EP1398565A1 - Horizontally positioned steam generator - Google Patents

Abstract

The horizontal steam generator (1) has a horizontal gas flow direction (x) channel (6) with a through flow heating surface (8) and multiple steam generator tubes (12) extending in parallel across the gas flow. The tubes are connected to a discharge manifold (20) extending parallel to the gas flow. The manifold can be cylindrical.

Description

The invention relates to a steam generator, in which in a Flowable in an approximately horizontal heating gas direction Heating gas channel arranged an evaporator continuous heating surface which is a number of to flow through a flow medium steam generator pipes connected in parallel, and which is designed so that a compared to another steam generator tube of the same continuous heating surface multi-heated steam generator tube compared to another steam generator tube higher throughput of the flow medium having.

In a gas and steam turbine plant, the is relaxed Work equipment or heating gas contained in the gas turbine Heat used to generate steam for the steam turbine. The heat transfer takes place in a downstream of the gas turbine Heat recovery steam generator, in which usually a Number of heating surfaces for water preheating, for steam generation and is arranged for steam superheating. The heating surfaces are connected to the water-steam cycle of the steam turbine. The water-steam cycle usually comprises several z. B. three, pressure levels, each pressure level an evaporator heating surface can have.

For the gas turbine as waste heat generator on the hot gas side Downstream steam generators come with several alternatives Design concepts, namely the design as a continuous steam generator or the design as a circulation steam generator. In the case of a once-through steam generator, the heating leads of steam generator tubes provided as evaporator tubes evaporation of the flow medium in the steam generator tubes in a single pass. In contrast to that in the case of a natural or forced circulation steam generator led water during a passage through the evaporator tubes only partially evaporated. The water that has not evaporated is after a separation of the steam generated for a further evaporation fed to the same evaporator tubes again.

In contrast to a natural or forced circulation steam _{generator, a once-through} steam generator is not subject to any pressure limitation, so that for live steam pressures it is far above the critical pressure of water (P _kri ≈ 221 bar) - where it is not possible to distinguish between the phases of water and steam and therefore no phase separation - can be interpreted. A high live steam pressure promotes high thermal efficiency and thus low CO ₂ emissions from a fossil-fired power plant. In addition, a continuous steam generator has a simple construction in comparison to a circulation steam generator and can therefore be produced with particularly little effort. The use of a steam generator designed according to the continuous flow principle as waste heat steam generator of a gas and steam turbine system is therefore particularly favorable in order to achieve a high overall efficiency of the gas and steam turbine system with a simple construction.

Special advantages in terms of manufacturing effort, but also offers required maintenance work a heat recovery steam generator in a horizontal design, in which the heating medium or heating gas, i.e. the exhaust gas from the gas turbine, in approximately horizontal flow direction the steam generator is guided. At a steam generator in The steam generator tubes of a heating surface can be constructed horizontally however depending on their positioning a very different one Exposed to heating. Especially on the output side steam generator tubes connected to a common collector of a once-through steam generator can be a different one Heating of individual steam generator tubes to one Merging steam streams with strong from each other deviating steam parameters and thus to undesirable losses in efficiency, especially to a comparative reduced effectiveness of the affected heating surface and one reduced steam generation. A different one Heating of neighboring steam generator tubes can also, especially in the mouth area of collectors Damage to the steam generator pipes or the collector. The desirable use of a lying construction executed continuous steam generator as heat recovery steam generator For a gas turbine this can pose significant problems with regard to a sufficiently stabilized flow guidance entail.

A steam generator is known from EP 0 944 801 B1 is suitable for a layout in horizontal construction and also has the mentioned advantages of a once-through steam generator. This is the evaporator heating surface of the known steam generator connected as a continuous heating surface and such designed that a compared to another steam generator tube same continuous heating surface multi-heated steam generator tube one compared to the other steam generator tube has higher throughput of the flow medium. Under Pass-through heating surface is generally a heating surface to understand the flow for the flow principle is designed. That of the interconnected as a continuous heating surface Flow medium supplied to evaporator heating surface is in a single pass through this continuous heating surface or by a plurality of series connected Continuous heating surface system completely evaporated.

The evaporator heating surface connected as a continuous heating surface of the known steam generator thus shows in the type of flow characteristic a natural circulation evaporator heating surface (Natural circulation characteristic) when different occur Heating individual steam generator tubes a self-stabilizing Behavior that requires no outside influence to equalize the outlet temperatures also on differently heated, fluid medium side steam generator pipes connected in parallel.

The known steam generator has a multi-stage design Evaporator system on which a first continuous heating surface another evaporator continuous heating surface on the flow medium side is connected downstream. To be a reliable and comparatively homogeneous overflow of the flow medium to ensure from the first to the second continuous heating surface is the well-known steam generator with a complex Distribution system provided that a comparatively high structural and constructive effort.

The invention is therefore based on the object of a steam generator of the type mentioned above, with which also comparatively little structural and constructive effort a particularly high degree of flow stability during operation the evaporator heating surface switched as a continuous heating surface or evaporator continuous heating surface is accessible.

This object is achieved in that a the steam generator tubes of the evaporator continuous heating surface outlet manifold downstream on the flow medium side its longitudinal axis essentially parallel to the direction of the heating gas is aligned.

The invention is based on the consideration that the structural and constructive effort in the creation of the Steam generator can be kept low by the number of the component types used is reduced to a particular degree becomes. Such a reduction of components is in the Steam generator of the above type by saving the Continuous heating surface accessible downstream distribution system, by the already provided property of Continuous heating surface, namely the self-stabilizing circulation characteristic, is consistently used. Precisely because of This characteristic can namely be the mixture of the different, steam generator tubes connected in parallel to each other flowing fluid and its transfer in the downstream heating surface system without any significant impairment the homogenization achieved in the mixture from a downstream distribution system in the steam generator pipes anyway downstream outlet collector be shifted in without this being noteworthy Flow instabilities or other problems would. Accordingly, this can be comparatively complex Distribution system is eliminated. One for this purpose, namely for suitable mixture and continuation of that from the steam generator tubes outflowing flow medium, suitable design the outlet collector can be reached by moving in the direction of the heating gas seen arranged one behind the other and thus one locally different with regard to the heating profile Heating exposed steam generator tubes of the evaporator continuous heating surface on the output side in a common Merging room. Such, for those in the heating gas direction seen steam generator pipes arranged one behind the other Common collector room is through an alignment of the outlet collector with its longitudinal axis essentially parallel to the hot gas direction.

A particularly simple construction of the outlet collector can be reached by this advantageously in is essentially designed as a cylinder body.

Included for a comparatively simple design the evaporator flow heating surface preferably in the manner of a tube bundle a number of seen in the heating gas direction Pipe layers arranged one behind the other, each of which consists of a Number of juxtaposed seen in the heating gas direction Steam generator tubes is formed. Each could an appropriate number of steam generator tubes each A common outlet collector is assigned to each pipe position his. The flow heating surface on the flow medium side subsequent distribution of the flow medium with savings a complex distribution system can be particularly simple be carried out by in a further advantageous embodiment the continuous heating surface one of the number of steam generator tubes corresponding number of in each pipe position with their longitudinal axis essentially parallel to the heating gas direction aligned exit collectors. It ends one steam generator tube each in each outlet header Pipe position.

The evaporator system of the steam generator is preferably in the type of a multi-stage design, the Evaporator continuous heating surface in the manner of a pre-evaporator for suitable conditioning of the flow medium its entry into a further evaporator once-through heating surface is provided. The further evaporator continuous heating surface therefore serves as a second Evaporator stage to complete the evaporation of the Flow medium.

The further evaporator once-through heating surface is also expedient taken for a self-stabilizing Flow behavior through consistent use of a natural circulation characteristic designed in the respective steam generator tubes. For this purpose, the further evaporator continuous heating surface includes advantageously a number of to flow through the Flow medium steam generator tubes connected in parallel. It is also expediently designed such that one compared to another steam generator tube the other Continuous heating surface of a multi-heated steam generator tube compared to the other steam generator tube higher Has flow rate of the flow medium.

During the evaporator flow heating surface of the steam generator expediently from essentially vertically oriented for flow through the flow medium from below is formed upward provided steam generator tubes is the further evaporator flow heating surface in a particularly advantageous Design made of U-shaped steam generator tubes educated. In this embodiment, the further evaporator tubes forming evaporator once-through heating surface each approximately vertically arranged, from Flow medium flowable downward flow and approximately one downstream of this on the flow medium side vertically arranged and upward from the flow medium flowable riser pipe section.

In the design of the further continuous heating surface with a U-shaped Steam generator tubes could be in the downpipe pieces forming vapor bubbles against the flow direction of the Flow medium rise and thus the stability of the Adversely affect flow. To do this avoid, the evaporator system is advantageously on a consistent entrainment of such vapor bubbles with the Flow medium designed.

In order to achieve this desired effect of a consistent take of in the downpipe section of a steam generator tube of the further continuous heating surface possibly existing vapor bubbles reliably ensure the continuous heating surface is expedient dimensioned in such a way that in the further flow heating surface flowing downstream Flow medium a flow velocity of more than the steam bubbles required to take away Has minimum speed.

Due to the substantially U-shaped configuration of the steam heater tubes forming further continuous heating surface their inflow area in the upper area or above the heating gas duct. With consistent use of the assigned to the evaporator flow heating surface, above the Heating gas channel arranged and with their longitudinal direction in each case essentially parallel to the direction of flow of the Outlet gas-oriented outlet manifold is an interconnection the evaporator flow heating surface with the further evaporator flow heating surface with a particularly small Effort is made possible by the or each exit collector the evaporator flow heating surface in an advantageous embodiment with an entry collector assigned to the Evaporator continuous heating surface connected on the flow medium side is integrated into a constructive unit. A such an arrangement enables direct overflow that exits from the first evaporator once-through heating surface Flow medium in the downstream of the fluid medium Steam generator tubes of the further evaporator continuous heating surface. Elaborate distribution or connecting lines between the outlet header of the evaporator continuous heating surface and the inlet collector of the further evaporator continuous heating surface as well as assigned mixing and distribution elements can be omitted, and in general the routing is comparatively easy.

In a further advantageous embodiment, the steam generator tubes of the further evaporator continuous heating surface on the inlet side in a common, perpendicular to the longitudinal axis the outlet collector and thus perpendicular to the direction of the heating gas aligned level to the entry collector assigned to them connected. With such an arrangement it is ensured that the partially evaporated, the other Flow medium to be supplied to evaporator continuous heating surface, starting from as an outlet collector for the first evaporator continuous heating surface used part of the integrated unit, first against the bottom of the as an entry collector for the part of the evaporator flow heating surface used constructive unit bounces, there is again swirled and then with almost the same two-phase components in the steam generator pipes connected to the respective inlet manifold the further evaporator continuous heating surface flows. This is a forwarding of the flow medium into the steam generator tubes of the further evaporator continuous heating surface without noticeable impairment of the mixture favored homogenization achieved in the outlet collector, already due to the in relation to the longitudinal axis the collector unit symmetrical arrangement of the outflow points a particularly homogeneous one from the respective entry collector Feeding the further continuous heating surface with flow medium he follows.

The steam generator is expediently used as a waste heat steam generator a gas and steam turbine plant used. there the steam generator is advantageously one on the hot gas side Downstream gas turbine. This circuit can be used expediently Additional firing to increase the gas turbine the heating gas temperature may be arranged.

The advantages achieved with the invention are in particular in that by aligning the exit collector parallel to the heating gas direction, the property already provided the evaporator continuous heating surface, namely one self-stabilizing circulation characteristic, consistent for a simplification of the distribution can be used. Just because of the self-stabilizing circulation characteristics namely now seen in succession in the heating gas direction arranged steam generator tubes on the output side with approximately same steam conditions in a common outlet collector lead. This is where the steam generator tubes flow out Flow medium mixed and for forwarding in a subsequent heating surface system without impairment the homogenization achieved in the mixture. In particular through the integration of exit and Inlet collectors can use a separate one, the evaporator once-through heating surface downstream and comparatively complex Distribution system is eliminated. Furthermore, the Steam generator designed in this way on the flow medium side comparatively low total pressure drop.

Figur 1

in vereinfachter Darstellung im Längsschnitt die Verdampfersektion eines Dampferzeugers in liegender Bauweise,

Figur 2

den Dampferzeuger nach Figur 1 ausschnittsweise in Aufsicht,

Figur 3

den Dampferzeuger nach Figur 1 im Ausschnitt entlang der in Figur 2 dargestellten Schnittlinie,

Figur 4

den Dampferzeuger nach Figur 1 im Ausschnitt entlang der in Figur 2 darstellten Schnittlinie, und

Figur 5

ein Enthalpie- bzw. Strömungsgeschwindigkeits-Massenstromdiagramm.

An embodiment of the invention is explained in more detail with reference to a drawing. In it show:

Figure 1

in a simplified representation in longitudinal section the evaporator section of a steam generator in a horizontal construction,

Figure 2

1 of the steam generator according to FIG. 1 in supervision,

Figure 3

1 in detail along the section line shown in FIG. 2,

Figure 4

the steam generator according to Figure 1 in a section along the section line shown in Figure 2, and

Figure 5

an enthalpy or flow velocity mass flow diagram.

The same parts have the same reference symbols in all the figures Mistake.

The steam generator shown in FIG. 1 with its evaporator section 1 is one in the manner of a heat recovery steam generator Gas turbine, not shown, connected downstream on the exhaust gas side. The steam generator 1 has a surrounding wall 2 which one in an approximately horizontal one, indicated by the arrows 4 Hot gas direction x hot gas duct through which flow 6 forms for the exhaust gas from the gas turbine. In the heating gas duct 6 is a number - in the exemplary embodiment two - from after Flow principle designed evaporator heating surfaces 8, 10 arranged, the for the flow of a flow medium W, D are connected in series.

That formed from the evaporator continuous heating surfaces 8, 10 multi-stage evaporator system is with undevaporated flow medium W acted upon by a single pass the evaporator flow heating surfaces 8, 10 evaporate and after the exit from the evaporator once-through heating surface 10 as Steam D removed and usually for further overheating Superheater heating surfaces is supplied. That from the evaporator continuous heating surfaces 8, 10 formed evaporator system is in the water-steam cycle, not shown Steam turbine switched. In addition to this evaporator system are in the water-steam cycle of the steam turbine Number of further heating surfaces, not shown in FIG. 1 which are, for example, superheaters, Medium pressure evaporator, low pressure evaporator and / or can be preheaters.

The evaporator flow heating surface 8 is by a number of connected in parallel to the flow through the flow medium W. Steam generator tubes 12 formed. The steam generator pipes 12 are essentially with their longitudinal axis aligned vertically and for a flow of the flow medium W from a lower entry area to one upper outlet area, i.e. from bottom to top.

The evaporator flow heating surface 8 comprises in the manner of a tube bundle seen a number of x in the heating gas direction successively arranged pipe layers 14, each of which from a number of viewed side by side in the heating gas direction x arranged steam generator tubes 12 is formed, and of those in FIG. 1 each have only one steam generator tube 12 is visible. The steam generator tubes 12 of each tube layer 14 is a common one with its longitudinal direction essentially aligned perpendicular to the heating gas direction x and inlet header arranged below the heating gas channel 6 16 upstream. The entry collectors 16 are there to a water supply system which is only indicated schematically in FIG. 1 18 connected, which is a distribution system for distribution of the inflow of flow medium W as required can include the entry collector 16. Output side and thus open out in an area above the heating gas duct 6 the steam generator tubes forming the evaporator continuous heating surface 8 12 into a number of associated exit collectors 20th

The evaporator continuous heating surface 8 is designed such that they are used for feeding the steam generator tubes 12 comparatively low mass flow density is suitable, wherein the design flow conditions in the steam generator tubes 12 have a natural circulation characteristic. This natural circulation characteristic shows a comparison to a further steam generator tube 12 of the same evaporator continuous heating surface 8 more heated steam generator tube 12 one compared to the other steam generator tube 12 higher Throughput of the flow medium W on.

According to the same principle, i.e. for setting a natural circulation characteristic, is also that of the continuous heating surface 8 Additional evaporator continuous heating surface downstream of the flow medium 10 designed. Also the further evaporator continuous heating surface 10 of the steam generator 1 comprises a plurality of to in the manner of a tube bundle Flow through the flow medium W connected in parallel Steam generator tubes 22. There is a plurality of each Steam generator tubes 22 to form a so-called tube layer arranged next to each other in the direction of the heating gas x, so that in each case only one of the so arranged side by side Steam generator tubes 22 of a tube layer is visible. The so arranged side by side steam generator tubes 22 An assigned distributor on the flow medium side or entry collector 24 upstream and a common exit collector 26 downstream.

To the design for the further evaporator continuous heating surface 10 envisaged natural circulation characteristics with special simple constructive means on particularly reliable To ensure way, includes the additional evaporator once-through heating surface 10 two flow medium side in Series connected segments. In the first segment, each includes the steam generator tube forming the further evaporator continuous heating surface 10 22 an approximately vertically arranged Downflow piece through which the flow medium W flows in the downward direction 32. In the second segment, each steam generator tube includes 22 a downstream of the downpipe piece 32 on the flow medium side, approximately vertically arranged and from the flow medium W riser pipe through which flow flows in the upward direction 34th

The riser pipe piece 34 is associated with it Downpipe piece 32 connected via an overflow piece 36. in the The overflow pieces 36 are within the embodiment Heating gas channel 6 out.

Each steam generator tube 22 of the further evaporator once-through heating surface 10 has, as can be seen in FIG almost U-shaped shape, with the legs of the U through the Downpipe piece 32 and the riser piece 34 and the connecting elbow are formed by the overflow piece 36. At a Such a steam generator tube 22 generates the geodetic pressure contribution of the flow medium W in the area of the downpipe section 32 - in contrast to the area of the riser pipe section 34 - a flow promoting and not one flow-reducing pressure contribution. In other words: the im Downpipe piece 32 located water column on undevaporated Flow medium W "pushes" the flow through each Steam generator tube 22 with, instead of hindering them. As a result, the steam generator tube 22 has one overall comparatively low pressure loss.

With the approximately U-shaped design, each steam generator tube is 22 each in the entry area of his downpipe section 32 and in the outlet area of its riser pipe 34 in the Kind of a suspended construction on the ceiling of the heating gas duct 6 hung or fastened. The lower ends spatially of the respective downpipe piece 32 and the respective riser pipe piece 34, through their overflow piece 36 with each other connected, however, are not directly spatially on Heating gas channel 6 fixed. Elongations of these segments of the Steam generator tubes 22 can thus be tolerated without risk of damage, the respective overflow piece 36 as an expansion curve acts. This arrangement of the steam generator tubes 22 is thus mechanically particularly flexible and with regard to thermal Stresses insensitive to differential expansion.

The steam generator 1 is for reliable, homogeneous flow control with a comparatively simple design designed. This is designed for the evaporator continuous heating surface 8 envisaged natural circulation characteristics consistently used to simplify the distribution system. This natural circulation characteristic and the associated designed to be designed to be comparatively low Mass flow density enables merging of the partial flows from one another seen in the heating gas direction x arranged and thus heated differently Steam generator pipes in a common room. Saving of an independent, complex distribution system thus a shift in the mixing of the evaporator flow heating surface 8 outflowing flow medium W in the outlet collector (s) 20 possible. To get it homogenization achieved from viewed in the heating gas direction x differently positioned and therefore different heated steam generator tubes 12 flowing fluid W when forwarding to the following system is as small as possible to affect everyone is essentially outlet collectors arranged parallel to one another and next to one another 20, of which only one is visible in FIG. 1 is, with its longitudinal axis substantially parallel to the heating gas direction x aligned. The number of exit collectors 20 is the number of steam generator tubes 12 in each Pipe layer 14 adjusted.

Each outlet collector 20 is an entry collector 24 which is the Flow heating surface 8 downstream on the flow medium side assigned another continuous heating surface 10. Because of the u-shaped Design of the further continuous heating surface 10 is the respective entry collector 24 as well the respective outlet header 20 above the heating gas channel 6. The series connection of the fluid medium Continuous heating surface 8 with the further continuous heating surface 10 is possible in a particularly simple manner by everyone Exit collector 20 with the entry collector assigned to it 24 is integrated into a structural unit 40. The structural or constructive unit 40 is an immediate one Overflow of the flow medium W from the evaporator continuous heating surface 8 in the further evaporator continuous heating surface 10 allows without a comparative complex distribution or connection system required would.

With the steam generator 1 in a horizontal construction and using the further evaporator once-through heating surface 10 with Steam generator tubes 22 which are essentially U-shaped can 22 steam bubbles in the downpipe section 32 of a steam generator tube occur. These vapor bubbles could go against the Flow direction of the flow medium W in the respective downpipe section 32 rise and thus the stability of the flow and also hinder the reliable operation of the steam generator 1. To reliably prevent this, the steam generator is 1 for feeding the further evaporator continuous heating surface 10 with already partially evaporated flow medium W designed.

The flow medium W is fed into the further one Evaporator continuous heating surface 10 is provided in such a way that the flow medium W in the downpipe piece 32 of the respective Steam generator tube 22 a flow rate of more has a predetermined minimum speed. This is in turn dimensioned such that on the basis of the sufficient high flow velocity of the flow medium W in each Downpipe piece 32 possibly existing there Steam bubbles reliably in the direction of flow of the flow medium W entrained and over the respective overflow piece 36 transferred into the downstream pipe section 34 become. Compliance with a sufficiently high level for this purpose Flow velocity of the flow medium W in the Downpipe pieces 32 of the steam generator tubes 22 are guaranteed that the supply of the flow medium W in the further evaporator continuous heating surface 10 with one for this sufficiently high steam content and / or with a sufficient for this high enthalpy is provided.

To supply the flow medium W with suitable for this Parameters in the already partially vaporized state enable, is the further evaporator continuous heating surface 10 of the steam generator 1 on the flow medium side in the manner of a Pre-evaporator upstream of the evaporator heating surface 8. The one provided in the manner of a pre-evaporator Evaporator continuous heating surface 8 is comparatively spatial colder area of the heating gas duct 6 and thus on the hot gas side downstream to the further evaporator continuous heating surface 10 arranged. The further evaporator continuous heating surface 10, however, is near the entrance area of the heating gas channel 6 for the flowing out of the gas turbine Heating gas arranged and therefore a comparative in the operating case exposed to strong heat input from the heating gas.

To according to the intended design of the through the continuous heating surface 8 and through which this is connected downstream of the flow medium further continuous heating surface 10 formed evaporator system, namely in the design case the input side Feeding of the further evaporator once-through heating surface 10 with partially pre-evaporated, a sufficiently high vapor content and / or a sufficiently high enthalpy flow medium W, is to ensure the evaporator continuous heating surface 8 suitably dimensioned. Here are particular a suitable choice of materials and a suitable dimensioning the steam generator tubes 12, but also a suitable one Positioning of the steam generator tubes 12 relative to one another considered. It is precisely with regard to these parameters the evaporator flow heating surface 8 is dimensioned in such a way that, in the event of operation, the further downstream Evaporator flow heating surface 10 flowing fluid W is a flow velocity of more than that Take along of the resulting 32 pieces in the downpipe or existing vapor bubbles required minimum speed having.

As it turned out, the design is aimed at high operational security achievable to a particular degree, by the mean heat absorption during operation in Essentially uniform on the evaporator continuous heating surface 8 and on the further evaporator continuous heating surface 10 is distributed. The evaporator continuous heating surfaces 8, 10 and which are these steam generator tubes 12 and 22, respectively therefore dimensioned in the embodiment such that in Operating case the entire heat input into the evaporator continuous heating surface 8 forming steam generator tubes 12 approximately the heat input into the further evaporator continuous heating surface 10 forming steam generator tubes 22 corresponds. Under Consideration of the mass flows occurring for the evaporator flow heating surface 8 one in view to the number of steam generator tubes 22 on the flow medium side downstream further evaporator continuous heating surface 10 suitably chosen number of steam generator tubes 12 on.

As shown in FIG. 2 in a cutout, are the steam generator tubes 12 each two adjacent Pipe layers 14 in a direction perpendicular to the heating gas direction x seen offset from each other, so that regarding the arrangement of the steam generator tubes 12 a substantially diamond-shaped basic pattern results. With this arrangement are the outlet collectors 20, of which in FIG. 2 only one is shown, positioned so that in each Outlet collector 20 from each tube layer 14 Steam generator tube 12 opens. It is also recognizable that each exit header 20 with an associated entrance header 24 for the evaporator continuous heating surface 8 downstream further evaporator continuous heating surface 10 a structural unit 40 is integrated.

FIG. 2 also shows that the further evaporator continuous heating surface 10 forming steam generator tubes 22 also seen a number of x in the heating gas direction Form pipe layers one behind the other, the in the direction of the heating gas x seen first two pipe layers from the riser pipe pieces 34 of the steam generator tubes 22 are formed, the on the output side into the outlet collector 26 for the vaporized Flow medium D open. The seen in the heating gas direction x The next two pipe layers, however, are from the downpipe pieces 32 of the steam generator tubes 22 formed, the input side connected to an associated entry collector 24 are.

Figure 3 shows a side view of sections of the mouth region the steam generator tubes 12, 22 into the respectively assigned structural unit 40, on the one hand, the outlet collector 20 for a number of the evaporator continuous heating surface 8 forming steam generator tubes 12 and on the other hand the inlet header 24 for two each of the further evaporator continuous heating surface 10 forming steam generator tubes 22 includes. It is particularly clear from this illustration that flowing out of the steam generator tubes 12 into the outlet header 20 entering flow medium W on direct Path in the assigned to the further evaporator once-through heating surface 10 Entry collector 24 can overflow. When overflowing of the flow medium W bounces depending on the operating state first against a bottom plate 42 of the entry collector 24 comprehensive structural unit 40. As a result this impact creates a vortex and particularly intimate Mixing of the flow medium W before it from Inlet collector 24 from in the downpipe pieces 32 of the associated Steam generator tubes 22 passes.

As in the illustration according to FIG. 3, it is also particularly special what is clear is the inlet manifold 24 for the steam generator tubes 22 designed end part of the structural Unit 40 designed such that the outflow of the flow medium W into the steam generator tubes 22 for everyone Steam generator tubes 22 vertically from a single plane to the cylinder axis of the structural unit 40 out. In order to make this possible for two steam generator tubes 22 as well, those with regard to their actual spatial positioning two different, seen in the heating gas direction x pipe layers arranged one behind the other are to be assigned each overflow piece 46 is assigned to each steam generator tube 22. Each overflow piece 46 runs obliquely to Heating gas direction x and connects the upper area of each assigned steam generator tube 22 with the respective Outlet opening 48 of the inlet collector 24. Through this arrangement can all outlet openings 48 of the inlet collector 24 in a common plane perpendicular to the cylinder axis the structural unit 40 be positioned so that already due to the symmetrical arrangement of the outlet openings 48 in relation to the flow path of the flow medium D, W an even distribution of the in the steam generator tubes 22 entering flow medium D, W guaranteed is.

To further clarify the pipe guides in the area of their Entries into and out of the building unit 40 in FIG. 4 is a number of such structural units 40 shown in front view, the one designated by IV in FIG Cutting line is used. It can be seen that the two structural elements shown on the left in FIG Units 40, which in the area of their entry collector 24 trained for the downstream steam generator tubes 22 Are shown at the end, each over the overflow pieces 46 the downstream downpipe pieces 32 of the steam generator tubes 22 are connected.

In comparison, the two are shown on the right in FIG structural units 40 each in the area of their as Outlet collector 20 for the steam generator tubes 12 of the evaporator once-through heating surface 8 trained front area shown. It can be seen from the illustration that the from pipe layers 14 lying one behind the other in the structural Unit 40 merging steam generator tubes 12 in a simple angled Form are introduced into the structural unit 40.

The steam generator 1 according to Figure 1 and with the special configurations according to Figures 2 to 4 is special for one safe operation of the further evaporator continuous heating surface 10 designed. For this purpose, when operating the steam generator 1 ensures that the substantially u-shaped Evaporator continuous heating surface 10 with flow medium W with a flow rate of more than a given one Minimum speed is applied. Thereby is achieved that in the downpipe pieces 32 the other Evaporator flow heating surface 10 forming steam generator tubes 22 existing vapor bubbles entrained and in each downstream riser pipe 34 are spent. Around a sufficiently high flow velocity for this in flowing into the further evaporator continuous heating surface 10 To ensure flow medium W, the feed takes place further evaporator continuous heating surface 10 using the this upstream evaporator continuous heating surface 8 in such a way that in the further evaporator continuous heating surface 10 inflowing flow medium W a vapor content or a Enthalpy of more than a specifiable minimum vapor content or has more than a predetermined minimum enthalpy. To comply with suitable operating parameters, the Evaporator flow heating surfaces 8, 10 designed or dimensioned that the steam content in all operating points or the enthalpy of the flow medium D, W when entering the further evaporator flow heating surface 10 above suitable predetermined characteristics, as exemplified in Figures 5a, 5b are shown.

FIGS. 5a, 5b show, in the manner of a family of curves with the operating pressure as a family parameter, the functional dependency of the minimum amount of steam X _{min to be set} or the minimum enthalpy H _{min to be set} as a function of the mass flow density m ˙ selected according to the design . Shown here as curve 70 is the design criterion for an operating pressure of p = 25 bar, whereas curve 72 is provided for an operating pressure of p = 100 bar.

It can be seen from these families of curves, for example, that in partial load operation with a design mass flow density m ˙ of 100 kg / m ² s and an intended operating pressure of p = 100 bar, it should be ensured that the steam content X _min in the flow medium W flowing into the continuous heating surface 8 has a value of at least 25%, preferably about 30%. In an alternative representation of this design criterion, it can also be provided that the enthalpy of the flow medium W flowing to the continuous heating surface 8 should have at least a value of H = 1750 kJ / kg under the mentioned operating conditions. The further continuous heating surface 10, which is designed to comply with these conditions, is dimensioned, i.e., for example, with regard to the type, number and design of the steam generator tubes 30 which form it, taking into account the heat available within the heating gas duct 6, which is designed for its spatial positioning, to these boundary conditions customized. claims

Claims (11)

Steam generator (1), in which an evaporator flow-through heating surface (8) is arranged in a heating gas channel (6) which can be flowed through in an approximately horizontal heating gas direction (x) and which has a number of steam generator pipes (12) connected in parallel to flow through a flow medium (D, W) ), and which is designed in such a way that a steam generator pipe (12) which is more heated in comparison to a further steam generator pipe (12) of the same continuous heating surface (8) has a higher throughput of the flow medium (W) compared to the further steam generator pipe (12),
characterized in that an outlet manifold (20) connected downstream of the steam generator tubes (12) of the evaporator continuous heating surface (8) on the flow medium side is aligned with its longitudinal axis essentially parallel to the heating gas direction (x). Steam generator (1) according to claim 1, wherein the respective Outlet collector (20) essentially designed as a cylinder body is. Steam generator (1) according to claim 1 or 2, the evaporator flow heating surface (8) a number of in the hot gas direction (x) seen pipe layers arranged one behind the other (14) includes, each of a number of in the hot gas direction (x) seen side by side steam generator tubes (12) is formed. Steam generator (1) according to claim 3, the evaporator flow heating surface (8) one of the number of steam generator tubes (12) in each tube layer (14) corresponding number of with its longitudinal axis essentially parallel to the heating gas direction (x) aligned outlet collectors (20) assigned , with a steam generator tube in each outlet header (20) (12) each pipe layer (14) opens out. Steam generator (1) according to one of claims 1 to 4, the Evaporator continuous heating surface (8) on the flow medium side followed by another evaporator once-through heating surface (10) is. Steam generator (1) according to claim 5, the further evaporator flow heating surface (10) a number of to flow through a flow medium (D, W) connected in parallel Steam generator tubes (22) and is designed such that one compared to another steam generator tube (22) of the further evaporator continuous heating surface (10) more heated Steam generator tube (22) one compared to the other Steam generator tube (22) higher throughput of the flow medium (D, W). Steam generator (1) according to claim 5 or 6, wherein the further evaporator flow heating surface (10) forming steam generator tubes (22) each have an approximately vertically arranged of the flow medium (W) in the downward direction Downpipe piece (32) and this one on the flow medium side downstream, approximately vertically arranged and from Flow medium (W) flowable in the upward direction Have riser pipe (34). Steam generator (1) according to one of claims 5 to 7, the Evaporator flow heating surface (8) is dimensioned in such a way that, in the event of operation, the further downstream Flow heating surface (10) inflowing flow medium (D, W) a flow rate greater than that to take with you from there existing vapor bubbles required minimum speed having. Steam generator (1) according to one of claims 5 to 8, that of the or each outlet collector (20) of the evaporator continuous heating surface (8) with an assigned entry collector (24) the downstream of the fluid medium another evaporator flow heating surface (10) in one constructive unit (40) is integrated. Steam generator (1) according to one of claims 5 to 9, the Outlet collector (20) arranged above the heating gas channel (6) is or are. Steam generator (1) according to one of claims 1 to 10, the a gas turbine is connected upstream of the heating gas.

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