EP2516854A2 - Solar thermal power plant and method for operating a solar thermal power plant - Google Patents

Abstract

The invention relates to a solar thermal power plant (1) comprising a solar collector steam generator unit (2) for generating steam, a solar collector steam superheater unit (4), downstream of the solar collector steam generator unit (2), for superheating the steam, and a steam turbine (40) which is connected to an outlet of the solar collector steam superheater unit (4) via a steam conduit system (13), superheated steam being supplied to the steam turbine when in use. The solar thermal power plant (1) comprises an intermediate storage (20) which is connected to the steam conduit system (13) at least in a first high-temperature storage connecting point (HA1) interposed between the solar thermal steam superheater unit (4) and the steam turbine (40) to remove steam superheated in a storage mode from the steam conduit system (13) and which comprises a heat reservoir (22, 23, 24) in which thermal energy is drained from the steam fed into during the storage mode and is accumulated and the stored thermal energy is given off to the steam in an extraction mode, said steam being fed to the steam conduit system (13) from the intermediate storage (20). The intermediate storage is connected to a condenser (65) and/or a relaxation device (89) of the solar thermal power plant (1) in a low-temperature storage connecting point (NA3). The invention also relates to a method for operating said solar thermal power plant (1).

Description

description

Solar thermal power plant and method for operating a solar thermal power plant

The invention relates to a solar thermal power plant with ei ^¬ ner solar panel steam generator unit for generating steam, with a solar panel steam generator unit downstream solar collector steam superheater unit for superheating the steam and a steam line via a system connected to an output of the solar panel steam superheater unit steam turbine, which is fed during operation with the superheated steam. Moreover, the invention relates to a method for operating such a solar thermal power plant.

Solar thermal power plants represent an alternative to conventional power generation ^¬ forth. Currently, solar-thermal power plants with parabolic trough collectors with an indirect evaporative means of an additional oil circuit are ^¬ leads. Solar thermal power plants with direct evaporation are being developed for the future. A solar thermal power ^¬ factory with direct evaporation, for example, from one or more solar panels nenkollektoren each with several parabolic trough and / or Fresnel collectors consist in which the in-pumped feed water is first preheated and vaporized and then the steam is superheated. The superheated steam is directed to a conventional power plant section, where the thermal energy of the water vapor is converted into electrical energy. Advantageously, it is such that first preheating and evaporation of the water in first solar fields with multiple parallel strands of parabolic trough collectors and / or Fresnel collectors takes place (hereinafter also "evaporator solar fields" called.) The generated steam or water produced - vapor mixture is then fed into a first of Dampfabschei- to deposit the remaining, not yet evaporated What ^¬ ser the steam is then further into the. Solar panel steam superheater units piped. The solar collector steam superheater units can be individual solar collectors, a plurality of parallel solar collector strands or solar fields that in turn consist of a plurality of solar collector strands.

In the power plant part of coming from the solar collector steam superheater units superheated steam turbine is supplied ^¬ leads, which drives a generator. Upon subsequent cooling in a condenser, the steam reverts to water, which is collected in a feedwater tank and fed to the solar panels via the feed water pump. For more efficient use of energy, the power plant part can not only have a turbine, but several with respect to the steam transport direction in series turbines, such as a high-pressure turbine, in the first steam is passed, and a medium-pressure and / or low-pressure turbine, in which of the high-pressure turbine coming steam is used again.

The operation of a turbine are usually set narrow temperature limits ^¬ to achieve the longest possible lifetime at the highest possible efficiency. If the steam temperature drops too much, the efficiency is reduced. Too high a temperature, on the other hand, can damage the turbine and shorten its service life. A typical temperature range is between 390 and 500 ° C, whereby the vapor pressure between 41 and 140 bar can lie. However, these parameters may vary from plant to plant depending on the design of the components. Nevertheless, the problem always remains that the temperature of the delivered to the turbine

Maintaining steam as stable as possible and should not be subject to large fluctuations. Therefore, it is necessary to realize a suitable main steam temperature control, WEL che is able, even in transient operation, ie when the output of the plant varies to keep the steam ^¬ temperature at a constant target value. A steam temperature control can be controlled with steam cooling devices z. B. in the area of the solar collector steam superheater units that cool the initially over the actual desired temperature superheated steam to the required temperature. Typically, this injection coolers are used, which inject precisely defined amounts of water into the steam and cool it. Other steam cooling systems mix colder steam. Depending on the heat input or load case, the amount of Kühlmedi ^¬ ums be reduced or increased to maintain the desired Tem ^¬ temperature.

Under extreme circumstances, however, as they can quite possibly occur in the transient operation of solar thermal power plants, a constant live steam temperature can not always be guaranteed by the injection system used, since the steam cooling devices leave their control range in extreme cases. For example, in a large-scale cloud passage over the solar field due to the abruptly reducing heat input, the live steam temperature can not be maintained even by completely closing the injection cooler. Such a situation can be intercepted by the feedwater control difficult or impossible, since this has a much slower time response compared to injection coolers or other steam cooling devices.

Some preliminary plans go there to equip solar power plants ^¬ with appropriate thermal long-term storage. These accumulators should be charged by removing live steam from the main circuit of the solar field. Thus, less vapor is available to flow through the turbine. Conversely, if necessary, the existing thermal energy in the memory can be used to provide ei ^¬ ne additional amount of steam available and so ei ^¬ nen temporary power loss, for example by ei ^¬ nen short-term partial or complete failure of the solar fields due to shadowing, compensate. A significant issue in the realization of such caching concepts is how the energy stored in the Spei rather effectively and for a long time and can be retrieved when needed with the least possible losses again from the memory.

It is therefore an object of the present invention to improve such a larthermisches power plant and a method for operating ei ^¬ nes solar thermal power plant of the type mentioned by means of a Zwischenspeicherkonzepts so that a particularly effective energy storage and un re-sampling of the stored energy allowed.

This object is achieved on the one hand by a solar thermal power plant according to claim 1 and on the other hand by a method according to claim 12.

A solar thermal power plant, as described above, has thereto according to the invention to an intermediate memory which th at at least one steam superheating unit and the steam turbine is arranged between the solar panel ers high-temperature storage connection point is connected to the Dampflei ^¬ processing system, is superheated in a memory operation mode steam from the Remove steam line system. This buffer comprises a heat accumulator in which thermal energy is extracted and stored in the steam introduced in the storage operating mode. In a Entnahmebe ^¬ operation mode the stored thermal energy is released back into the steam which is supplied from the buffer memory to the steam circuit. At a Niedertempera ^¬ ture storage connection point of the buffer is inventions ^¬ tion according to a capacitor and / or a relaxation device of the solar thermal power plant connected. The connections to the high-temperature storage connection point and the low-temperature storage connection point can usefully take place via a storage connection valve device with one or more valves. In the inventive method for operating the solar thermal power plant, a part of the superheated steam in the Zwischenspei- is accordingly rather directed to the heat accumulator in a SpeI ^¬ cherbetriebsmodus at a high-temperature storage ^¬ connection point. In this steam is extracted from the thermal energy and stored. At a low temperature ^¬ memory junction, the cooled steam or water formed thereby / steam mixture is fed to a capacitor and / or an expansion device. Preferably other - - in the extraction mode of operation the latch at one is low-temperature storage connection ^¬ point of water and / or steam supplied and the stored thermal energy is released into the water or the steam and the superheated steam thus generated is supplied directly or indirectly to the steam turbine.

In this construction and operation, in the storage operating mode, ie at the high-temperature storage connection point, constantly new superheated steam can be passed into the intermediate storage. Since the heat storage is normally not able to take up thermal energy at a constant rate over the entire duration of the storage operation mode, the low temperature side end of the heat storage may experience the heat storage at the low temperature end depending on the duration of the storage operation mode Change temperature and pressure conditions and according to the current conditions there is water, steam or a water / steam mixture. According to the invention, the buffer is therefore connected to a low-temperature storage connection point (preferably directly but possibly also indirectly, ie via further components) to a condenser and / or a relaxation device of the solar thermal power plant. The expansion device may be, for example, a flash tank or the like, in which the pressurized steam or the water / steam mixture z. B. is relaxed atmospherically. In this case, according to the invention, a feed water tank with a suitable design as a relaxation device for the derivative serve the medium at the low temperature end of the cache. In particular, it is also possible for an expansion tank to be connected in series between the low-temperature-side outlet of the intermediate store and the condenser. This is particularly useful if it is specified by the herstel ^¬ ler of the condenser system is that only liquid medium should enter the condenser from such a bypass. The supply line in a condenser or to a relaxation device has the advantage that regardless of the temperature and pressure conditions and the state of matter of the medium (water and / or steam) at the output of the buffer the medium carried away and the water / steam cycle of solar thermal Power plant can be fed again. This allows a very high thermal charge of the heat accumulator. Ie. the buffer can be brought to a higher temperature level in total, as in a construction in which, for example, only a storage operation is possible, as long as the capacity of the heat accumulator is sufficient to completely convert the steam into the liquid phase and supply the condensate to the feed water. Conversely, then in Entnahmebetriebsmo ^¬ dus a larger amount of energy or heat energy at ver ^¬ comparatively higher temperature level from the Zwischenspei ^¬ cher are removed again and so the fresh steam temperature are better supported even in full load operation of the solar field.

In the extraction operation mode feed water can in particular be extracted from the Speisewas ^¬ water pipe, which is then first vaporized in a thermally highly charged heat storage by releasing the stored thermal energy and then overheated, so that the superheated steam can be fed back at a high-temperature storage connection point the Dampfleitungssys- tem can. For this purpose, the buffer may be preferably connected via a valve at a low-temperature storage connection point with the feedwater line. At a common pressure difference between the feedwater line and the main steam line, the water flows in the removal mode automatically in the buffer and then steam in the main steam line.

The storage operation mode is usefully set when the solar thermal power plant is in a

Excessive operation is located, in which the solar collector array provides more steam power than is needed. The removal ^¬ operating mode is set when the solar-thermal power plant ^¬ is in a lower power mode, ie when the solar collector field less steam power supplies than is actually needed. It is clear that in such a system, the capacity of the solar field, ie the Son ^¬ nenkollektor-steam generator unit (s) and the solar collector ^¬ gate steam superheater unit (s), must be sized larger than it is needed in normal average operation, as sufficient to provide capacity to fill the Zwischenspei ^¬ chers during the memory operation mode. In addition to the short-term increase in capacity or to support the live steam temperature, the buffer can be used even in sunny periods, especially in the evening and at night, to continue to produce steam and produce electricity with the solar thermal power plant even in these times.

The dependent claims and the following description contain particularly advantageous embodiments and further developments of the invention, wherein explicitly it should be noted that the inventive method can also be developed according to the dependent claims for solar thermal power plant and vice versa.

Depending on the current temperature and pressure conditions on the low-temperature side of the accumulator, the cooled and possibly even partially or completely condensed steam can at least temporarily be returned to the water / steam cycle of the solar thermal power at other suitable locations. plants are supplied. For this purpose, the buffer is preferably connected to other low-temperature Speicheranschlussstel ^¬ len with different lines or other components in the line system of the solar thermal power plant.

For this purpose, the buffer may also be connected to various low-temperature storage connection points-via controllable valves-with different steam lines, in which steam is conducted at different temperatures or pressures during operation. The connection to the various steam lines at the various low-temperature storage connection points is advantageously carried out via suitable valves, which are individually controllable. The connection of the buffer with different low-temperature storage connection points on a condenser or a relaxation device and / or on different steam lines is particularly useful for those cases in which the heat accumulator due to design or because he is already so heavily charged, the steam not enough energy can escape, so that the steam condenses completely. If there are connections to different steam lines, in which steam at different temperatures and pressures is fed, then for example the valve can always be opened to the steam line, in which steam is guided with the suitable steam temperature range and in the appropriate pressure range. The steam or the water / steam mixture can then be used without energy losses at the appropriate places in the circuit. It is preferably arranged to ^¬ least a part of the low-temperature storage connection points in output steam lines of a steam turbine and / or at least a part of the low-memory connection points connected to heat exchangers. Thus, the medium coming from the intermediate storage can still be used for regenerative feedwater pre-heating. If the pressure and / or temperature conditions at the low-temperature end of the accumulator are not suitable for any of the connected steam pipes or other components, then the steam or the water / steam mixture according to the invention is supplied to the flash tank or the condenser.

If the heat accumulator is constructed in such a way that the steam is liquefied in the storage operating mode in principle - at least if the accumulator is not so highly charged - then the accumulator at the low-temperature accumulator connection point is preferably also connected to a ^feed water line via which the accumulator is connected in the buffer memory resulting water is fed as feed water to the solar collector steam generator unit. Particularly preferably, the buffer is connected to the low-temperature storage connection point via a pump with the feedwater ^¬ line. Again, the connection preferably takes place via controllable valves. Preferably, the pump is controlled by a control device suitable for the valves.

In a particularly preferred embodiment of the solar thermal power plant, a steam cooling device (hereinafter also referred to as "end steam cooling device") is arranged in the steam line system between the abovementioned high-temperature storage connection point at which the steam is conducted into the intermediate store and the steam turbine. in addition, preferably, the solar thermal power plant, a control ^¬ device on which is formed so as to drove the be ^¬, the temperature of the superheated steam controlled to a Turbi ^¬ NEN-steam temperature by the steam first in the solar collector steam superheating unit to above the Superheater final temperature is superheated and is then cooled by means of the final steam cooling device to the turbine steam temperature in a corresponding preferred operating method so the temperature of the superheated steam beispielswe ise under measurement of a current actual temperature to a given turbine live steam temperature (as target temperature) regulated by the steam is first superheated to a lying above the Tur ^¬ binen fresh steam temperature steam superheater end temperature and then cooled only in a arranged behind the solar collector steam superheater steam cooling device controlled to the turbine live steam temperature.

When the high-temperature storage connection point at which the steam is passed to the buffer is in flow direction in front of the steam-cooling device, in which the temperature of the live steam is regulated down to Shaped ^¬ joined hundreds of the turbine value obtained used to charge the storage steam to the main steam circuit at the site ^¬ le taken with the highest steam temperature. Thus, in the extraction mode from the buffer, it is also possible to recirculate steam which has a higher temperature than the required live steam temperature, so that the accumulator can be used not only to provide additional steam, but also to a temperature drop counteract the coming of the solar collector steam superheater steam, ie pensieren this drop in temperature by introducing a hotter steam to kom ^¬ . Due to the additional admixture of higher temperature steam in the manner according to the invention, the live steam temperature can thus be kept constant within certain limits even when the end steam cooling device is completely deactivated, even if the steam supplied by the solar collector steam superheater unit is below the live steam temperature lies. This means that even with a partial performance of the solar collector steam generator unit and / or the solar collector steam superheater unit, the fresh steam temperature for the door ^¬ bine easier in predetermined limits can be maintained. This increases the availability and operational flexibility of the entire solar thermal power plant.

In the simplest and most preferred variant of this arrangement with the final steam cooling device takes place while the Supplying the steam from the intermediate storage in the steam line system during the removal operating mode preferably at the first high-temperature storage connection point itself, ie at the same connection point at which the steam is also supplied to the memory in the storage mode of operation. This can be used in any case within the steam line system angeord ^¬ designated end steam cooling device to cool and the next from the buffer superheated steam during the removal operation mode temperature to the appropriate Frischdampftempe-.

Another advantage of the arrangement is that when a short-term requirement of power reserves (so-called "seconds reserve") stored in the long-term storage thermal see energy can be used to additional steam production, even if no temperature drop of coming from the solar panel steam superheater steam before ^¬ is, but merely to increase power, the amount of steam to be increased. the vapor additionally produced can then be mixed into the steam circuit before the final steam cooling means the Hauptdampfström and be brought into the cooling device to the main steam temperature. Due to the advantageous coupling of the latch to the Steam line system before the final steam cooling device can thus be ensured in a simple manner, a constant live steam ^¬ temperature during the provision of seconds reserve.

Due to the fact that the final temperature level of the outlet steam from the intermediate store is above the required live steam temperature, the live steam temperature can also be maintained longer in an operating mode by the steam cooling device, in which, in times of low sunshine, e.g. As in the evening, continues to produce steam and electricity is produced. A lowering of the temperature of the live steam via the steam cooling device and accepted by the turbine would also be possible with this arrangement, for B. if the cache is to be emptied in night mode. In another variant of this arrangement, the superheated steam is the steam circuit from the buffer at a second high-temperature storage junction leads conces- which is disposed in the steam circuit between the "end steam cooling means" and the turbine. In the ^¬ sem case should be in the supply line from the buffer to the second high-temperature storage connection location of the Dampflei ^¬ processing system also preferably be arranged to cool so separately coming from the buffer superheated steam, the yes should have a temperature above the steam temperature at the main steam temperature, a steam cooling device. It is true that with such further Supply line to the second high-temperature storage connection point and a second steam cooling device additional

Costs, but here the temperature of the steam from the buffer can be controlled separately and independently of the main steam flowing through the end steam cooling device, so that this variant may be useful depending on the constructive further specifications of the system.

In the memory mode of operation of the latch is preferential ^¬ example by opening a valve with the steam circuit between the solar collector steam superheater unit and the steam turbine, wherein, in a preferred variant, the opening of the valve in response to a pre give ^¬ NEN mass flow setpoint in the steam circuit before the steam turbine is regulated. In another preferred Va ^¬ riante the opening of the valve is regulated to a constant pressure upstream of the steam turbine.

In the removal operation mode, the buffer is also connected by opening a valve with the steam line between the solar collector steam superheater unit and the steam turbine, but preferably here the opening of the valve is controlled to a constant temperature in the steam ^¬ line system at the high-temperature storage connection point. If the supply of steam from the Intermediate storage at the first high-temperature storage connection point, ie before the end steam cooling device, at which the steam is also led from the steam line system into the memory, it can be ensured in this way ^¬ the that before the last steam cooling device, the temperature already on a kept as constant as possible, so that in the context of temperature control using the final steam cooling device no large control fluctuations occur.

The heat accumulator can be constructed in different ways.

The heat accumulator can be constructed, for example, such that the thermal energy is stored or released again by a phase transition of a storage medium, ie it can be a so-called PCM storage (PCM = phase change material). The heat-storing medium of a PCM memory can, for. B. from salts or already molten salts. A phase change of the salts between a solid and a liquid state or the molten salts between a liquid and a gaseous state is used here to store thermi ^¬ specific energy. Conversely is released during a phase ^¬ transition from gaseous to liquid or liquid to solid thermal energy. The heat transfer between the steam and the storage medium, for example, within a heat exchanger, preferably in a tube register, take place.

Alternatively or additionally, the buffer may also include at least one heat storage in which the thermal energy is stored or released again from a storage medium without phase transition. For example, high-temperature concrete can be used as the storage medium here. In these types of storage, the heat transfer in a heat exchanger, preferably within a tube register, are performed. There are already high-temperature Concrete materials working in the range of up to 400 ° C. Other materials working in the range up to 500 ° C are under development. In a particularly preferred embodiment, the buffer memory comprises a plurality of storage stages for receiving and emitting thermal energy. Here, particular ^¬ DERS preferably composed of at least two of the memory stages functionally different. Ie. For example, one memory level is constructed as PCM memory and another is

Storage stage with a heat storage in which the thermal energy is stored without phase transition.

In one variant of a buffer with several storage stages, the steam is stored in one of the storage stages

Memory ^operating mode liquefied and in Entnahmebetriebsmo ^¬ dus depending on the system operating state, for example, at reduced load with lower pressure, in this storage stage, the water is also evaporated again. In particular, in such a structure, the storage stages are preferably constructed functionally parallel to the solar collector-steam generator unit with the downstream solar panel steam superheater unit. That is, for example, the buffer is parallel to the So ^¬ larfeldern in a kind of by-pass between the feed water supply line and the steam line system upstream of the turbine located and is graded in a manner similar to a ^¬ individual steps in the solar fields. In this case, a storage stage is arranged parallel to the solar collector-steam generator units, in which steam condenses in the storage operating mode and water is evaporated in Ausnahmebetriebsmodus and paral ^¬ lel to the solar collector steam superheater units then the storage stages are arranged, which cool the superheated steam in Speicherbetriebsmo ^¬ ; In recovery mode, overheat the steam again. It is clear that the condensation of steam in the low-temperature side last memory stage is only possible if the light coming from the pre-turn ^¬ th memory stage steam is sufficient abge ^¬ cools and the last memory level is still able, extract enough energy from the steam. Because of he ^¬ inventive coupling of the latch on the low temperature side to a capacitor or an expansion device, and optionally other connection points but the water can, as explained above, regardless of the temperature and pressure conditions and the physical state

and / or the steam low temperature side the water / steam cycle of the solar thermal power plant to be fed again.

The invention will be explained in more detail below with reference to Ausführungsbei ^¬ games with reference to the accompanying drawings. The single figure shows a schematic block diagram of a solar thermal power plant according to a preferred embodiment of the invention.

The figure shows a simplified solar thermal power plant with direct evaporation. This has a solar collector steam generator unit 2 formed from a plurality of solar collector strands for the evaporation of feed water, which is supplied via a feedwater line. The solar collector-boiler unit 2 is followed by a likewise formed of sev- eral solar panel solar collector strands steam superheating unit 4 to superheat the generated from the Son ^¬ nenkollektor steam generator steam unit 2 to about ^¬. Between the solar collector steam generator unit 2 and the solar collector steam superheater unit 4 there is a steam separator 3, in which residual water still present in the steam is separated off and fed back to the feedwater line 10 via a return line 11 with a pump 9. The steam coming from the solar panel steam superheater unit 4 is supplied to a high pressure turbine 40 via a steam line system 13. A check valve or turbine control valve 18 is located over an output shaft in front of the turbine inlet 41, the turbine 45 is connected to a 40 Ge ^¬ gear 46, which in turn is connected to a generator 62 connected to convert the kinetic energy of the drive shaft into electrical energy.

The steam used in the high-pressure turbine 40 is then routed in stages at different outputs of the high-pressure turbine 40 in output steam lines 42, 43, 44, which lead to heat exchangers 47, with which the feed water for the solar collector-steam generator unit 2 preheated can be. In addition, a part of the steam from the steam output line 44 is fed to 50 to use the steam further to Encrypt ^¬ lung in electric power a turbine input 56 of a low pressure turbine. An output shaft 53 of this low-pressure turbine 50 is also connected to the generator 62 for this purpose. In the steam line to the turbine inlet 56 is on the one hand a separator 52 to separate condensed water, and a heat exchanger 51, in which the steam is heated again (reheated) before it is the low-pressure turbine 50 is fed. Via a valve 54 in front of the turbine inlet 56, the pressure at the inlet of the low-pressure turbine 50 can be regulated. 50 supplying the steam for the low-pressure turbine in the heat exchanger 51 more thermal energy, this is traversed by steam, which is branched off via a diverter valve 48 in a branch ^¬ line 49 seen from the upstream se for the high-pressure turbine 40 superheated steam becomes. The steam coming from the branch line 49 condenses in the Wärmetau ^¬ shear 51 and is fed via a line 55 via the heat exchanger 47 a feedwater tank 63. The low-pressure turbine 50 also has at several turbine stages a plurality of outputs which are connected to output steam lines 57, 58, 59, 60, 61. An output steam line 57 leads into the feedwater tank 63. Another output steam line 61, which is located at the very end of the low pressure turbine 50, ie the line with the lowest vapor pressure, leads to a condenser 65, which via another heat exchanger 67 with a Cooling tower 68 is connected. In this condenser 65, the residual steam condenses to water, which is supplied via a pump 69 to the feedwater tank 63. On the way there, several heat exchangers 70 can pass, which are supplied with residual steam via the outlet steam lines 58, 59, 60 from the low-pressure turbine 50. In these heat exchangers 70, the residual steam also condenses to water, which is mixed at the mixing point 66 with the condensed water in the condenser 65 and this is supplied via the pump 69 in turn through the heat exchanger 70 to the feedwater tank 63. This effectively condenses the water and keeps it at a high temperature (below the steam temperature) without giving away the thermal energy in the residual steam. The feed water tank 63 is also supplied with the condensed in the other heat exchangers 51, 47 water. The feed water is then fed back to the solar panel steam generator unit 2 via a feedwater line 10 by means of a feed water pump 64, so as to close the circuit.

The solar collector-steam generator unit 2 consists here, as already mentioned, of several strands of individual solar panels 5. This may be, for. For example, parabolic trough collectors or Fresnel collectors. Shown here are only four strands, each with three collectors 5. In reality, such a solar thermal power plant will have a variety of other solar collector strands with a significantly higher number of solar panels. Possibly. There are also several collector strands grouped into spatially separated solar fields and the steam generated therein is mixed behind the solar fields before entering the solar collector steam superheater units. In this case, the individual solar fields for generating steam each own solar panels are assigned to overheat the steam. Ie. There are then several groups of solar collector steam generator units 2, each with a downstream solar collector steam superheater units 4, as for a sol- che group is shown in Figure 1, connected in parallel and are fed via one or more feed water pipes 10 and the superheated steam is mixed in the end of a Mischzo- ne in Dampflei ^¬ processing system 13 before the high pressure turbine 40th

The solar collector steam superheater unit 4 consists of several solar collector strands, each with a plurality of solar panels 6V, 6E. When the solar panels 6V are pre-superheater solar panels 6V (hereinafter referred to as "pre-superheater") and the solar panels 6E to end superheater solar panels 6E (hereinafter referred to as "final superheater" called). Between the superheater 6V and the final superheater 6E there are injection coolers, which are shown schematically here by an injection point 7. At this point 7 water is injected for cooling, so as to regulate the output ^¬ temperature TD at the end of the final superheater 6E, ie the steam superheater end temperature TD to a predetermined value.

Serves for this purpose a control device 19, which inter alia receives the measured at a temperature measuring point 34 behind the final superheater 6E steam superheater end temperature TD as the current actual temperature and regulated to a predetermined target temperature by an intermediate injection control signal ZKS to a control valve outputs, which regulates the water to ^¬ drove to the injection coolers at the injection point. 7 The control can in principle be carried out separately for each collector strand, if the injection cooler of the collector strands are each supplied via separately controllable valves. The cooling water can be removed, for example via a Kühlwas ^¬ serleitung 12 behind the pump 9 for returning the condensed water from the water separator 3. The control device 19 may for this purpose one or more control devices (not shown) which entwe ^¬ the discrete electronic components in the form of individual or integrated into a computer in the form of software can be implemented.

This control device 19 may obtain another measurement data from the entire pipe system, such as the current pressure in the solar collector steam generator unit, in the solar collector steam superheater unit or Dampflei ^¬ processing system upstream of the turbine 40. The desired temperature to which the steam superheater final temperature TD should always be higher than the required fresh steam temperature for the steam turbine 40. In order then to bring the steam temperature to the required steam temperature, located in the steam line system 13 between the output of the solar collector steam superheater unit 4 and the input 41 of the steam turbine 40, an end steam cooling device 15, here another injection cooler 15. This is also from the Control unit 19 via a Endabspritzungs control signal EKS ^¬ controls, which can be done for example via a control ei ^¬ nes valve, via which the injection cooler 15 is supplied with cooling water (not shown). In Fol ^¬ constricting the end steam cooling device 15 is also referred to as "Endeinspritzer" without ^¬ limit the invention to be sure that this must necessarily be a steam-cooling device in the form of an injection cooler.

To regulate the temperature, a further actual temperature, in this case, the actual live steam temperature TE, is measured at a temperature measuring point 35 behind the end injector 15 and measured with a setpoint temperature value, i. here with the setpoint value of the required for the turbine 40 live steam temperature, which the control device 19 is given for example by the block control of the turbine gets compared. Accordingly, the Endinspritzer 15 is then driven.

According to the invention is also in the steam line ^¬ system 13 before the final injection 15 a high-temperature Storage connection HAI, to which a buffer 20 is connected via a controllable valve 25.

This buffer 20 consists of several storage stages Sl, S2, S3 with different heat accumulators 22, 23, 24, which are connected in a chain in series.

The individual heat storage 22, 23, 24 may be constructed differently and also work differently. In the present case it is for all heat accumulators 22, 23, 24 to such a memory, the escape the guided medium by thermal energy for storage or thermal energy again abge ^¬ ben to the conducted medium, if necessary. This may for example, be heat storage, which operate without a phase change of energiespei ^¬ chernden medium, eg. As solid state memory such as high-temperature concrete storage, or to PCM memory with storage media that perform a phase change in the energy storage. An example of this is a storage facility with molten salt as storage medium, which undergoes a phase change to a gaseous state for energy storage. In the embodiment shown in the figure, for example, the heat storage 22, 23 of the first two storage stages Sl, S2 are constructed as non-phase-change memory and the heat storage 24 in the storage stage S3 as a PCM memory. In principle, however, other arrangements are mög ^¬ Lich.

At the remote from the high-temperature connection point HAI side of the latch 20, at the last memory stage S3, the latch 20 is connected to two low-temperature connection points NAl, NA2 with the feedwater line 10. The connection to the first low-temperature storage connection point NAl via a first valve 31, a pump 26 and a second valve 27. A parallel connection to a second low-temperature storage connection NA2 takes place only via a third valve 28, ie without an intermediate ^¬ circuit of a pump. In addition, the buffer 20 on the low-temperature side is connected at a branch point 30 via a fourth valve 32 to a line 80 which leads to a low-pressure storage connection NA3 on the capacitor 65 of the power plant. In front of the condenser 65, a ^flash tank 81 is connected here, in which the medium coming from the line 80 from the buffer is atmospherically expanded. In systems where it does not matter with which pressure and temperature values, the medium is supplied to the capacitor 65, can also be dispensed with this expansion tank 81. Via a further valve 88, the line 80 can be shut off to the expansion tank 81 or to the condenser 65.

At various low-pressure storage connection points NA4, NA5, NA6, NA7, NA8, NA9, the line 80 is connected via separate controllable ^¬ valves 82, 83, 84, 85, 86, 87 to different steam lines within the power plant block. As an example, it is shown here that part of the

Low-temperature storage ports NA4, NA5, NA6 each in the various output steam lines 42, 43, 44 of the high-pressure turbine 40 and another part of the low-temperature storage ports NA7, NA8, NA9 the various output steam lines 58, 59, 60 of the low-pressure turbine 50, which lead to the heat exchangers 47, 70 for the feed water 10.

All valves 27, 28, 31, 32, 82, 83, 84, 85, 86, 87, 88 of the low-temperature side of the buffer 20 are controlled as well as the valve 25 on the high-temperature side of the intermediate ^¬ memory 20 by a memory controller 21. This also receives as a further input signal, a temperature SNT of the steam, which is measured at a temperature measuring point 36 on the low temperature side of the intermediate storage ^¬ chers 20. This memory control device 21 in turn is in contact with the control device 19 via a communication connection 17, so that these two control signals Facilities 19, 21 work in a coordinated manner. Alternatively, the memory controller 21 may also be formed as a subcomponent of the control device 19. The operation of the latch 20 during a loading ^¬ drive of the solar thermal power plant 1 shown in the figure, for example, as follows:

In a storage mode of operation is to use superheated steam, rather WEL is not needed for the steam turbine can be supplied from the steam ^¬ pipe system 13 to the latch 20 to store therein as much heat energy. For this purpose, the first valve 27 is opened at the low-temperature storage connection point NA1 and the pump 26 is put into operation. At the same time the valve is opened regulated at the high-temperature storage junction HAI 25, wherein a re ^¬ gelung the open position of the valve 25 is preferably carried out mass senstromgeregelt. A required mass flow measuring device is provided accordingly (not shown in the figure). In addition, however, a pressure-controlled ^¬ tes opening of the valve 25 is conceivable, so that the pressure within the steam line system 13 remains as constant as possible. For this purpose, the pressure p is measured at a pressure measuring point 33 and supplied to the storage control device 21, so that the valve 25 can be regulated accordingly. Optionally, this is coordinated with an already effective Druckre ^¬ gelung on the steam turbine valve.

It then flows superheated steam through the valve 25, first in the first storage stage Sl, where it gives off heat to the Me ^¬ dium of the heat storage 22. In the process, the steam cools down and finally reaches the second storage stage S2. In the heat storage 23 of this second storage stage S2, the steam continues to emit heat. The cooled vapor then passes into the third storage stage S3. Here, for the time being, ie at the beginning of the storage ^{operating mode} , the steam liquefies into the storage medium of the heat accumulator 24, releasing considerable heat, which, as explained above, for example. wise as a PCM heat accumulator is constructed with a phase-changing medium, which converts from a liquid to a gaseous state in the recording of the thermal ^¬ 's energy. The resulting in the buffer 20 while water is supplied via the pump 26 and the valve 27 of the feed ^¬ water line 10.

As the storage mode of operation progresses, the buffer 20 is already significantly charged with thermal energy and the low temperature side last storage stage S3 is no longer able to remove so much heat from the supplied steam that it completely condenses. It is then a water / steam mixture. On the basis of the temperature SNT at the low-temperature end of the buffer 20, this state can be detected by the Spei ^¬ cher control device 21. The valves 27, 31 to the first low-temperature storage junction ^¬ NA1 are then closed and the pump is stopped 26 and instead be the valve 32 to the line 80 and open the valve 88 before the flash tank 81st In the expansion tank 81, the water / steam mixture is thermally expanded and forwarded to the condenser 65 at the third low-temperature storage connection point NA3. It is pointed out once again that the expansion tank 81 in front of the condenser 65 is optional and that the water / steam mixture can also be fed directly to the condenser 65 if the condenser 65 is designed accordingly. With later during the memory operation mode of the Zwi ^¬ rule memory 20 is finally time thermally charged that the supplied steam not condensed and pending 20 almost pure steam at the never ^¬ dertemperaturseitigen end of the cache. Based on the temperature at SNT niedertem- peraturseitigen end of the intermediate store 20 and given ^¬ if an additional pressure measurement (not shown) may be checked by the memory controller 21 determines whether the temperature and pressure of the steam at the low temperature side of the buffer 20 corresponds approximately to the temperature and the pressure in one of the steam lines 42, 43, 44, 58, 59, 60 of the further low-temperature connection points NA4, NA5, NA6, NA7, NA8, NA9. If so, the valve 88 in front of the flash tank 81 and the condenser 65 is closed again and the corresponding valve 82, 83, 84, 85, 86, 87 opened on the low temperature side. If the pressure and / or temperature conditions are not suitable for any of the lines 42, 43, 44, 58, 59, 60, the valve 88 in front of the expansion vessel 81 or the condenser 65 simply remains open or is opened when it was previously closed ,

In this structure, the latch 20 can be brought to a higher temperature level in total than in a construction in which only a storage operation is possible, as long as the absorption capacity of the last storage stage S3 is sufficient to convert the steam completely in the liquid phase ^¬ . The storage mode of operation can be carried out until the heat accumulator 20 is fully charged, ie can no longer absorb heat energy. For ^compensating for heat losses in the heat accumulators, the storage ^operating mode can then be temporarily switched on again in phases for a short time. Preferably, a maximum steam temperature is defined, with which the temperature SNT at the low-temperature end of the buffer 20 is compared. Once this maximum steam temperature has been reached, further throughflow of the buffer 20 is prevented (for example by the valve 25 being closed) and the buffer 20 is considered fully charged. Essential criteria for determining the maximum steam temperature, for example, process requirements to ^¬ requirements, such. B. safer, optimally efficient and economical operation of the buffer 20 in connection with the regenerative feedwater pre-heater or the condensate system, as well as safety requirements of the material used in the connecting lines and fittings. In a withdrawal mode of operation, this process will be reversed. Such a removal operation mode is the pitch switched at ^¬ when the solar panels with the sun collector steam generator units 2 and solar panel steam superheating unit 4 are not able to achieve a vapor ^¬ superheater finish temperature TD, which is above the required steam temperature to the turbine 40 , In this case, the second valve 28 is opened at the second low-temperature storage connection point NA2 and again the valve 25 is opened controlled at the high-temperature storage connection HAI, but now this is not pressure-controlled, but temperature-controlled in the way that the Temperature is kept at the high-temperature Speicheran- closing point HAI to a constant value above the ei ^¬ cently required live steam temperature. The exact setting of the live steam temperature then takes place as usual on the final injection 15. In this removal operating mode so water from the

Feedwater line 10 removed. Given a customary pressure difference between the feedwater line 10 (eg 50-145 bar) and the steam line system 13 (for example 41-110 bar), no pump is expected to be required for water to flow into the buffer memory 20 in the extraction mode of operation

Steam can be taken. In the third storage stage S3 this water is preheated, with the withdrawal of heat from the PCM heat storage 24 to boiling temperature, evaporated and fed to the second storage stage S2, where also under withdrawal of heat from the heat storage 23 the

Water is first overheated and then the storage stage Sl is supplied. In this, taking out the heat from the heat storage 22, the final superheating of the water vapor, so that a steam superheater end temperature TD is reached, which is sufficiently high.

The workflow of the intermediate memory 20 thus takes place functionally ^¬ in the same order as in the parallel switched solar collector-steam generator unit 2 with the downstream solar panel steam superheater unit 4, as can be seen easily from Figure 1. Of course, the entire solar thermal power plant 1 not only in addition to the illustrated solar collector strands or solar fields have more solar fields, which are connected in parallel and superheated steam supply the Dampflei ^¬ processing system 13 in front of the turbine 40, but also several parallel memory 20, which also separately depending According to Be ^¬ may be operated in the various operating modes.

In the figure, also an optional bypass 14 from the high-temperature side end of the buffer 20 to a high-temperature connection point HA2 behind the Endin ^¬ splitter 15 is located. This bypass 14 is opened over a se ^¬ parates valve 29th Behind this valve 29 is a separate bypass injection cooler 16 for reducing the temperature of the coming out of the buffer 20 steam. The additional bypass injection cooler 16 is also controlled by the control device 19 and the valve 21 by the memory controller 29 The bypass 14 can be used in the extraction operation mode the overheated over ^¬ vapor not before the Endeinspritzung 15 via the valve 25 into the Admit steam line system 13, but instead via the valve 29 and the additional bypass injection cooler 16 already set exactly to the desired Frisch ^¬ steam temperature adjusted steam to the turbine 40.

It is finally pointed out once again that the methods described in detail above and the solar thermal power plants are merely preferred exemplary embodiments which can be modified by the person skilled in the art in ^various ways without ^{departing from} the scope of the invention, as far as it is concerned the claims are given. In particular, even more low-cost Temperature storage connection points to be provided to various other steam lines. These can be fed under suitable conditions (pressure and temperature) already with water-steam mixture. Likewise, even with an injection into one or more steam lines, for example, excess flow medium, which can no longer be taken up by the steam lines or should be discharged into the expansion device and / or the condenser in parallel. Furthermore, a connection of the buffer 20 on the low-temperature side directly to the feed ^¬ water tank 63 is possible. In particular, the intermediate memory 20 can be constructed with any further number of memory stages or, in principle, also consist of only one single memory stage. Furthermore, instead of the aforementioned parabolic trough collectors or Fresnel

Collectors, any other direct or indirect processing ^¬ tends solar panels used. In particular, use in connection with the newer solar tower technology with direct evaporation is possible. Also, the above-mentioned temperature and pressure ranges are merely exemplary and not restrictive. It is critically dependent on the available types and materials of storage, up to which temperatures and pressures the invention can be used.

For the sake of completeness, it is also pointed out that the use of indefinite articles does not exclude "a" or "one", that the characteristics in question can also be present multiple times. Likewise, the terms "unit" does not exclude that this is ^¬ be of several components, which can optionally be also distributed spatially.

Claims

claims

1. Solar thermal power plant (1) with at least the following components:

a solar collector-boiler unit (2) for the generation ^¬ supply of steam,

one of the solar collector steam generator unit (2) nachge ^¬ switched solar collector steam superheater unit (4) for superheating the steam,

 a steam turbine (40) connected to an outlet of the solar panel steam superheater unit (4) via a steam line system (13), which in operation is supplied with the superheated steam,

 a buffer (20),

which on at least one between the solar panel steam superheating unit (4) and the steam turbine (40) been ^¬ associated first high temperature storage connection point (HAI) to the steam circuit (13) is connected to a memory operation mode superheated steam from the steam line system (13) to remove,

 which comprises a heat accumulator (22, 23, 24) in which thermal energy is withdrawn and stored in the steam introduced in the storage operating mode, and in which the stored thermal energy is returned to steam from the temporary store (20) to the steam piping system in a withdrawal mode of operation (13) is supplied,

and which at a low-temperature storage connection ^{¬ point} (NA3) with a capacitor (65) and / or a relaxation device (89) of the solar thermal power plant (1) is connected.

2. Solar thermal power plant according to claim 1,

characterized in that the temporary store (20) at various other low-temperature storage port ^¬ places (NA4, NA5, NA6, NA6, NA8, NA9) with different

Steam pipes (42, 43, 44, 58, 59, 60) is connected, in In operation steam at different temperatures and / or pressures is performed.

3. Solar thermal power plant according to claim 1 or 2, characterized in that the latch (20) at least one further low-temperature storage connection ^¬ place

 (NA2) is connected to a feedwater line (10) via which feed water is conducted to the solar collector steam generator unit (5) in the removal operating mode.

4. Solar thermal power plant according to one of claims 1 to 3,

characterized in that the intermediate store (20) is connected to a further low-temperature storage connection point (NA1) via a pump (26) with the feedwater line (10).

5. Solar thermal power plant according to one of claims 1 to 4,

characterized in that in the steam line system (13) between the high-temperature storage connection point (HAI) and the steam turbine (40) a steam cooling device (15) angeord ^¬ net and optionally between the first high-temperature storage connection point (HAI) and the steam turbine (40) a second high-temperature storage connection point (HA2) is angeord ^¬ net and that the solar thermal power plant (1) has a STEU ^¬ ereinrichtung (19, 21), which is designed so that during operation, the temperature (TE) of the superheated steam on fes controlling a turbine live steam temperature by first superheating the steam in the solar panel steam superheater unit (4) to a steam superheater end temperature (TD) above the turbine live steam temperature and then cooling it down to the turbine live steam temperature by the steam cooling means (15),

and that in a memory operation mode, part of the superheated Damp ^¬ fes at the first high-temperature storage connection point (HAI) is directed into the intermediate memory (20)

and

in a discharge mode of operation superheated steam from the intermediate memory (20) to the steam circuit (13) to the first high-temperature storage connection point (HAI) and / or - so ^¬ remotely available - the second high-temperature storage connection point (HA2) is supplied.

6. Solar thermal power plant according to one of claims 1 to 5,

characterized in that the latch (20) comprises at least one heat accumulator (24), in which the thermal energy ge ^¬ stores by a phase transition of a storage medium or is released again.

7. Solar thermal power plant according to one of claims 1 to 6,

characterized in that the intermediate store (20) comprises at least one heat store (22, 23) in which the thermal energy is stored or released again from a storage medium without a phase transition.

8. Solar thermal power plant according to one of claims 1 to 7,

characterized in that the intermediate store (20) comprises a ^{plurality of} storage stages (S1, S2, S3) for receiving and emitting thermal energy.

9. Solar thermal power plant according to claim 8,

characterized in that at least two of the Speicherstu ^¬ fen (Sl, S2, S3) are constructed differently.

10. Thermal power plant according to claim 8 or 9, characterized in that in one of the memory stages (S3) at least temporarily steam in the memory operation mode is at ^¬ least liquefied partly and at least at times, water is evaporated in the extraction mode of operation.

11. Solar thermal power plant according to one of claims 8 to 10,

characterized in that the storage stages (Sl, S2, S3) are functionally parallel to the solar collector-steam generator unit (2) with the downstream solar collector steam superheater unit (4) are constructed.

A method of operating a solar thermal power plant (1) comprising a solar panel steam generator unit (2) for evaporating water, a solar panel steam superheater unit (4) for superheating the steam, and a steam turbine (40) in operation with the superheated one Steam is fed

in which

in a storage mode to a high-temperature storage connection point (HAI) part of the superheated Damp ^¬ fes in a buffer (20) having a heat store (22, 23, 24) is passed, in the vapor thermal energy is energy extracted and stored, and a low-temperature tempering ^¬ memory connection point (NA3), the cooled steam or water formed thereby / steam mixture to a condenser (65) and / or an expansion device (89) is fed

and wherein, in a picking operation mode, water and / or steam is supplied to the latch (20) at a low-temperature storage junction (NA2) and the stored thermal energy is returned to the water and the steam, respectively, and the superheated steam generated thereby

Steam turbine (40) is supplied.

13. The method according to claim 12,

characterized in that

the temperature (TE) of the superheated steam controlled to a specified ^differently bene turbine main steam temperature by the steam first to a temperature above the turbine steam temperature steam superheater finish temperature (TD) is superheated and then in a behind the solar panel steam superheating unit (4) arranged steam cooling device (15) is cooled to the turbine live steam temperature, and that

in the storage operating mode, a portion of the superheated steam is passed before the steam cooling device (15) in the latch (20) and

superheated steam before and / or downstream of the steam cooling device (15) is removed from the intermediate store (20) in the removal operating mode.

14. The method according to claim 12 or 13,

characterized in that in the storage operating mode of the buffer (20) by opening a valve (25) with a steam line system (13) between the solar collector steam superheater unit (4) and the steam turbine (40) verbun ^¬ is, wherein the opening of the valve (25 ) is controlled in dependence on a predetermined mass flow setpoint in the steam line system (13) in front of the steam turbine (40).

15. The method according to any one of claims 12 to 14,

characterized in that in the removal operation mode, the buffer (20) by opening a valve (25) with a steam line system (13) between the solar collector steam superheater unit (4) and the steam turbine (40) verbun ^¬ is, wherein the opening of the valve (25 ) is controlled to a kon ^¬ constant temperature at a high-temperature storage connection ^{¬ point} (HAI) in the steam line system (13).