of the upper downpipe connections. It can also be provided to refer the filling level to the downpipe connections, that is to say to the lowest point of the steam drum 48, and to indicate, for example, an overlying level with a positive sign and a level below it with a negative sign. So if z. For example, if the height of the downcomers 102 is two meters, a level of "minus 1.9 meters" would indicate a potentially imminent complete dry operation.

The so measured level of liquid flow medium in the downpipes 102 of the low-pressure evaporator circuit 94 is transmitted to a central evaluation unit, not shown here, a monitoring and control device for the combined cycle power plant 1. A further input variable for the monitoring is the temperature Ti of the flue gas R prevailing in the region of the riser tubes 104, which in the exemplary embodiment according to FIG. 2 is arranged by a flow measuring device 118, which is only shown schematically in the flow direction of the flue gas R, just upstream of the riser tubes 104 in the heat recovery steam generator 20 or whose temperature sensor is detected. The monitoring and control device is configured or programmed to initiate a safety measure in the downpipes 102 at least in an operating condition with a liquid level below the connection to the steam drum 48 as soon as the temperature Ti measured by the temperature measuring device 118 exceeds a predetermined limit - below. This limit value can be predetermined in particular depending on the liquid level in the downpipes 102.

For example, if the temperature limit for the risers 104 of the low-pressure evaporator circuit 94 at 300 C, so may be set at about half height with water-filled downpipes 102, a first limit at 290 ⁰ C, in the first in the bypass line 36 of the Kondensatvorwärmers 26 lying valve 38 is opened. In the case of a complete dry operation, this first limit is suitably set correspondingly lower, z. B. at about 270 ⁰ C.

The opening of the valve 38 causes the condensate K on the suction side of the feedwater pump 34 has a mixing temperature T _M , which adjusts due to the at least partial recirculation of the condensate preheater 26. This mixed temperature T _M is smaller than the condensate temperature T _κ "with completely flowed, ie not flow around condensate preheater 26. Even with preheating a partial flow K ^λ in the condensate preheater 26, a mixing temperature T _M , which is smaller than the temperature T _κ In this way, comparatively cold feed water S reaches both the feed-fluid heater 42 and the first high-pressure economizer 68, with the result that the flue gas R flows in front of the flow in the direction of flow Low pressure stage 100 is relatively strongly cooled. As a result, the low-pressure stage 100, ie in particular the low-pressure evaporator 96, receives comparatively little heat, while at the same time comparatively cooler condensate K flows into the low-pressure steam drum 48 through the condensate line 120. Thus, depending on the position of the valve 38, the temperature load for the riser pipes 104 of the low-pressure stage 100 is greatly reduced and at the same time the water level in the low-pressure steam drum 48 or in the downpipes 102 connected to it is increased again, so that potentially dangerous operating conditions due to the temporary dry operation of the derdruck-Verdampferumlaufs 94 can be counteracted active and targeted as needed.

Should despite the measures described the temperature Ti of the flue gas R in the region of the low-pressure evaporator 96 continue to rise and a second limit of z. B. 320 ⁰ C at half filled with water downpipes 102 or z. B. 300 ⁰ C in dry operation exceed, so the monitoring and control device for the gas and steam turbine 1 initiates further security measures, eg. B. an emergency shutdown of the gas turbine plant Ia.

For the monitoring of the medium-pressure evaporator circulation 52 applies accordingly. That is, it is on the one hand a level measuring device, indicated by the double arrow 124, to

Measurement of the height of the fluid column formed by the flow medium in the downpipes 54 connected to the steam drum 44 and on the other hand provided a temperature measuring device 126 arranged in the flue gas duct just before the risers 56 for measuring the flue gas temperature T ₂ prevailing in the region of the risers 56. Analogous to the low-pressure evaporator circuit 94, a monitoring and control device connected to the temperature and level sensors is configured to initiate a safety measure in an operating condition with a liquid level in the downcomers 54 below the connection to the medium-pressure steam drum 44 as soon as the measured by the temperature measuring device 126, the flue gas temperature T ₂ exceeds a predetermined limit.

For example, a first safety measure may be to open the valve 38 in the bypass line 36 for the condensate preheater 26. Alternatively or additionally, the valve 90 may be opened in the bypass line 88 for the first high-pressure economizer 68, so that comparatively cooler feed water S is supplied to the second high-pressure economizer 70. The second high pressure economizer 70 therefore removes the pressure in this area of the heat recovery steam generator 20 flowing flue gas R compared to the operation with closed bypass valves 38, 90 in addition heat, the smoke gas side downstream medium-pressure heating surfaces and the risers 56 is no longer available. As a result, in particular during dry operation, the temperature load for the riser pipes 56 can be reduced. A second, more drastic security measure can in turn consist in an emergency shutdown of the gas turbine plant Ia.

Particularly advantageous is the ability to temporarily drive the medium-pressure evaporator circuit 52 or the low-pressure evaporator circuit 94, during the so-called bypass operation. Such a bypass operation, which is provided in particular when starting or stopping the steam turbine 12 and at a steam turbine short circuit, leads to a diversion of the generated live steam F, bypassing the steam turbine 12 directly into the condenser 18. For this purpose, the valve 86 is closed and the valve 112th open. In parallel, the condensate preheater 26 is at least partially flowed around by opening the valve 38 located in the bypass line 36. Optionally, the valve 90 in the bypass line 88 is opened, so that due to the above-described heat shifts in the heat recovery steam generator 20, the production of low-pressure steam and possibly also of medium-pressure steam throttled or even completely brought to a standstill. Thus, only high-pressure steam or live steam F is generated, which is, however, introduced directly into the condenser 18 via the vapor line 12 bypassing steam line 110. Due to the possibility of being able to drive the intermediate-pressure evaporator circulation 52 and / or the low-pressure evaporator circulation 94 safely, the enlargement of the medium-pressure steam drum 44 or the low-pressure steam drum 48, which is otherwise necessary in gas and steam turbine plants without divert stations, is opposite such installations, in which diversion stations are present, avoided.

Claims

claims

1. A method for operating a gas and steam turbine plant (1), in which the flue gas (R) leaving a gas turbine (2) is passed through a heat recovery steam generator (20), and in which a steam turbine (12) is driven. used fluid in a number of pressure stages (40, 92, 100) comprising the fluid circuit (16) is guided, wherein at least one of the pressure stages (100) an evaporator circuit (94) with a steam drum (48), with a number of the downcomers (104) connected to the steam drum (48) and having a number of riser pipes (104) connected downstream of the downpipes (102) and also connected to the steam drum (48) and heated by the flue gas (R) in the heat recovery steam generator (20) in that the height of the liquid column formed by the flow medium in the downpipes (102) connected to the steam drum (48) is monitored.

2. The method according to claim 1, characterized in that the temperature (Ti) of the flue gas (R) in the region of the risers (104) is monitored, wherein in an operating condition with a below the connection to the steam drum (48) lying liquid level in the downpipes (102) a safety measure is initiated as soon as the temperature (Ti) of the flue gas (R) in the region of the downpipes (102) downstream risers (104) exceeds a predetermined limit.

3. The method according to claim 2, characterized in that the limit value is specified depending on the liquid level in the downpipes (102).

4. The method of claim 2 or 3, characterized in that as a safety measure a bypass line (36) of the evaporator circuit (94) on the flow side upstream condensate preheater (26) or the evaporator circuit (94) is opened on the flue gas side upstream Speisewasservorwärmers (68).

5. The method according to any one of claims 2 to 4, characterized in that as a security measure a

Power reduction or rapid shutdown of the gas turbine plant (Ia) is initiated, and / or that the flue gas (R) emerging from the gas turbine (2) is at least partially bypassed the heat recovery steam generator (20).

6. The method according to any one of claims 1 to 5, characterized in that at at least three pressure stages (40, 92, 100) each having an evaporator circuit (80, 52, 94) comprising fluid circuit (16), wherein the risers (78, 56, 104) of the evaporator circuits (80, 52, 94) in the flow direction of the flue gas (R) are arranged one behind the other in the heat recovery steam generator (20), the height of the liquid column in the downpipes (102) seen in the flow direction of the flue gas (R) last Evaporator circulation (94), which is preferably designed as a low-pressure evaporator circulation is monitored.

7. The method according to claim 6, characterized in that further the height of the liquid column in the downpipes (54) in the flow direction of the flue gas (R) seen penultimate evaporator circulation (52), which is preferably designed as a medium-pressure evaporator circulation is monitored ,

8. Gas and steam turbine plant (1) with a gas turbine (2) and with one of these abgasseitig downstream heat recovery steam generator (20), and with a number of pressure stages (40, 92, 100) comprising fluid circuit (16) in which a At least one of the pressure stages (100) an evaporator circuit (94) with a steam drum (48), with a number of the steam drum (48) connected downpipes (102) and with a number of the Downpipes (102) downstream, also to the steam drum (48) and connected by the flue gas (R) in the heat recovery steam generator (20) heated risers (104), characterized in that a Füllstandsmessvor- direction for measuring the height of the fluid column formed by the flow medium in the connected to the steam drum (48) downpipes (102) signal output side is connected to a monitoring and control device for the gas and steam turbine plant (1).

9. Gas and steam turbine plant (1) according to claim 8, characterized in that the monitoring and control device signal input side connected to a temperature (Ti) of the flue gas (R) in the region of the risers (104) monitoring temperature measuring device (118) and such is configured to initiate a safety measure in an operating condition with a liquid level in the downpipes (102) below the connection to the steam drum (48) as soon as the temperature (Ti) measured by the temperature measuring device (118) exceeds a predetermined limit ,