WO2011104328A2 - Apparatus and method for generating superheated steam using solar energy on the basis of the natural circulation concept, and use of the superheated steam - Google Patents

Abstract

The invention relates to an apparatus and a method for generating superheated steam using solar energy and a steam generator based on the natural circulation concept. Superheated steam, which is used to drive a steam turbine, for example, is generated in multiple stages within a water pipe, i.e. by preheating, evaporating, and superheating feed water. The thermal energy required for said process is supplied by a heat transfer medium heated using solar energy. In order to be able to more efficiently generate superheated steam, tube bundles are used, inter alia. Furthermore, a plurality of steam generators are connected in parallel for use in larger steam generator units.

Description

description

Apparatus and method for generating superheated steam by means of solar energy based on the natural circulation concept and use of superheated steam

The invention relates to a device for generating superheated steam by means of solar energy and a procedural ren for generating superheated steam using the device. In addition, a use of the superheated steam is indicated.

The use of solar thermal power plants as an alternative to conventional power generation is a way to defuse the existing carbon dioxide problem. In this way lar energy (solar energy), ^¬ ie electromagnetic Strah development of the sun into electrical energy.

Currently, a majority of the solar thermal power plants al solar thermal power plants with indirect evaporation out ^¬ leads. Solar fields with parabolic trough collectors serve as receivers of the solar energy. As an alternative to the parabolic trough collectors, Fresnel collectors are used as receivers of solar energy. Instead of the solar fields, solar towers are also used.

A solar thermal power plant with indirect evaporation has a steam generator. The steam generator includes a heat transfer circuit (primary circuit) with a heat carrier medium and a water / steam circuit (secondary circuit) with water. The heat transfer medium of the heat ^¬ carrier circuit, such as a thermal oil or a salt melt, absorbs the solar energy in the form of heat (thermal energy). The heat transfer medium is he ^¬ warms. The heat absorbed by the heat transfer medium heat is transferred by means of feed water preheater, evaporator and Üb heater to the water of the water / steam cycle. In this case, superheated steam is generated. The stored in superheated steam thermal energy is used to obtain the electrical energy. It comes to the conversion of thermal energy into electrical energy.

The conversion of the thermal energy of the superheated steam into electrical energy takes place in the "conventional" part of a solar thermal power plant, for example with the aid of a steam turbine.

Object of the present invention is to show how efficiently superheated steam can be obtained with the help of solar energy, which can be used for the production of electrical energy.

To solve the problem, a device for generating superheated steam by solar energy is specified, comprising at least one heat transfer circuit with a heat transfer medium for receiving the solar energy in the form of heat and at least one water / steam cycle with water Forming the superheated steam, wherein the heat transfer circuit and the water / steam circuit for generating the superheated steam via at least one steam generator are thermally coupled to each other and through the steam generator a natural circulation concept with feed ^¬ water preheater for preheating of liquid water Water / steam cycle, with evaporator for evaporating the heated by means of the feedwater preheater liquid water of the water / steam cycle and with superheater for overheating of the formed ^¬ using the evaporator Was ^¬ serdampfs the water / steam cycle is realized. In this case, the evaporator at least one natural circulation steam drum for the separation of liquid water from the water vapor formed by the evaporator.

To achieve the object, a method for generating superheated steam using the apparatus is also specified with the following method steps: a) Provide b) converting solar energy into heat of the heat transfer medium and c) transferring the heat of the heat transfer medium to the water of the water / steam cycle, wherein the superheated steam is generated.

According to a further aspect of the invention, a use of the superheated steam generated by the described method to obtain electrical energy is indicated, wherein with the aid of the superheated steam, a steam turbine is driven.

The idea underlying the invention consists in using solar energy for the formation of superheated steam (water vapor at a temperature above the boiling point of water), that is to say the electromagnetic radiation emitted by the sun and directed towards the earth's surface ^¬ che meets. For this purpose, a suitable steam generator system be ^¬ reitgestellt. The steam generator or the steam generator system are based on the concept of natural circulation.

The generation of superheated steam takes place mehrstu ^¬ fig, namely on the feedwater preheating, evaporation (formation of water vapor) and the overheating of the water vapor. Each of the steps is operated solar-thermally.

For the feedwater preheating, evaporation and overheating can each be provided a separate heat transfer circuit. Preferably, however, a single, common heat transfer circuit is present for the feedwater preheating, evaporation and overheating. It is the

Heat transfer circuit advantageously designed such that the heat transfer medium is successively available in the region of the superheater, in the region of the evaporator and in the region of the feedwater preheater for the respective thermal coupling.

The evaporator has a natural circulation steam drum. With the help of the natural circulation steam drum, liquid water from the Water vapor are separated, which is formed by the steam generator. Due to the natural circulation steam drum, a phase separation takes place. First the product obtained after the phase separation "dry" steam is superheated and a nachge ^¬ off steam turbine supplied. The drying of the water vapor may at any time, for example during a startup of the steam generator system, are provided for optimum conditions for the formation of steam Thus. also it possible at any time of operation of the device effi ^¬ cient conversion of solar energy into water vapor made ^¬ union.

Feed water preheating, evaporation and overheating can take place in a single, common pressure vessel. Preferably, however, necessary for the feedwater preheating, evaporation and overheating necessary thermal coupling of each of the stages in a separate pressure vessel. According to a particular embodiment of this case has the feedwater preheater to at least one pre-heating pressure vessel, is a pre-heating water pipe for receiving of liquid water of the water / steam cycle is arranged in the at least ^¬. The preheating water pipe and the heat ^¬ carrier circuit in the preheating pressure vessel for heating befindlichem in the preheating water pipe, liquid water of the water / steam cycle by means of heat of the heat transfer medium are thermally coupled together.

With regard to the evaporation advantageous embodiment in which the evaporator has at least one evaporator pressure vessel in which at least one evaporator heat transfer tube for receiving the heat transfer medium of the heat transfer circuit is arranged, and the evaporator heat transfer tube and the Water / steam cycle in Ver ^¬ steamer-pressure vessel for transferring located in the evaporator pressure vessel, heated by the feedwater preheater liquid water of the water / steam cycle in water vapor by means of heat of the heat transfer medium ther- Mixed with each other. In the evaporator pressure vessel, the formation of water vapor takes place.

With regard to overheating, a configuration is advantageous in which the superheater has at least one superheater pressure vessel in which at least one superheater water pipe for receiving the water vapor generated by the evaporator of the water / steam cycle is arranged, and the superheater water pipe and the heat carrier -Circulation in the superheater pressure vessel for overheating of the located in the superheater water pipe, formed by the evaporator steam are thermally coupled to each other by means of heat of the heat transfer medium. For thermal coupling pipes are used through which either the heat transfer medium of the heat transfer circuit or the water of the water / steam cycle are performed. During the feed water preheating and overheating, the water of the water / steam cycle is guided in the respective tube. In contrast, during the overheating does not flow the water or water vapor of the water / water cycle in the tube, but the heat transfer medium of the heat transfer circuit in the corresponding tube. In principle, evaporator pressure vessel of the evaporator, natural circulation steam drum of the evaporator and superheater pressure vessel of the superheater can be arranged arbitrarily to each other. It is only necessary to ensure that the water vapor formed in the evaporator pressure vessel can get into the natural circulation steam drum and that the water vapor only after the separation of liquid water from the natural circulation steam drum to superheater, ie passed into the superheater water pipe of the superheater becomes. Therefore, according to a particular embodiment, the ^¬ their natural circulation drum and the superheater water pipe are connected together so that the steam can enter the superheater water tube of the superheater, after separation of liquid water. In addition, it is favorable to the separated liquid What ^¬ ser supply the water / steam cycle. Therefore, according to another embodiment of the evaporator pressure vessel of the evaporator and the natural circulation steam drum of the evaporator are interconnected such that the water vapor formed in the evaporator pressure vessel can pass into the natural circulation drum and by the Ab ^¬ separation in nature drum formed liquid water can enter the evaporator pressure vessel. The separated liquid water is returned to the evaporator pressure vessel. For this purpose, special lines can be provided, through which the liquid water passes back into the evaporator pressure vessel. The use of pumps is also conceivable in order to control the return flow of the liquid water into the evaporator pressure vessel.

According to a particular embodiment, the natural circulation drum is arranged above the evaporator pressure vessel. In this case, at least one steam riser is arranged between the natural circulation drum and the evaporator pressure vessel through which the water vapor formed in the evaporator pressure vessel can enter the natural circulation drum. This arrangement utilizes a natural movement of the water vapor formed in the evaporator pressure vessel from "bottom to top." Through the steam riser, the water vapor formed in the evaporator pressure vessel enters the natural circulation steam drum the natural circulation steam drum flow back separated water back into the evaporator pressure vessel. in addition, the vapor riser may in a particular embodiment, the steam riser therefore serves one wearing the natural circulation steam drum through the evaporator pressure vessel, the natural circulation steam drum tra ^¬ gen. This means that no additional carrying or holding device must be present.

The individual stages of the steam generator can be arranged separately from each other ^¬ . According to a particular embodiment tion are therefore the preheating pressure vessel, the evaporator pressure vessel and the superheater pressure vessel connected to each other via at least one external line through which the heat transfer medium of the heat transfer circuit or the water of the water / steam cycle can flow. The pressure tanks of feedwater preheaters, evaporators and / or superheaters are designed as units separated from each other (apparatuses). Via external lines is ensured that the water / steam cycle and / or the Wärmeträ ^¬ ger cycle are closed. What waters of ^¬ ser / steam cycle and heat transfer medium of the heat carrier ^¬-cycle move from one stage to the next. The individual apparatuses can be arranged in any manner to each other, for example vertically or horizon tal ^¬.

A flow of the heat transfer medium in the heat transfer circuit and / or a flow of water in the water / steam cycle from one stage to the next stage can al ^¬ lein by the on the heat transfer medium and / or on the water of the water / Steam cycle acting gravity can be caused. The flow of the heat transfer medium and or the flow of water can also be supported or effected by means of ent ^¬ speaking pumps. The flui ^¬ de be pumped from one stage to the next. It is because ^¬ provided for, that the heat carrier medium is first, then led past in the region of the superheater in the region of the evaporator and closing ^¬ Lich in the region of the feed water preheater for thermal coupling to the respective tubes. Hot heat transfer medium is thus used to overheat the water vapor, "slightly cooled" heat transfer medium for Ver ^¬ steaming and "cold" heat transfer medium for feedwater preheating.

The stages of the steam generator can also be constructed together as one unit (a single apparatus), ie not a separate units. It is ensured that the heat transfer medium of the heat transfer circuit and / or the water of the water / steam cycle passes directly from one stage to the next. It will be used (with the exception of any existing steam risers) no external lines. The steam generator has, for example, a steam generator boiler. Preheating pressure vessels, evaporator pressure vessels and / or superheater pressure vessels are integrated as individual chambers in the steam generator boiler. In this case, all three units in the steam generator boiler side by side, ie horizontally to each other, are integrated. It is also possible that only two of the three units are contained in the steam generator boiler. It follows from the above ^¬ previous considerations: In a particular embodiment the pre-heating pressure vessel and the evaporator pressure vessel are arranged to each other such that the water of the water / steam cycle and / or the heat transfer medium of the heat carrier circuit directly from the preheating Pressure vessel can get into the evaporator pressure vessel. The same applies to the evaporator and superheater in view of the heat transfer medium (The water vapor takes going through the natural circulation steam drum): Preferably, evaporator pressure container and the superheater pressure vessel are arranged to each other such that the heat ^¬ carrier medium of the heat transfer Circuit can get directly from the Üb ^¬ heater pressure vessel in the evaporator pressure vessel.

As mentioned above, tubes are preferably used for thermal coupling through which either the heat transfer medium of the heat transfer circuit or the water of Was ^¬ water / steam cycle are performed. On the outer walls of the tubes are - vice versa - the water of the What ^¬ water / steam cycle or the heat transfer medium of the heat transfer circuit. Indirectly via the pipe or via the pipes, the respective heat exchange takes place. For this purpose, the tube or consist of the tubes of a material having a relatively high thermal conductivity coefficient λ. A suitable material is, for example, copper (λ = 395

J / mKs). According to a particular embodiment, the preheating pressure vessel is designed such that the heat transfer medium of the heat transfer circuit can flow past the preheating water pipe for thermal Kopp ^¬ treatment of the preheating water pipe and the heat transfer circuit. It can be ensured that the heat transfer medium mehrzügig, so several times flows past the preheating water pipe. A corresponding structure is preferred for the superheater pressure vessel: The superheater pressure vessel is designed such that for thermal coupling of the superheater water pipe and the heat transfer circuit with each other, the heat transfer medium of the heat transfer circuit can flow past the superheater water pipe. By passing the heat transfer medium, the thermal coupling takes place. Again, a mehrzügiges Vorbeiströmen the heat transfer medium may be provided.

In principle, the preheating water pipe and the superheater water pipe can be arranged arbitrarily with respect to a flow direction of the heat transfer medium in the respective pressure vessels. It is particularly advantageous, however, when a Längsaudehnung of preheating the water pipe and / or a longitudinal ^¬ extension of the superheater water pipe transversely to a Strö ^¬ direction of flow of the heat carrier medium in the preheating pressure vessel and / or transverse to a flow direction of the heat carrier medium in the Superheater pressure vessel are arranged. In this form an efficient energy transfer takes place. There is a "cross-countercurrent circuit." The "cross-countercurrent circuit" can be realized in the preheater of the preheater and / or in the superheater pressure vessel of the superheater.

According to a particular embodiment, the water pipe used for the heat coupling is meandering. This means that the preheat water pipe and / or the superheater water pipe have at least one meander (arc). The corresponding water pipe is bent. Although the water pipes are advantageously meandering. But other designs are also proving their worth in terms of efficient heat exchange. So it is also advantageous if the preheat water pipe and / or the superheater water pipe are spiral.

According to a particular embodiment, the preheating water pipe and / or the superheater water pipe have at least one coated meander. Coated meander tubes are used. Coated meanders (U-bends) are bends with a bending angle greater than 180 °. so that a height of a Ge ^¬ total number of meanders (meander harp) against a structure with "real" U-tubes is smaller. plated meanders is also utilized optimally, a potential of a possible heat transfer.

The situation is different with respect to the evaporator heat transfer tube. Here, the use of a straight pipe proves its worth. This is especially true for a tube bundle of several evaporator heat transfer tubes. The evaporator heat transfer tubes are welded, for example, on both sides in Rohrplat ^¬ th. The welded-evaporator heat transfer tubes counteract a high pressure of a lateral surface of the evaporator pressure vessel. This makes it possible to use thin tube plates.

In view of efficient heat exchange, it is particularly efficient to provide a plurality in parallel angeord ^¬ neter pipes. There is a tube bundle. In ge ^¬ gebenem pipe volume is a (total) pipe surface over which takes place the thermal coupling of the heat transfer medium and the water, higher in a tube-bundle as compared to a ^¬ a Zigen tube. This concerns the feed water preheating, the evaporation and / or the overheating. According to a particular embodiment, therefore, a multiplicity of preheating water pipes arranged parallel to one another and / or a plurality of evaporator plants arranged parallel to one another are provided. Heat transfer tubes and / or a plurality of mutually parallel superheater water pipes available.

In a bundle of superheater water pipes, for example, the water vapor, starting from the natural circulation steam drum, is distributed via a distributor to a plurality of superheater water pipes of the superheater. In each of the superheater water pipes takes place separately, the overheating of the water vapor. A collector collects the superheated steam recovered in the individual superheater water pipes. The merged, Bulb temperature ^¬ te steam is then fed to a steam turbine further ^¬. As already stated above, it is advantageous to use a meandering or spiral water pipe in each case with regard to the feedwater preheating or the overheating of steam. Particularly advantageous is the Ver ^¬ application of tube bundles of tubes of this tube forms: for the feed water preheating and / or the water vapor

Overheating is a variety of parallel, meandering or spiral water pipes available. To further increase the efficiency with which the heat of the heat transfer medium of the heat transfer circuit can be transferred to the water or the water vapor of the water / steam cycle, it is advantageous, the flow direction (and the flow velocity) of the Heat transfer medium to influence. This concerns both the feedwater preheating and the steam overheating. The heat transfer medium can be channeled on the respective water pipe or passed to the respective water pipes over. Therefore, according to a particular embodiment, between the plurality of preheating water pipes arranged parallel to one another and / or between the plurality of superheater water pipes arranged parallel to one another, deflecting plates for changing a flow direction of the preheating pressure vessel are flowing Heat transfer medium of the heat transfer circuit and / or for changing a flow direction of flowing in the superheater pressure fluid heat transfer medium of the heat carrier circuit available.

According to a particular embodiment, a plurality of steam generators are present. Preferably, the plurality of steam generators are connected in parallel to a larger steam generator unit.

In addition to feedwater preheaters, evaporators and superheaters, the steam generator can also have an intermediate superheater (intermediate overheating stage). With the intermediate superheater ^¬ an efficiency is increased, with a down- stream steam turbine is operated. With the intermediate overheating stage, additional thermal energy is introduced into the water vapor. The introduction of the thermal energy can be done arbitrarily, for example by means of fossil fuels. Preferably, however, the intermediate overheating stage is operated solar-thermally: The

Intermediate superheater has an intermediate superheater water pipe for receiving the water vapor. For intermediate superheating hot, heated by means of solar energy Wärmeträ ^¬ ger medium is passed by the intermediate superheater water pipe. Intermediate superheater water pipe and heat transfer medium are thermally coupled together. By passing the heat transfer medium, the water vapor in the intermediate superheater water pipe is additionally overheated. With reference to several embodiments and the associated figures, the invention will be described in more detail below. The figures are schematic and are not true ^¬ dimensioning true to scale drawings. Figure 1 shows a circuit diagram of a solar parabolic gutter power plant. Figure 2 shows a device with steam generator as a system with separate apparatus.

FIG. 3 shows a steam generator as a unit with horizontally arranged apparatuses.

FIG. 4 shows the operating principle of the steam generator as a unit according to FIG. 3 in a lateral cross section. Given is a device 1 for generating water vapor by means of solar energy. The device has a Wärmeträ ^¬ ger circuit 2 and a water / steam circuit 3. The circuits are thermally coupled to each other via at least one steam generator 4. An exchange of heat can take place via the steam generator, so that the water is transferred from the liquid phase into the gaseous phase as water vapor (FIG. 1).

With the steam generator, a natural circulation concept 44 with feedwater preheater 41, evaporator 42 and superheater 43 is realized. The feedwater preheater has a preheat pressure vessel 411, the evaporator an evaporator pressure vessel 421 and the superheater on a superheater pressure vessel 431. Above the evaporator pressure vessel, a natural circulation steam drum 441 is disposed. Via the vapor risers 451, the evaporator pressure vessel and the natural circulation steam drum are connected. Through the steam risers the water vapor formed in the evaporator pressure vessel enters the natural circulation steam drum. In addition, the steam risers serve as a carrier of natural circulation steam drum.

In the natural circulation steam drum, a separation of liquid water from water vapor takes place. The separated liquid water is returned to the evaporator pressure vessel via the return guide lines 452, where it is again available for steam generation. Via the steam supply line 453, the with the natural circulation Steam drum dried water vapor in the superheater pressure vessel.

Is transferred to the transfer of heat from the solar panel 11 (para- bolrinnen field) to the heat transfer medium 20 of the Wärmeträ ^¬ ger-circuit, the water of the What ^¬ ser / steam circuit and the heat carrier medium are the heat transfer -Kreislaufs in preheating-pressure vessel of the feed ^¬ water preheater for heating located in the preheating water pipe 412 liquid water by means of heat of the heat transfer medium thermally coupled together. A bundle 413 is present at meandering preheat water pipes. The preheating water pipes are in the form of coated meander ^¬ sets. The preheating water pipes are combined to form a rectangular tube bundle.

Via a distributor 35, the water is distributed to the preheating water pipes (see Figure 4). The heated by the thermal ^¬ coupling of heat transfer medium and preheating water pipes water is recombined via a collector 36 at the end of the preheating water pipes and forwarded to the evaporator (see Figure 4).

In the evaporator pressure vessel, the evaporator heat transfer tube 422 and the water of the water / steam cycle are thermally coupled together. In the evaporator pressure vessel, a bundle of evaporator heat transfer tubes is present, which are supplied via a manifold with heat transfer medium. The used heat transfer medium is recombined via a collector and forwarded to the feedwater preheater.

In addition, the water of the water / steam cycle and the heat transfer medium of the heat carrier circuit in the superheater pressure vessel of the superheater for heating located in the superheater water pipe 432 liquid water by means of heat of the heat transfer medium are thermally coupled together. Again, superheater Used water pipes with coated meanders. Like the preheating water pipes, the superheater water pipes are combined into a rectangular tube bundle.

The heat transfer medium is a thermal oil. In an alternatively ^¬ ven embodiment, the heat transfer medium is a salt melt.

Furthermore, in addition to the steam generator, an intermediate overheating stage (intermediate superheater) 13 is provided to increase the efficiency of the downstream steam turbine. The intermediate stage is also operated solar-thermally. The intermediate superheater has an intermediate superheater water pipe for receiving the water vapor. For intermediate superheating hot, heated by means of solar energy Wärmeträ ^¬ ger medium is passed past the intermediate superheater water pipe. Intermediate superheater water pipe and heat transfer medium are thermally coupled together.

Example 1 :

Preheating pressure vessel, evaporator pressure vessel and superheater pressure vessel are designed as separate and horizontally arranged to each other apparatuses and connected with ex ^¬ ternal pipes together (Figure 2). The preheat pressure vessel and the superheater pressure vessel are vertically positioned. The evaporator pressure vessel is there ^¬ against horizontal.

The superheater pressure vessel has a heat transfer inlet 22, through which the heated via the solar panel 11 heat ^¬ medium carrier is fed from above into the superheater pressure vessel. Within the superheater pressure vessel, the heat transfer medium flows from the heat transfer medium inlet with a vertical flow direction from top to bottom. The preheat pressure vessel has a water inlet 33 for liquid water of the water / steam cycle. Cooled heat transfer medium is removed again via the heat carrier outlet of the preheating pressure vessel and is available for the renewed absorption of heat by solar energy.

The individual heat exchangers are connected in countercurrent, so that the superheated steam escapes from the superheater pressure vessel on the side at which the hot heat medium ^¬ carrier medium occurs. The cooled heat-carrier medium exits the preheat pressure vessel on the side where the feedwater enters. In addition, the water pipes in the preheating pressure vessel and the superheater pressure vessel are arranged transversely to the flow direction of the heat transfer medium. In order to ensure the most efficient transfer of heat, in the preheating pressure vessel and in the superheater pressure vessel between the water pipes Umleitbleche for changing the flow direction of the heat transfer medium are also present. This ensures that an ef ^¬ efficient heat exchange between the heat transfer medium and in the

 Water pipes existing water can take place.

Example 2:

Again, a natural circulation steam drum used. In this embodiment, the apparatuses (feedwater preheater, evaporator and superheater) are gekop ^¬ pelt to a steam generator unit and placed in a container (Figures 3 and 4). The coupling of this type can be dispensed with external lines between the apparatus, except drop and risers of the steam drum. The risers are also used in this concept as a support structure for the steam drum. The apparatuses inside the container are connected in counter ^¬ current. In order to ensure the natural circulation between the evaporator and steam drum, the entire steam generator unit is arranged horizontally. To comply with the specified pipe pitch metallic bracket holder are used. In this embodiment, a distributor for distributing water of the water / steam circuit and a collector for collecting the water or the superheated steam of the water / steam circuit are present in each of these apparatuses. An outer pressure shell of distributor and collector is cylindrical in each case. The centrally located between feed water preheater and superheater evaporator is constructed as a simple tube bundle with straight evaporator heat transfer tubes. The welded on both sides in tube plates evaporator heat transfer tubes counteract a high pressure in the mantle space of the evaporator pressure vessel. This allows a use of thin tube plates. Hot heat transfer medium flows through the evaporator heat transfer tubes. In this case, the heat transfer medium in the example shown is passed three times through the boiling point in the evaporator pressure vessel water. This simple principle, in addition to the efficient heat exchange, the production costs are kept low. Likewise, this and the cleaning of the evaporator is straightforward.

For the diameter of the evaporator pressure vessel the required diameter of the tube bundle of the evaporator heat transfer tubes is decisive. This can be brought by varying pipe parameters to different dimensions. The diameter of preheating pressure vessel and superheater pressure vessel can be adjusted by a corresponding Bundelgestal ^¬ tion without problems. For the execution of maintenance or repair work between the apparatus (not shown) accesses to the tube bundles provided.

The device described is used to generate superheated steam by means of solar energy. The following process steps are carried out: a) Provide b) converting solar energy into heat of the heat transfer medium; and c) transferring the heat of the heat transfer medium to the water, whereby the superheated water vapor is generated.

The generated, superheated steam is forwarded to a steam turbine for the production of electricity.

Claims

claims 1. Device (1) for generating superheated steam by means of solar energy, - At least one heat transfer circuit (2) with a heat carrier medium ^¬ (20) for receiving the solar energy in the form of heat and - At least one water / steam circuit (3) with What ^¬ ser to form the superheated steam, wherein  - The heat transfer circuit and the water / steam circuit for generating the superheated steam via at least one steam generator (4) are thermally coupled together and - By the steam generator (4) a natural circulation concept (44) with feedwater preheater (41) for preheating liquid water of the water / steam cycle, with evaporator (42) for the evaporation of it with the help of the feedwater preheater he heated ^¬ liquid water of the water / steam cycle and with superheater (43) for overheating of the water vapor formed by the evaporator of the water / steam circuit is realized, wherein the evaporator at least one natural circulation steam drum (441) for the separation of flüs ^¬ sigem water comprising the water vapor formed by the evaporator. 2. Device according to claim 1, wherein  - The feedwater preheater at least one preheating pressure vessel (411), in which at least one preheating water pipe (412) for receiving liquid water of the water / steam cycle is arranged, and  - The preheating water pipe and the heat transfer circuit in the preheating pressure vessel for heating located in the preheating water pipe, liquid water of the water / steam cycle are thermally coupled to each other by means of heat of the heat transfer medium. Apparatus according to claim 1 or 2, wherein - The evaporator has at least one evaporator pressure vessel (421), in which at least one evaporator heat transfer tube (422) for receiving the heat transfer medium of the Wärmeträ ^¬ ger circuit is arranged, and - The evaporator-heat transfer tube and the water / steam circuit in the evaporator pressure vessel for transferring located in the evaporator pressure vessel, heated by the feedwater preheater liquid water of the water / steam cycle in water vapor by means of heat of the heat transfer medium thermally coupled together 4. Device according to one of claims 1 to 3, wherein  - The superheater has at least one superheater pressure vessel (431) in which at least one superheater water pipe (432) for receiving the water vapor generated by the evaporator of the water / steam cycle is arranged, and  - The superheater water pipe and the heat transfer circuit in the superheater pressure vessel for superheating the water vapor contained in the superheater water pipe, formed by the evaporator by means of heat of the heat transfer medium are thermally coupled together. 5. Device according to one of claims 1 to 4, wherein the evaporator pressure vessel of the evaporator and the natural circulation drum of the evaporator are connected to each other such that the water vapor formed in the evaporator pressure vessel can enter the natural circulation steam drum and by the separation in the natural drum formed liquid water can enter the evaporator pressure vessel. 6. Device according to one of claims 1 to 5, wherein the natural circulation drum and the superheater water pipe are connected to ^¬ each other, that the water vapor can pass after the separation of liquid water in the superheater water pipe of the superheater. 7. Device according to one of claims 1 to 6, wherein the natural circulation drum on the evaporator pressure vessel ange- is arranged and between the natural circulation drum and the Ver ^¬ steamer-pressure vessel at least one steam riser (451) is arranged, through which the water vapor formed in the evaporator pressure vessel can enter the natural circulation drum. 8. Apparatus according to claim 7, wherein the steam riser is for carrying the natural circulation steam drum over the evaporator pressure vessel. 9. Device according to one of claims 4 to 8, wherein the preheating pressure vessel, the evaporator pressure vessel and the superheater pressure vessel are connected to each other via at least one external line, through which the heat transfer medium of the heat transfer circuit or the water ^¬ water / steam cycle can flow. 10. The device according to one of claims 3 to 9, wherein the preheating pressure vessel and the evaporator pressure vessel are arranged in such a way that the water of Was ^¬ water / steam cycle and / or the heat transfer medium of the heat transfer cycle directly from Preheat pressure vessel can get into the evaporator pressure vessel. 11. Device according to one of claims 4 to 9, wherein the evaporator pressure vessel and the superheater pressure vessel are arranged in such a way that the heat transfer medium of the heat transfer circuit can pass directly from the superheater pressure vessel in the evaporator pressure vessel. 12. Device according to one of claims 2 to 11, wherein the preheating-pressure vessel is configured such that for thermal coupling of the preheating water pipe and the heat carrier circuit with each other, the heat transfer medium of the heat transfer circuit can flow past the preheating water pipe , 13. The device according to one of claims 4 to 12, wherein the superheater pressure vessel is configured such that for thermal coupling of the superheater water pipe and the Wär ^¬ meträger cycle with each other, the heat transfer medium of the heat transfer circuit can flow past the superheater water pipe , 14. The device according to one of claims 2 to 13, wherein a longitudinal expansion of the preheating water pipe and / or a longitudinal extent of the superheater ^¬ water pipe transverse to a Strö ^¬ tion direction of the heat transfer medium in the preheating pressure vessel and / or transverse to a flow direction the heat transfer medium are arranged in the superheater pressure vessel. 15. Device according to one of claims 2 to 14, wherein the preheating water pipe and / or the superheater water pipe have at least one meander. 16. The apparatus of claim wherein the meander is coated. 17. Device according to one of claims 2 to 16, wherein the preheating water pipe and / or the superheater water pipe are spiral. 18. Device according to one of claims 3 to 17, wherein the evaporator heat transfer tube is straight. 19. Device according to one of claims 2 to 18, wherein a plurality of parallel arranged preheating water pipes and / or a plurality of mutually parallel evaporator heat transfer tubes and / or a plurality of mutually parallel superheater water pipes are present. 20. The apparatus of claim 19, wherein between the plurality of parallel arranged preheating water pipes and / or between the plurality of mutually parallel superheater water pipes Umleitbleche for changing a flow direction of flowing in preheating pressure vessel heat transfer medium of the heat transfer circuit and / or changing a flow direction in the superheater pressure vessel flowing heat transfer medium of the heat transfer Circulation are present. 21. Device according to one of claims 1 to 20, wherein a plurality of steam generators is present. 22. A method for generating superheated steam using a device according to one of claims 1 to 21, comprising the following method steps: a) providing the heat transfer medium, b) converting solar energy into heat of the heat transfer medium and c) transferring the heat of the heat transfer medium to the What ^¬ water of the water / steam cycle, wherein the superheated steam is generated. 23. Use of the superheated in accordance with the method of claim 22 water vapor for the production of electrical energy, wherein with the aid of the superheated steam, a steam turbine (12) is driven.