Gas turbine and steam turbine installation

A gas turbine and steam turbine installation has a waste-heat steam generator whose heating surfaces are connected into the water/steam cycle of the steam turbine. A gasification device is connected upstream of the gas turbine in order to provide an integrated gasification of a fossil fuel. Reliable operation of a saturator which is connected into a fuel line is ensured independently of the operating condition of the gasification device. For this purpose, a saturator-water heat exchanger connected with its secondary side into the saturator cycle is supplied, on its primary side, with feed water extracted from the water/steam cycle of the steam turbine. Thus it is possible to heat the feed water cooled in the saturator-water heat exchanger through the use of a partial flow of compressed air, and it is possible to supply the partial flow of compressed air to an air separation unit connected upstream of the gasification device.

BACKGROUND OF THE INVENTION
 Field of the Invention
 The invention relates to a gas turbine and steam turbine installation with
 a waste-heat steam generator connected downstream of a gas turbine. The
 heating surfaces of the waste-heat steam generator are connected into the
 water/steam cycle of a steam turbine. A gasification device for gasifying
 fuel is connected, with a fuel line, upstream of a combustion chamber of
 the gas turbine. A saturator is connected into the fuel line. The gasified
 fuel is guided in counterflow to a water flow which is guided in a
 saturator cycle.
 A gas turbine and steam turbine installation with integrated gasification
 of fossil fuel usually includes a fuel gasification device which is
 connected, at the outlet end, to the combustion chamber of the gas turbine
 via a number of components provided for gas cleaning. The waste-heat steam
 generator can then be connected downstream of the gas turbine, at a flue
 gas side. The heating surfaces of the waste-heat steam generator are
 connected into the water/steam cycle of the steam turbine. Such an
 installation is known, for example, from Published UK Patent Application
 GB-A 2 234 984.
 In order to reduce the pollutant emission during the combustion of the
 gasified fossil fuel, a saturator is connected, in this installation, into
 the fuel line between the gasification device and the combustion chamber
 of the gas turbine. The gasified fuel is loaded with water vapor in the
 saturator. For this purpose, the gasified fuel flows through the saturator
 in counterflow to a flow of water which is guided within a water cycle.
 This water cycle is designated as saturator cycle. In order to set a
 temperature level in the saturator which is sufficient for loading the
 gasified fuel with water vapor, heat is coupled into the saturator cycle
 by cooling the tapped or extracted air and/or by cooling the crude gas
 from the fuel gasification.
 In this installation, however, the operation of the saturator depends on
 the operating condition of the gasification device and/or on the operating
 condition of an air separation unit connected upstream of the gasification
 device, so that this concept only has limited flexibility. With respect to
 control, furthermore, such a concept is comparatively complicated and
 therefore susceptible to failure.
 U.S. Pat. No. 5,319,924 discloses to preheat, in a heat exchanger, the feed
 water to be fed into a saturator, wherein it is possible to provide the
 heat exchanger with uncleaned crude gas on the primary side. In addition,
 a saturator configured as a fuel humidifier is known from Published,
 Non-Prosecuted Patent Application DE 43 21 081 in which a heat exchanger,
 which is supplied with feed water on the primary side, is provided for
 preheating the saturator water.
 In the article "Effiziente und umweltfreundliche Stromerzeugung im
 GUD-Kraftwerk mit integrierter Vergasung" [Efficient and environmentally
 friendly power production in a gas and steam power plant with integrated
 gasification] by G. Haupt in "Elektrotechnik und Informationstechnik"
 [Electrical engineering and information technology], AT, Springer Verlag,
 Vienna, Volume 113, No. 1,2 (Feb. 1996), pages 102-105, the heating in a
 heat exchanger of a water flow which is to be fed into a saturator is
 described. The water flow is heated in a heat exchange with feed water
 extracted from the water/steam cycle of the steam turbine and supplied in
 a dedicated reservoir ("flash tank") connected into a circulating circuit.
 A heat exchanger is connected into this circulating circuit and in the
 heat exchanger the feed water absorbs heat from a partial flow of
 compressed air, the air being appropriately cooled in the process.
 SUMMARY OF THE INVENTION
 It is accordingly an object of the invention to provide a turbine
 installation which overcomes the above-mentioned disadvantages of the
 heretofore-known turbine installations of this general type and which
 allows, in a particularly simple manner, reliable operation of the
 saturator even under different operating conditions.
 With the foregoing and other objects in view there is provided, in
 accordance with the invention, a turbine installation, including:
 a gas turbine having a combustion chamber and a flue gas side;
 a steam turbine having a water/steam cycle;
 a waste-heat steam generator connected downstream of the flue gas side of
 the gas turbine, the waste-heat steam generator having heating surfaces
 connected into the water/steam cycle of the steam turbine;
 a fuel line;
 a gasification device for providing gasified fuel, the gasification device
 being connected upstream of the combustion chamber of the gas turbine via
 the fuel line;
 a saturator cycle for guiding a waterflow;
 a saturator connected into the saturator cycle and into the fuel line, the
 saturator guiding the gasified fuel in a counterflow to the water flow
 guided in the saturator cycle;
 a saturator-water heat exchanger connected, with a secondary side thereof,
 into the saturator cycle, the saturator-water heat exchanger being
 supplied, on a primary side thereof, with feed water extracted from the
 water/steam cycle of the steam turbine, the saturator-water heat exchanger
 heating the water flow and cooling the feed water;
 an air separation unit connected upstream of the gasification device;
 an air compressor;
 an extraction air line connecting the air compressor to the air separation
 unit for providing a partial flow of compressed air to the air separation
 unit;
 a feed water tank allocated to the waste-heat steam generator;
 a feed water line connecting the saturator-water heat exchanger at an
 outlet side thereof to the feed water tank; and
 a further heat exchanger connected with a primary side thereof in the
 extraction air line, the further heat exchanger being connected with a
 secondary side thereof into the feed water line, and the further heat
 exchanger heating the feed water and cooling the partial flow of
 compressed air.
 In other words, the object of the invention is achieved by a
 saturator-water heat exchanger, which is connected on the secondary side
 into the saturator cycle to heat the water flow, and which can be
 supplied, on the primary side, with feed water extracted from the
 water/steam cycle of the steam turbine, wherein it is possible to heat the
 feed water cooled in the saturator-water heat exchanger through the use of
 a partial flow of compressed air, wherein it is possible to supply the
 partial flow of compressed air to an air separation unit connected
 upstream of the gasification device, and wherein it is possible to connect
 a further heat exchanger on the primary side in an extraction air line
 connecting the air compressor to the air separation unit in order to cool
 the partial flow of compressed air, the secondary side of the further heat
 exchanger is connected into a feed water line connecting the
 saturator-water heat exchanger at the outlet end to a feed water tank
 associated with the waste-heat steam generator.
 According to another feature of the invention, the air separation unit has
 an inlet side and receives at the inlet side the partial flow of
 compressed air compressed in the air compressor associated with the gas
 turbine; and the gasification device receives oxygen from the air
 separation unit.
 According to a further feature of the invention, the saturator cycle
 defines a flow direction for the water flow; and a feed line opens into
 the saturator cycle upstream of the saturator-water heat exchanger as seen
 in the flow direction of the water flow.
 The invention is based on the consideration that a reliable operation of
 the saturator is made possible even when there are differing operating
 conditions, and therefore a particularly high flexibility of the gas
 turbine and steam turbine installation is achieved in that the saturator
 can be operated independently of the operating parameters of the
 gasification device and the air separation unit. In this connection, the
 coupling of the heat into the saturator cycle, in particular, should not
 take place directly through the use of a medium flowing out of the
 gasification device or through the use of tapped or extracted air flowing
 into the air separation unit. Instead of this, coupling of heat into the
 saturator cycle is, rather, provided through the use of a medium extracted
 from the water/steam cycle of the steam turbine, such that the operating
 parameters for the gasification device and/or the air separation unit, on
 the one hand, and the saturator, on the other, can be set independently of
 one another. The control devices necessary for operating these components
 can also, therefore, be comparatively simply constructed.
 In a particularly advantageous further embodiment, oxygen from an air
 separation unit can be supplied to the gasification device, wherein the
 air separation unit can, for its part, be subjected at the inlet end to a
 partial flow of air compressed in an air compressor associated with the
 gas turbine, a further heat exchanger being connected on the primary side
 in an extraction air line connecting the air compressor to the air
 separation unit in order to cool the partial flow of compressed air, the
 secondary side of the further heat exchanger is connected into a feed
 water line connecting the saturator-water heat exchanger at the output end
 to a feed water tank associated with the waste-heat steam generator. Such
 a configuration ensures a particularly high installation efficiency. The
 feed water flowing to the saturator-water heat exchanger is initially
 cooled by the thermal coupling into the water flow guided in the saturator
 cycle. In the further heat exchanger connected on the feed water side
 downstream of the saturator-water heat exchanger, the cooled feed water
 then experiences reheating, wherein the partial flow of compressed air,
 also referred to as tapped air or extracted air, flowing to the air
 separation unit, is simultaneously cooled. Coupling of heat from the
 tapped air flow into the water/steam cycle of the steam turbine therefore
 occurs to provide a particularly large recovery of heat.
 In order to compensate for losses in the water flow guided in the saturator
 cycle, for example because of the loading or charging of the gasified fuel
 with water vapor in the saturator, a feed line expediently opens into the
 saturator cycle, the entry location of the feed line into the saturator
 cycle being provided before the saturator-water heat exchanger, viewed in
 the flow direction of the water flow, in order to provide a particularly
 high installation efficiency in a particularly advantageous embodiment.
 With such a configuration, a particularly high transfer of heat from the
 feed water to the water flow guided in the saturator cycle is ensured. The
 feed water therefore flows out of the saturator-water heat exchanger with
 a particularly low temperature so that, particularly when the cooled feed
 water is used for cooling the tapped (extracted) air, a particularly
 effective cooling of the tapped air is also made possible.
 The advantages achieved by the invention result from the fact that because
 of the coupling of heat into the saturator cycle through the use of feed
 water extracted from the water/steam cycle of the steam turbine, reliable
 operation of the saturator is made possible independent of the operating
 condition of the gasification device. In consequence, the gas turbine in
 particular can also be operated within specified parameter limits
 independent of the operating condition of the gasification device. Such a
 concept for coupling in heat is therefore particularly flexible and, in
 particular, is also independent of the integration concept, i.e.
 independent of the type of air supply for the air separation unit and the
 components employed for that purpose. Because of the use of the feed
 water, cooled due to the heat transfer to the water flow, for cooling the
 tapped air from the air separation unit, a particularly high installation
 efficiency is also ensured.
 Other features which are considered as characteristic for the invention are
 set forth in the appended claims.
 Although the invention is illustrated and described herein as embodied in a
 gas turbine and steam turbine installation, it is nevertheless not
 intended to be limited to the details shown, since various modifications
 and structural changes may be made therein without departing from the
 spirit of the invention and within the scope and range of equivalents of
 the claims.
 The construction and method of operation of the invention, however,
 together with additional objects and advantages thereof will be best
 understood from the following description of specific embodiments when
 read in connection with the accompanying drawings.

DESCRIPTION OF THE PREFERRED EMBODIMENT
 Referring now to the drawing in detail there is shown a gas turbine and
 steam turbine installation 1 which includes a gas turbine installation 1a
 and a steam turbine installation 1b. The gas turbine installation 1a
 includes a gas turbine 2 with, connected to it, an air compressor 4 and a
 combustion chamber 6, which is connected upstream of the gas turbine 2 and
 is connected to a compressed air line 8 of the compressor 4. The gas
 turbine 2, the air compressor 4 and a generator 10 are located on a common
 shaft 12. The steam turbine installation 1b includes a steam turbine 20
 with, coupled to it, a generator 22 and, in a water/steam cycle 24, a
 condenser 26 and a waste-heat steam generator 30 connected downstream of
 the steam turbine 20. The steam turbine 20 consists of a first pressure
 stage or a high-pressure part 20a and a second pressure stage or a
 medium-pressure part 20b and a third pressure stage or a low-pressure part
 20c, which drive the generator 22 via a common shaft 32.
 An exhaust gas line 34 is connected to an inlet 30a of the waste-heat steam
 generator 30 in order to feed a working medium AM or flue gas expanded in
 the gas turbine 2 into the waste-heat steam generator 30. The expanded
 working medium AM from the gas turbine 2 leaves the waste-heat steam
 generator 30 via its outlet 30b in the direction of a chimney (not shown).
 The waste-heat steam generator 30 includes a condensate preheater 40 which
 can be fed, at its inlet end, with condensate K from the condenser 26 via
 a condensate line 42, into which is connected a condensate pump unit 44.
 At its outlet end, the condensate preheater 40 is connected via a line 45
 to a feed water tank 46. In order, if required, to bypass the condensate
 preheater 40, the condensate line 42 can, in addition, be connected
 directly to the feed water tank 46 via a bypass line (not shown). The feed
 water tank 46 is connected via a line 47 to a high-pressure feed pump 48,
 with medium pressure extraction.
 The high-pressure feed pump 48 brings the feed water S flowing from the
 feed water tank 46 to a pressure level suitable for a high-pressure stage
 50 of the water/steam cycle 24 associated with the high-pressure part of
 the steam turbine 20. The feed water S--which is at a high pressure--can
 be supplied to the high-pressure stage 50 via a feed water preheater 52
 which, at its outlet end, is connected to a high-pressure drum 58 via a
 feed water line 56 which can be shut off by a valve 54. The high-pressure
 drum 58 is connected to a high-pressure evaporator 60 provided in the
 waste-heat steam generator 30 for the formation of a water/steam circuit
 62. For the removal of the live steam F, the high-pressure drum 58 is
 connected to a high-pressure superheater 64 provided in the waste-heat
 steam generator 30, the high-pressure superheater 64 being connected at
 its outlet end to the steam inlet 66 of the high-pressure part 20a of the
 steam turbine 20.
 The steam outlet 68 of the high-pressure part 20a of the steam turbine 20
 is connected via a reheater 70 to the steam inlet 72 of the
 medium-pressure part 20b of the steam turbine 20. The steam outlet 74 of
 the medium-pressure part 20b is connected via a transfer line 76 to the
 steam inlet 78 of the low-pressure part 20c of the steam turbine 20. The
 steam outlet 80 of the low-pressure part 20c of the steam turbine 20 is
 connected via a steam line 82 to the condenser 26 so that a closed
 water/steam cycle 24 results.
 In addition, a branch line 84 branches off from the high-pressure feed pump
 48 at an extraction location at which the condensate K has reached a
 medium pressure. This branch line 84 is connected via a further feed water
 preheater 86 or medium-pressure economizer to a medium-pressure stage 90
 of the water/steam cycle associated with a medium-pressure part 20b of the
 steam turbine 20. For this purpose, the second feed water preheater 86 is
 connected at its outlet end via a feed water line 94, which can be shut
 off by a valve 92, to a medium-pressure drum 96 of the medium-pressure
 stage 90. The medium-pressure drum 96 is connected to a heating surface 98
 provided in the waste-heat steam generator 30 and configured as a
 medium-pressure evaporator in order to form a water/steam circuit 100. For
 the removal of medium-pressure live steam F', the medium-pressure drum 96
 is connected via a steam line 102 to the reheater 70 and therefore to the
 steam inlet 72 of the medium-pressure part 20b of the steam turbine 20.
 A further line 110, which is provided with a low-pressure feed pump 107,
 which can be shut off by a valve 108 and which is connected to a
 low-pressure stage 120 of the water/steam cycle 24 associated with the
 low-pressure part 20c of the steam turbine 20, branches off from the line
 47. The low-pressure stage 120 includes a low-pressure drum 122, which is
 connected, in order to form a water/steam circuit 126, to a heating
 surface 124 provided in the waste-heat steam generator 30 and configured
 as a low-pressure evaporator. In order to remove low-pressure live steam
 F", the low-pressure drum 122 is connected to the transfer line 76 via a
 steam line 128, into which is connected a low-pressure superheater 129.
 The water/steam cycle 24 of the gas turbine and steam turbine installation
 1 therefore includes, in the exemplary embodiment, three pressure stages
 50, 90, 120. As an alternative, however, fewer pressure stages, in
 particular two, can be provided.
 The gas turbine installation la is configured for operation with a gasified
 synthesis gas SG which is generated by the gasification of a fossil fuel
 B. Gasified coal or gasified oil can, for example, be provided as the
 synthesis gas. For this purpose, the combustion chamber 6 of the gas
 turbine 2 is connected at its inlet end via a fuel line 130 to a
 gasification device 132. Coal or oil, as the fossil fuel B, can be
 supplied to the gasification device 132 via a charge system 134.
 In order to make available the oxygen 02 necessary for the gasification of
 the fossil fuel B, an air separation unit 138 is connected via an oxygen
 line 136 upstream of the gasification device 132. At its inlet end, the
 air separation unit 138 can be subjected to a partial flow T of the air
 compressed in the air compressor 4. For this purpose, the air separation
 unit 138 is connected, at its inlet end, to an extraction air line 140
 which branches off from the compressed air line 8 at a branch location
 142. A further air line 143, into which is connected an additional air
 compressor 144, also opens into the extraction air line 140.
 In the exemplary embodiment, the total airflow L flowing to the air
 separation unit 138 is made up of the partial flow T branched off from the
 compressed air line 8 and the airflow delivered by the additional air
 compressor 144. Such a connection concept is also designated a partially
 integrated installation concept. In an alternative embodiment, the
 so-called fully integrated installation concept, it is possible to
 dispense with the further air line 143 and also with the additional air
 compressor 144 so that the complete air feed to the air separation unit
 138 takes place through the use of the partial flow T extracted from the
 compressed air line 8.
 The nitrogen N.sub.2 obtained, in addition to the oxygen O.sub.2, in the
 air separation unit 138 during the separation of the airflow L is supplied
 to a mixing appliance 146, via a nitrogen line 145 connected to the air
 separation unit 138, and is there mixed with the synthesis gas SG. The
 mixing appliance 146 is then configured for a particularly uniform and
 streak-free mixing of the nitrogen N.sub.2 with the synthesis gas SG.
 The synthesis gas SG flowing away from the gasification device 132 passes
 initially, via the fuel line 130, into a crude gas waste-heat steam
 generator 147 in which, through the use of heat exchange with a flow
 medium, cooling of the synthesis gas SG takes place. High-pressure steam
 generated during this heat exchange is supplied, in a manner not shown in
 any more detail, to the high-pressure stage 50 of the water/steam cycle
 24.
 Behind the crude gas waste-heat steam generator 147 and before the mixing
 appliance 146, viewed in the flow direction of the synthesis gas SG, a
 dust-removal device 148 for the synthesis gas SG and a desulphurization
 installation 149 are connected into the fuel line 130. In an alternative
 configuration, a soot-washing appliance can also be provided instead of
 the dust-removal device 148, in particular in the case of the gasification
 of oil as the fuel.
 For particularly low pollutant emission during the combustion of the
 gasified fuel in the combustion chamber 6, the gasified fuel is loaded
 with water vapor before it enters into the combustion chamber 6. This can
 take place in a thermally particularly advantageous manner in a saturator
 system. For this purpose, a saturator 150, in which the gasified fuel is
 guided in counterflow relative to the heated water flow W (also referred
 to as saturator water), is connected into the fuel line 130. The saturator
 water or the water flow W then circulates in a saturator cycle 152, which
 is connected to the saturator 150 and into which a circulating pump 154 is
 connected. A feed line 158 is connected to the saturator cycle 152 to
 compensate for losses of saturator water occurring during the saturation
 of the gasified fuel.
 The secondary side of a heat exchanger 159 acting as a crude gas/mixed gas
 heat exchanger is connected into the fuel line 130 behind the saturator
 150, viewed in the flow direction of the synthesis gas SG. The primary
 side of the heat exchanger 159 is then likewise connected into the fuel
 line 130 at a position in front of the dust removal installation 148, so
 that the synthesis gas SG flowing to the dust removal installation 148
 transfers a part of its heat to the synthesis gas SG flowing out of the
 saturator 150. The guidance of the synthesis gas SG via the heat exchanger
 159 before it enters the desulphurization installation 149 can then also
 be provided in a modified connection concept relative to the other
 components. In the case of the connection of a soot-washing device, in
 particular, the heat exchanger can preferably be provided on the crude gas
 side downstream of the soot-washing device.
 The secondary side of a further heat exchanger 160, whose primary side can
 be heated by feed water or also by steam, is connected into the fuel line
 130 between the saturator 150 and the heat exchanger 159. Particularly
 reliable preheating of the synthesis gas SG flowing to the combustion
 chamber 6 of the gas turbine 2, even in the case of different operating
 conditions of the gas turbine and the steam turbine installation 1, is
 then ensured by the heat exchanger 159, which is configured as a crude
 gas/clean gas heat exchanger, and by the heat exchanger 160.
 In order to subject the synthesis gas SG flowing to the combustion chamber
 6 to steam, if required, a further mixing appliance 161 is, in addition,
 connected into the fuel line 130. Medium-pressure steam can be supplied to
 this further mixing appliance 161 via a steam line (not shown) in order,
 in particular, to ensure reliable gas turbine operation in the case of
 operational faults.
 In order to cool the partial flow T of compressed air, also designated as
 tapped air or extracted air, to be supplied to the air separation unit
 138, the primary side of a heat exchanger 162 is connected into the
 extraction air line 140, the secondary side of this heat exchanger 162
 being configured as a medium-pressure evaporator for a flow medium S'. The
 heat exchanger 162 is connected to a water/steam drum 164, which is
 configured as a medium-pressure drum, in order to form an evaporator
 circuit 163. The water/steam drum 164 is connected to the medium-pressure
 drum 96 associated with the water/steam circuit 100 by lines 166, 168. As
 an alternative, the secondary side of the heat exchanger 162 can also be
 directly connected to the medium-pressure drum 96. In the exemplary
 embodiment, the water/steam drum 164 is therefore directly connected (see
 III, IV) to the heating surface 98, which is configured as a
 medium-pressure evaporator. In addition, a feed water line 170 is
 connected to the water/steam drum 164 in order to top up evaporated flow
 medium S'.
 A further heat exchanger 172, whose secondary side is configured as the
 low-pressure evaporator for a flow medium S", is connected into the
 extraction air line 140 after the heat exchanger 162, viewed in the flow
 direction of the partial flow T of compressed air. The heat exchanger 172
 is then connected to a water/steam drum 176, which is configured as a
 low-pressure drum, in order to form an evaporator circuit 174. In the
 exemplary embodiment, the water/steam drum 176 is connected (see I, II) to
 the low-pressure drum 122, which is associated with the water/steam
 circuit 126, via lines 178, 180 and is therefore directly connected to the
 heating surface 124, which is configured as a low-pressure evaporator. As
 an alternative, however, the water/steam drum 176 can also be connected in
 another suitable manner, wherein it is then possible to supply steam taken
 from the water/steam drum 176 to an auxiliary consumption unit as process
 steam and/or as steam for heating purposes. In a further alternative
 embodiment, the secondary side of the heat exchanger 172 can also be
 directly connected to the low-pressure drum 122. The water/steam drum 176
 is, in addition, connected to a feed water line 182.
 Each of the evaporator circuits 163, 174 can be configured as a forced
 circulation system, the circuit of the flow medium S' or S" being ensured
 by a circulating pump and the flow medium S', S" being at least partially
 evaporated in a heat exchanger 162 or 172 configured as an evaporator. In
 the exemplary embodiment, however, both the evaporator circuit 163 and the
 evaporator circuit 174 are respectively configured as natural circulation
 systems, the circulation of the flow medium S' or S" being ensured by the
 pressure differences arising during the evaporation process and/or by the
 geodetic configuration or positioning of the respective heat exchanger 162
 or 172 and the respective water/steam drum 164 or 176. In this
 configuration, only a comparatively modestly dimensioned circulating pump
 (not shown) is respectively connected into the evaporator circuit 163 or
 into the evaporator circuit 174 for starting the system.
 In order to couple heat into the saturation cycle 152 and therefore for
 setting a temperature in the water flow W sufficient for charging the
 synthesis gas SG with water vapor, a saturator-water heat exchanger 184 is
 provided which can be subjected on the primary side to feed water S from
 the feed water tank 46. For this purpose, the primary side of the
 saturator-water heat exchanger 184 is connected (see V), at the inlet end,
 via a line 186 to the branch line 84 and, at the outlet end, via a line
 188 (see VI) to the feed water tank 46. The saturator-water heat exchanger
 184 is then connected on the secondary side downstream, viewed in the flow
 direction of the water flow W, of the inlet of the feed line 158 into the
 saturator cycle 152.
 For additional heating of the water flow W, if required, an additional heat
 exchanger 189 is connected into the saturator cycle 152 in the exemplary
 embodiment. The additional heat exchanger 189 is then subjected on the
 primary side (see VII, VIII) to preheated feed water from the medium
 pressure stage 90 of the water/steam cycle 24. The additional heat
 exchanger 189 can, however, also be dispensed with --depending on the
 specified emission values and/or combustion gas temperatures.
 A further heat exchanger 190 is connected into the line 188 for reheating
 the cooled feed water S flowing from the saturator-water heat exchanger
 184, this further heat exchanger 190 being connected on the primary side
 downstream of the heat exchanger 172 in the extraction air line 140. Such
 a configuration can achieve a particularly high heat recovery from the
 tapped (extracted) air and, therefore, a particularly high efficiency of
 the gas turbine and steam turbine installation 1.
 A cooling air line 192, through the use of which a partial quantity T' of
 the cooled partial flow T can be supplied as cooling air to the gas
 turbine 2 for blade cooling, branches off from the extraction air line 140
 between the heat exchanger 172 and the heat exchanger 190, viewed in the
 flow direction of the partial flow T.
 Subjecting the saturator-water heat exchanger 184 to feed water S from the
 water/steam cycle 24 of the steam turbine 20 permits reliable operation of
 the saturator 150 independent of the operating condition of the air
 separation unit 138. The overall efficiency of the gas turbine and steam
 turbine installation 1 then benefits particularly from the fact that
 reheating of the feed water S cooled in the saturator-water heat exchanger
 184 takes place in the additional heat exchanger 190. The invention thus
 ensures a reliable setting of the final temperature of the partial flow T
 flowing as tapped air to the air separation unit 138 and also ensures a
 simultaneous recovery of the heat carried in this partial flow for the
 energy generation process of the gas turbine and steam turbine
 installation 1.