EP1848925B1 - Horizontally positioned steam generator - Google Patents

Description

The invention relates to a steam generator, in which an evaporator Durchlaufheizfläche is arranged in a flow-through in an approximately horizontal Heizgasrichtung Heizgaskanal an evaporator Durchlaufheizfläche comprising a number of parallel to the flow of a flow medium steam generator tubes, with a number of each a few steam generator tubes flow medium side downstream outlet collectors.

Such steam generators are eg in US-A-4572110 and in US-A-6055803 disclosed.

In a gas and steam turbine plant, the heat contained in the relaxed working fluid or heating gas from the gas turbine is used to generate steam for the steam turbine. The heat transfer takes place in a heat recovery steam generator connected downstream of the gas turbine, in which a number of heating surfaces for water preheating, steam generation and steam superheating is usually arranged. The heating surfaces are connected in the water-steam cycle of the steam turbine. The water-steam cycle usually includes several, z. B. three, pressure levels, each pressure stage may have a Verdampferheizfläche.

For the gas turbine as heat recovery steam generator downstream of the steam generator come several alternative design concepts, namely the design as a continuous steam generator or the design as circulation steam generator, into consideration. In a continuous steam generator, the heating of steam generator tubes provided as evaporator tubes leads to an evaporation of the flow medium in the steam generator tubes in a single pass. In contrast, in a natural or forced circulation steam generator, the recirculated water is only partially vaporized when passing through the evaporator tubes. The unevaporated water is after a separation of the generated vapor for a further evaporation supplied to the same evaporator tubes again.

In contrast to a natural or forced circulation steam generator, a continuous steam generator is not subject to any pressure limitation, so that it is possible for fresh steam pressures far above the critical pressure of water (P _Kri ≈221 bar) - where no differentiation of the phases water and steam and thus no phase separation is possible. can be designed. A high live steam pressure promotes a high thermal efficiency and thus low CO ₂ emission of a fossil-fired power plant. In addition, a continuous steam generator in comparison to a circulating steam generator a simple construction and is thus produced with very little effort. The use of a designed according to the flow principle steam generator as heat recovery steam generator of a gas and steam turbine plant is therefore particularly favorable to achieve a high overall efficiency of the gas and steam turbine plant with a simple design.

Particular advantages in terms of the manufacturing effort, but also in terms of required maintenance offers a heat recovery steam generator in horizontal construction, in which the heating medium or heating gas, ie the exhaust gas from the gas turbine, is guided in approximately horizontal flow direction through the steam generator. Such a steam generator, which has a particularly high degree of flow stability in a design as a continuous steam generator with comparatively low structural and constructive effort, is for example from the WO 2004/025176 A1 known. This steam generator has an evaporator pass-through heating surface which comprises a number of steam generator pipes or evaporator pipes connected in parallel to the flow through a flow medium. In order to ensure between homogenization and stabilization of the flow conditions seen in Heizgasrichtung successively arranged evaporator tubes, this continuous steam generator, a number of the Evaporator Durchlaufheizfläche downstream outlet collectors, which are aligned with their longitudinal direction substantially parallel to the Heizgasrichtung and thus absorb the seen from in Heizgasrichtung successively arranged and thus differently heated evaporator tubes flowing out flow medium. These outlet headers of the evaporator continuous heating surface also serve as inlet manifolds for the downstream superheater heating surface.

In general, a continuous steam generator is operated in low-load operation or when starting with a minimum flow of flow medium in the evaporator tubes to ensure reliable cooling of the evaporator tubes and to avoid possible formation of steam in the evaporator Durchlaufheizfläche flow medium side upstream economizer heating. This minimum flow is not completely evaporated during startup or during low-load operation in the evaporator tubes, so that in such an operating mode at the end of the evaporator tubes still unvaporized flow medium is present. In other words, in this mode of operation, a water-steam mixture emerges from the evaporator tubes. However, a distribution of such a water-steam mixture on the evaporator tubes usually downstream superheater tubes in the continuous steam generator is usually not possible; the usually provided distribution requires rather that the flow medium to be distributed contains only vapor fractions. Therefore, a water-steam separation is usually required when starting or during low load operation of the continuous steam generator at the outlet of the evaporator Durchlaufheizfläche, which usually takes place in so-called cyclone separators.

Due to the design, a feedthrough of these cyclone separators with water is only possible to a limited extent. The usable for the evaporation heating surface must therefore be seen in the flow direction of the flow medium before the separators and is thus limited. This has the consequence that the live steam temperature can be controlled only in small limits by the amount of feed water, which are usually required for a larger control range injection cooler. The associated with these aspects restriction of operational flexibility usually requires in addition to the high equipment costs usually undesirably long startup times and response times with load changes of the continuous steam generator in low load operation.

The invention is therefore an object of the invention to provide a continuous steam generator of the type mentioned above, which allows for low production costs even in start-up or low load operation, a particularly high operational flexibility and thus in particular also kept low start-up and load change times.

This object is achieved in that the or each outlet header each comprises an integrated Wasserabscheiderelement via which the respective outlet header is connected on the steam side with a number of downstream superheater tubes a Überhitzerheizfläche.

The invention is based on the consideration that in order to achieve a particularly high operational flexibility even in start-up or low-load operation, a particularly large proportion of the total available heating surfaces should be usable for evaporation purposes. In this case, in particular, a superheater heating surface connected downstream of the evaporator throughflow heating surface should also be used for evaporation of the flow medium if necessary, that is to say just for start-up or light-load purposes. Accordingly, the evaporation end point should be slidable into the superheater heating surface. To make this possible, the transition area between the evaporator passage heating surface and the subsequent superheater heating surface should be designed such that a feed of water into the superheater heating surface is possible. In view of the distribution problems usually associated with the feeding of water, therefore, the water separation system connected between the evaporator flow heating surface and the superheater heating surface should be designed such that a complex distribution is not required. This can be achieved by deviating from the conventionally provided central water-steam separation, the water separation system is designed decentralized, wherein the separation function is integrated tube groups in a plurality of parallel connected, individual pipe groups associated components. For this purpose, the type of construction anyway associated with only a small number of evaporator tubes, provided with their longitudinal direction in Heizgasrichtung outlet collector are provided.

Advantageously, the outlet collectors are designed for a water-vapor separation according to the principle of inertial separation as required. The knowledge is used that due to the considerable inertial differences between steam on the one hand and water on the other hand, the vapor content of a water-steam mixture at an existing flow comparatively much easier deflection can be subjected as the proportion of water. Especially when integrating the water separation function in the outlet collector or in this can be implemented in a particularly simple manner by advantageously the respective outlet header is designed substantially as a cylinder body which is connected at its not connected to the steam generator tubes end with a Wasserableitrohrstück.

In this case, in a further advantageous embodiment of the respective cylinder body or the respective Wasserableitrohrstück branches off a Abströmrohrstück for flow medium, which is advantageously connected to a number of downstream superheater tubes. In this embodiment, the discharge collector provided with an integrated water separation function is thus essentially in the manner of a T-piece formed, in which the cylinder body forms a substantially straight-through channel, in which due to its relatively higher inertia preferably the water content of the flow medium is performed. From this channel branches off the Abströmrohrstück, in which due to its relatively lower inertia preferably the vapor content of the flow medium is deflected into.

Advantageously, the outlet collector - viewed from above - aligned with its longitudinal direction substantially parallel to the Heizgasrichtung so that they take the view of Heizgasrichtung successively arranged and thus differently heated evaporator tubes flowing flow medium. Viewed in the lateral direction, the outlet header can also be aligned substantially parallel to the direction of the heating gas. However, a particularly high separation efficiency is achievable in that the outlet collector with integrated separation function is preferably designed so that on the one hand the water content of the flow medium is preferably guided on the inner wall of the cylinder body opposite the branching outflow pipe piece and on the other hand the discharge of the water is favored. For this purpose, the cylinder body and / or the Wasserableitrohrstück are advantageously arranged with its longitudinal direction relative to the horizontal in the flow direction of the flow medium inclined downwards. The inclination can also be relatively strong, so that the cylinder body is oriented substantially vertically. In this case, said inertia separation is additionally favored by the gravitational effect on the water content of the flow medium flowing in the cylinder body.

A particularly simple design with regard to the flow guidance of the separated water can be achieved by advantageously some or all Wasserabscheiderelemente water outlet side groups each with a common Outlet collector are connected, in turn, in a further advantageous embodiment, a water collection tank is connected downstream.

In the separation of water and steam in Wasserabscheidesystem either almost the entire water content can be deposited, so that only evaporated flow medium is passed on to the downstream superheater tubes. In this case, the evaporation end point is either still in the evaporator tubes or is fixed in Wasserabscheidesystem itself. Alternatively, however, only a portion of the resulting water can be deposited, the remaining still unvaporized flow medium is passed together with the vaporized flow medium in the subsequent superheater tubes. In this case, which comes into play especially in the superimposition of an additional circulation on the actual media flow in low load or starting operation, the evaporation end point shifts into the superheater tubes.

In the latter case, also referred to as Überspeisung the separator, first the water separator elements downstream water components such as outlet header or water tank are completely filled with water, so that forms a backwater with further inflowing water in the corresponding line pieces. Once this backwater has reached the Wasserabscheiderelemente, at least a partial flow of new inflowing water is passed along with the entrained in the flow medium steam to the subsequent superheater tubes. In terms of extent, this partial flow corresponds to the amount of water that can not be absorbed by the downstream components of the water separator elements. In order to ensure a particularly high operational flexibility in this mode of operation of the so-called overfeeding of the separation system, is advantageously in a connected to the water collection drain pipe connected via an associated control device controllable control valve. The control device is advantageously acted upon by an input value characteristic of the enthalpy of the flow medium on the steam-side outlet of the superheater heating surface arranged downstream of the water separation system.

By means of such a system, the mass flow flowing out of the water collecting container can be adjusted in the operating mode of the bypassed separating system by targeted activation of the valve connected in the outflow line of the water collecting container. Since this is replaced by a corresponding mass flow of water from the Wasserabscheiderelementen, thus, the mass flow is adjustable, which passes from the Wasserabscheiderelementen in the collection system. Thus, in turn, the remaining partial flow is adjustable, which is passed together with the steam in the superheater tubes, so that a predetermined enthalpy can be maintained via an appropriate setting of this partial flow, for example, at the end of the downstream superheater. Alternatively or additionally, the water partial flow passed on together with the steam to the superheater pipes can also be influenced by a corresponding control of the superimposed circulation. For this purpose, in a further or alternative advantageous embodiment of the control device associated with the evaporator tubes circulating pump can be controlled.

Advantageously, the respective outlet collector provided with integrated water separation function is designed for the use of gravity to facilitate the removal of the separated water. For this purpose, the or each outlet collector is advantageously arranged above the Heizgaskanals.

A particularly high operational stability of the steam generator can be achieved by the evaporator Durchlaufheizfläche is designed for a self-stabilizing flow behavior with occurring heating differences between individual steam generator tubes of Durchlaufheizfläche. This can be achieved by the evaporator Durchlaufheizfläche is designed in a particularly advantageous embodiment such that a more heated compared to another steam generator tube Durchlaufheizfläche same steam generator tube has a higher compared to the other steam generator tube throughput of the flow medium. The thus designed evaporator Durchlaufheizfläche thus shows in the nature of the flow characteristics of a Naturumlaufverdampferheizfläche (natural circulation) with occurring different heating individual steam generator tubes a self-stabilizing behavior that leads to an adjustment of the exit temperatures even at differently heated, flow medium side parallel steam turbine tubes without the need for external influence ,

Conveniently, the steam generator is used as a heat recovery steam generator of a gas and steam turbine plant. In this case, the steam generator is advantageously followed by a gas turbine on the hot gas side. In this circuit can be arranged expediently behind the gas turbine, an additional firing to increase the temperature of the heating gas.

The advantages achieved by the invention are in particular that a decentralized Wasserabscheidesystem can be provided by the integration of Wasserabscheidefunktion in the outlet collector, in which due to the small number of each water separator downstream superheater tubes can be a complex distribution system omitted. Thus, a feed of unevaporated flow medium through the water is possible, so that the evaporation end point can be moved into the superheater tubes if necessary. Thus, especially in start-up and low-load operation particularly large proportions of the heating surfaces are used for evaporation purposes, wherein In addition, a particularly high operational flexibility can be achieved even under these load conditions. In particular, by the T-piece-like configuration of the outlet collector as a cylinder body with branching Abströmrohrstück can also be achieved by simple means a reliable water separation according to the principle of inertial separation.

An embodiment of the invention will be explained in more detail with reference to a drawing. The figure shows in a simplified representation in longitudinal section the evaporator section of a steam generator in horizontal construction.

The steam generator 1 shown in the figure with its evaporator section downstream in the manner of a heat recovery steam generator of a gas turbine, not shown, downstream. The steam generator 1 has a surrounding wall 2, which forms a in a nearly horizontal, indicated by the arrows 4 Heizgasrichtung x fuel gas channel 6 for the exhaust gas from the gas turbine. In the heating gas channel 6, a designed according to the flow principle evaporator Durchlaufheizfläche 8 is arranged, which is followed by a superheater 10 for the flow of a flow medium W, D.

The evaporator Durchlaufheizfläche 8 is acted upon with unvaporized flow medium W, which evaporates in normal or full load operation with a single pass through the evaporator Durchlaufheizfläche 8 and after exiting the evaporator Durchlaufheizfläche 8 as steam D superheater 10 is supplied. The evaporator through-flow heating surface 8 and the superheater 10 formed evaporator system is connected in the non-illustrated water-steam cycle of a steam turbine. In addition to this evaporator system, a number of other, not shown in FIG heating surfaces are connected in the water-steam cycle of the steam turbine, which, for example, in which can be superheater, medium pressure evaporator, low pressure evaporator and / or preheater.

The evaporator passage heating surface 8 is formed by a number of parallel to the flow of the flow medium W steam generator tubes 12. The steam generator tubes 12 are aligned substantially vertically with their longitudinal axis and designed for a flow through the flow medium W from a lower inlet region to an upper outlet region, ie from bottom to top.

Here, the evaporator Durchlaufheizfläche 8 comprises in the manner of a tube bundle a number of seen in Heizgasrichtung x successively arranged pipe layers 14, each of which is formed from a number of viewed in Heizgasrichtung x juxtaposed steam generator tubes 12, and of which in FIG each only one Steam generator tube 12 is visible. Each pipe layer 14 may comprise up to 200 steam generator tubes 12. The steam generator tubes 12 of each tube layer 14 are each preceded by a common inlet collector 16 aligned with its longitudinal direction substantially perpendicular to the heating gas direction x and arranged below the heating gas channel 6. Alternatively, a common inlet header 16 may also be assigned to a plurality of pipe layers 14. The inlet header 16 are connected to a in FIG only schematically indicated water supply system 18, which may include a distribution system for needs-based distribution of the influx of flow medium W to the inlet header 16. On the output side and thus in an area above the heating gas channel 6 open the evaporator Durchlaufheizfläche 8 forming steam generator tubes 12 in a number of associated outlet headers 20th

Analogously, the superheater heating surface 10 is formed by a number of superheater tubes 22. These are designed in the exemplary embodiment for a flow of the flow medium in the downward direction, ie from top to bottom. On the input side is the superheater tubes 22 upstream of a number of designed as a so-called T-distributor distributors 24. On the output side, the superheater tubes 22 open into a common live steam collector 26, from which the superheated live steam can be supplied in a manner not shown to an associated steam turbine. In the exemplary embodiment, the live steam collector 26 is arranged below the heating gas channel 6. Alternatively, however, the superheater heating surface 10 could also be equipped with U-shaped superheater tubes 22. In this case, not shown in the FIG case, each superheater tube 22 each comprise a downcomer piece and this downstream riser piece, wherein the live steam collector 26 as well as the outlet header 20 is disposed above the Heizgaskanals 6. In this case, a drainage collector can be connected between downpipe pipe and riser pipe piece.

The evaporator pass-through heating surface 8 is designed such that it is suitable for feeding the steam generator tubes 12 with a comparatively low mass flow density, wherein the design flow conditions in the steam generator tubes 12 have a natural circulation characteristic. In this natural circulation characteristic, a more heated steam generator tube 12 compared to another steam generator tube 12 of the same evaporator pass-through heating surface 8 has a higher throughput of the flow medium W compared to the other steam generator tube 12.

The steam generator 1 is designed for a reliable, homogeneous flow guidance with a comparatively simple construction. The designed according to the design of the evaporator Durchlaufheizfläche 8 natural circulation characteristic is consistently used for a simple held distribution system. This natural circulation characteristic and the concomitantly designed, comparatively low mass flow density that is provided allow the merging of the partial flows from one another in heating gas direction x arranged and thus differently heated steam generator tubes in a common room. With the saving of an autonomous complex distribution system, it is thus possible to shift the mixing of the flow medium W flowing out of the evaporator through-flow heating surface 8 into the outlet collector or outlets 20.

In order to minimize the thereby achieved homogenization of viewed in Heizgasrichtung x differently positioned and thus differently heated steam generator tubes 12 flowing out flow medium W as it passes into subsequent system, each of substantially parallel to each other and juxtaposed outlet collector 20, of which in FIG only one is visible, aligned with its longitudinal axis substantially parallel to the heating gas x direction. The number of outlet headers 20 is adapted to the number of steam generator tubes 12 in each tube layer 14, so that in each case an outlet header 20 is assigned to each of the steam generator tubes 12 positioned one behind the other, forming a so-called evaporator disc. Analogously, the distributors 24 are each aligned with their longitudinal axis parallel to the heating gas direction x, so that in each case a respective distributor 24 is assigned to the respective superheater tubes 22 positioned in succession.

The steam generator 1 is designed so that, if necessary, in particular in start-up or low-load operation, the steam generator tubes 12 in addition to the vaporizable mass flow of flow medium for reasons of operational safety yet another Umwälzmassenstrom can be superimposed on the flow medium. In order to ensure a particularly high operational flexibility and thus particularly low start-up and load change times and to keep usable a particularly large proportion of heating surfaces, it is provided that in this operating state of the evaporation endpoint of the steam generator tubes 12 in the Superheater tubes 22 can be moved into it. In order to make this possible with comparatively low production costs, each of the outlet headers 20 comprises an integrated water separator element 28, via which the respective outlet header 20 is connected via an overflow pipe 30 to one of the downstream distributors 24 on the flow medium side. By this construction is particularly ensured that after the water-vapor deposition, a complex distribution of water-steam mixture to the superheater tubes 22 is not required.

For a high separation efficiency with high operational reliability, the discharge collectors 20 each provided with integrated separation function are designed for the concept of inertial separation of a water-steam mixture. In this case, the knowledge is used that the water content of a water-steam mixture due to its relatively greater inertia at a branch point preferably continues to flow straight in its flow direction, whereas the vapor content of a forced deflection is relatively easier to follow due to its relatively lower inertia. In order to make use of this for a particularly simple construction of the water separation, the outlet headers 20 are each embodied in the form of T-pieces, wherein an outlet pipe piece 34 for flow medium branches off from a main body designed substantially as a cylinder body 32.

The designed as a cylinder body 32 main body of the respective outlet header 20 is connected at its not connected to the steam generator tubes 12 end 36 with a Wasserableitrohrstück 38. By this construction thus flows the water content of the water-steam mixture in the outlet header 20 at which the respective integrated Wasserabscheiderelement 28 forming branch point of Abströmrohrstücks 34 preferably in the axial direction and passes The steam content of the water-steam mixture flowing in the cylinder body 32, on the other hand, can better follow an imposed deflection because of its comparatively lower inertia and thus preferably flows via the outflow pipe section 34 and the further intermediate components to the downstream superheater pipes 22 too. To reinforce the separation effect achieved thereby and / or to facilitate the removal of water, the cylinder body 32 can be arranged with its longitudinal direction opposite the horizontal in the flow direction inclined downwards.

Water outlet side, so on the Wasserableitrohrstücke 38, the integrated into the outlet header 20 Wasserabscheiderelemente 28 are connected in groups with a respective common outlet header 40. This is a water collection tank 42, in particular a separation bottle, downstream. On the output side, the water collecting container 42 is connected via a connected outflow line 44, from which also a discharge line 45 connected to a sewage system, to the water supply system 18 of the continuous evaporator heating surface 8, so that a closed circulation circuit can be operated. About this circulation can be superimposed in start-up, low or partial load operation flowing into the steam generator tubes 12 evaporable flow medium, an additional circulation to increase the operational safety. Depending on the operational requirement or requirement, the separating system formed by the integrated water separator elements 28 can be operated in such a way that all water still entrained at the outlet of the steam generator tubes 12 is separated from the flow medium and only evaporated flow medium is passed on to the superheater tubes 22.

Alternatively, the Wasserabscheidesystem can also be operated in the so-called over-flow mode, in which not all water is separated from the flow medium, but together with the steam, a partial flow of entrained water is passed on to the superheater tubes 22. In this mode, the evaporation end point shifts into the superheater tubes 22. In such over-fed mode, first both the water collecting container 42 and the upstream outlet header 40 completely fill with water, so that a backflow forms up to the transition region respective water separator element 28, at which the Abströmrohrstück 34 branches off. Due to this backwater also experiences the water content of the water separator 28 incoming flow medium at least partially a deflection and thus passes together with the steam in the Abströmrohrstück 34. The height of the partial flow, which is supplied to the superheater tubes 22 together with the steam results here on the one hand, from the total water mass flow supplied to the respective water separator element 28 and, on the other hand, from the partial mass flow discharged via the water drainage pipe section 38. Thus, by appropriate variation of the supplied water mass flow and / or the water mass flow discharged via the Wasserableitrohrstück 38 of the passed into the superheater tubes 22 mass flow of non-evaporated flow medium can be adjusted. Thus, it is possible to adjust by controlling one or both of the mentioned sizes, the proportion of passed to the superheater tubes 22 unverdampftem flow medium such that, for example, a predetermined enthalpy at the end of the superheater 22 sets.

In order to make this possible, the water separation system is associated with a control device 60 which is connected on the input side to a measuring sensor 62 designed to determine a characteristic value characteristic of the enthalpy at the flue gas end of the superheater heating surface 22. On the output side, the control device 60 acts, on the one hand, on a control valve 64 connected in the outflow line 44 of the water collecting container 42. This can be specified by selective control of the control valve 64, the water flow, the off taken from the separation system. This mass flow can in turn be withdrawn from the flow medium in the water separator elements 28 and forwarded to the subsequent collection systems. Thus, by controlling the control valve 64 influencing the Wasserabscheiderelement 28 respectively branched off water flow and thus influencing the after the deposition still passed in the flow medium to the Überhitzerheizflächen 22 water content possible. Alternatively or additionally, the control device 60 can still act on a circulating pump 66 connected in the outflow line 44, so that the inflow rate of the medium into the water separation system can also be adjusted accordingly.

Claims (11)

1. Steam generator (1), in which an evaporative once-through heating surface (8) is arranged in a hot gas passage (6) which is exposable to through-flow in an approximately horizontal hot gas direction (x), which evaporative once-through heating surface comprises a number of steam generator tubes (12) which are connected parallel to the through-flow of a flow medium, with a number of outlet headers (20) which are connected downstream on the flow medium side to some steam generator tubes (12) in each case,
   characterized in that
   the outlet header (20), or each outlet header, comprises an integrated water separator element (28) in each case, by means of which the respective outlet header (20) is connected on the steam side to a number of downstream-connected superheater tubes (22) of a superheater heating surface (10).
2. Steam generator (1) according to Claim 1, characterized in that
   the outlet header (20), or each outlet header, is designed basically as a cylindrical body (32) in each case, which by its end (36) which is not connected to the steam generator tubes (12) is connected to a water drain pipe section (38).
3. Steam generator (1) according to Claim 2, characterized in that
   an outflow pipe section (34) for flow medium branches off from the respective cylindrical body (32) or from the respective water drain pipe section (38).
4. Steam generator (1) according to Claim 2 or 3,
   characterized in that
   the cylindrical body (32) and/or the water drain pipe section (38) are arranged with their respective longitudinal direction inclined downwards in the flow direction in relation to the horizontal.
5. Steam generator (1) according to one of Claims 1 to 4,
   characterized in that
   some or all the water separator elements (28) are connected on the water outlet side in groups to a common outlet header (40) in each case.
6. Steam generator (1) according to Claim 5,
   characterized in that
   a water collecting vessel (42) is connected downstream to the respective outlet header (40).
7. Steam generator (1) according to Claim 6,
   characterized in that
   a control valve (64), which is controllable by means of an associated control unit (60), is connected into a discharge line (44) which is connected to the water collecting vessel (42), wherein the control unit (60) is subjectable to an input value which is characteristic for the enthalpy of the flow medium at the outlet on the steam side of the superheater heating surface (10) which is connected downstream to the water separating system.
8. Steam generator (1) according to Claim 7,
   characterized in that
   a circulating pump (66), which is associated with the steam generator tubes (12), is controllable by means of the control unit (60).
9. Steam generator (1) according to one of Claims 1 to 8,
   characterized in that
   the outlet header (20), or each outlet header, is arranged above the hot gas passage (6).
10. Steam generator (1) according to one of Claims 1 to 9,
    characterized in that
    the evaporative once-through heating surface (8) is designed in such a way that one steam generator tube (12) which is heated more in comparison to a further steam generator tube (12) of the same evaporative once-through heating surface (8), has a higher throughput of flow medium in comparison to the further steam generator tube (12).
11. Steam generator (1) according to one of Claims 1 to 10,
    characterized in that
    a gas turbine is connected upstream on the hot gas side to the hot gas passage (6).

Images