DE10329623B3 - Solar-thermal extraction of electrical energy involves heating medium by solar heating to above temperature working point of steam turbine, using to charge heat store connected before steam turbine. - Google Patents

Abstract

The method involves feeding a solar thermally heated heat carrying medium to a steam turbine at a defined temperature working point. The heat carrying medium, or a working medium heated by it, is heated by solar heating to a temperature corresponding to a temperature of the medium above the temperature working point of the steam turbine and used to charge a heat store connected before the steam turbine. An independent claim is also included for the following: (a) a solar-thermal power station.

Description

The The invention relates to a process for solar thermal recovery electrical energy, in the solar thermal heated heat transfer medium one Steam turbine is supplied to a defined temperature operating point.

The The invention further relates to a solar thermal power plant comprising a collector device, by means of a heat transfer medium or a working medium, heated by which heat transfer medium is, can be heated solar thermal, a steam turbine, the heat transfer medium vapor can be fed and a heat storage.

Such devices may be found, for example, in the articles "The Power Production Operation of Solar One, the 10 MWe Solar Thermal Central Receiver Pilot Plant" by LG Radosevich and AC Skinrood, Transactions of the ASME 144 / Vol. 111, May 1989 or "Direct Steam Generation in Parabolic Troughs Final Results and Conclusions of the DISS Project" by E. Zarza et al., 11 ^th International Symposium on Solar Thermal Concentrating Technologies, Zurich, 4-6 September 2002, pages 21 to 27 or "Regenerative thermal Storage in Atmospheric Air system solar Power Plants" by HW Fricker, 11 ^th SolarPACES Symposium on Concentrated solar Power and Chemical Energy Technologies, Sept. 4-6 2002, Zurich, pages 509-515 known.

From the US 4,400,946 For example, a solar thermal steam turbine power plant is known which comprises a heliostat field and a collector system mounted on a tower or column. Radiation receiver of the collector system are preferably formed annular sector-shaped and extend over a peripheral portion of the top of the tower.

From the US 4,249,386 For example, a heat engine system with a liquid condenser is known.

Of the Invention is based on the object, a method and an apparatus of the type mentioned above, in which or on easy way to heat storage is realized.

These The object is achieved according to the invention in the method mentioned solved that the heat transfer medium or a working medium which heats the heat transfer medium, solar thermal is heated to a temperature which corresponds to a temperature of the heat transfer medium corresponds above the temperature operating point of the steam turbine, and that means of the heat transfer medium or working medium a heat storage is loaded, which is upstream of the steam turbine.

According to the invention Heat transfer medium or the working medium, if enough Solar thermal energy is provided at a temperature heated, which is above the temperature of the heat transfer medium for the downstream steam power process. The excess energy will to the heat storage issued. The heat transfer medium or the working medium cool From and the steam power process heat transfer medium is provided at the temperature operating point. When there are deteriorated irradiation conditions, such as when cloud cover the collector device, then the heat storage Thermal energy provide for continued operation of the steam turbine.

There the heat transfer medium or the working fluid through the collector means to a higher temperature is heated, as for the steam power process is needed then again the opportunity arises that in the Discharge process reaches the temperature operating point of the steam turbine becomes. In contrast to known from the prior art heat storage method the storage medium is in the heat storage brought to a temperature which is above the temperature operating point the steam turbine is located. It can be thereby also in unloading a power plant cycle with the optimal Operating parameters for reach the steam turbine. This in turn allows, with a simple system structure, achieve a high energy yield, since just the steam turbine optimally is operable.

Of the Heat storage according to the invention acts as a buffer that at least temporarily worsened in the irradiation conditions can bridge. In these bridging times while the efficiency is not significantly deteriorated.

The inventive concept can be especially use when the heat transfer medium is evaporated directly solar thermal. There still exists here no cost Storage concept, such is the method of the invention provided.

It has proved to be advantageous if the temperature difference between the temperature to which the heat transfer medium or the working medium is heated solar thermal, and the temperature operating point of the steam turbine is at least 20 K and preferably at least 25 K. In particular, the temperature difference is in Be rich between 30 K and 60 K, and preferably between 30 K and 50 K. System parameters that determine this temperature difference, in particular heat losses that occur in the system.

By the inventive method let yourself the pressure level for keep the loading operation and unloading operation substantially the same. This ensures in particular that in the unloading operation is not in the Partial load operation must be driven. Preferably, the temperature difference between the temperature to which the heat transfer medium or the working medium is heated, and the temperature operating point of the steam turbine so chosen that the pressure during a charging process of the heat accumulator and a discharge of the heat accumulator at the same level.

All It is particularly advantageous if the heat transfer medium or the working medium for heating the heat transfer medium solar thermal to a higher Temperature is heated as for the steam turbine process is needed. This can be done then also in the unloading the temperature required for the steam turbine process in the heat transfer medium reach and in particular can be reach the temperature operating point of the steam turbine.

Further Cheap is it when the heat transfer medium or the working medium solar heated to a temperature which is a temperature above the inlet temperature of Heat transfer medium in the steam turbine corresponds (in normal operation, that is when sufficient irradiation conditions are present). This in turn let yourself in unloading the heat transfer medium Heat to the temperature operating point of the steam turbine.

Especially is in a discharge process of the heat storage heat transfer medium supplied to the steam turbine at the temperature operating point, so that yourself also in unloading no significant deterioration of the efficiency results.

Especially is the temperature of the solar thermal heated heat transfer medium or working medium whose mass flow is controlled and / or regulated. In the solar thermal Direct evaporation can be done via the volume flow or mass flow the temperature can be adjusted. (As the fluids used in the relevant temperature and pressure range considered incompressible can be are volume flow and mass flow proportional to each other.)

Favorable is the heat storage over a Charging circuit charged and over unload a discharge circuit. The two circles are separated disconnect, so that the heat load the heat storage and the heat discharge the heat storage perform optimally to let.

Especially can be advantageous the inventive concept use when the heat transfer medium is evaporated directly solar thermal.

It can be provided that the heat transfer medium is heated in a gutter collector device. Basically it but it is also possible that the direct solar thermal evaporation in a Turmreceivereinrichtung carried out becomes.

in the Trap of a trough collector device stores the heat storage advantageously sensitive heat. For this purpose, for example, a ceramic bed is used as a storage medium or a liquid one Storage medium like a heat oil.

It is possible, too, that heat transfer medium and / or working medium heated in a Turmreceivereinrichtung becomes.

Especially is used in this context as a working medium air, which heat to heat transfer medium in a heat transfer medium circuit emits. The air is released to a high temperature such as 800 ° C heated. The corresponding Heat is then from the gaseous Air to the heat transfer medium delivered to overheat Heat transfer medium vapor to create.

Especially is then a charging circuit for the heat storage to a working medium guide coupled. The hot Working medium then indicates heat the storage medium in the heat storage from.

One Discharge circuit for the heat storage is preferably to the heat transfer medium coupled so that the heat storage direct heat the heat transfer medium can deliver without a Working medium circuit is connected in between.

It can be provided that then the heat storage sensible heat stores. It is also possible, that the heat storage latent heat stores, since the temperature of the working medium above the temperature the heat transfer medium lies.

The above-mentioned object is achieved in the generic solar thermal power plant according to the invention that a control and regulating device is provided, via which the mass flow through the collector device is controlled and / or regulated so that the Heat transfer medium or the working fluid is heated to a higher temperature than corresponds to the temperature operating point of the steam turbine, and that the heat accumulator is coupled to a guide for the thus heated heat transfer medium or working fluid.

These Device is suitable for the implementation the method according to the invention. The corresponding benefits have already been linked to the inventive method explained.

Further advantageous embodiments have also already been related with the method according to the invention explained.

Especially is a charging circuit for the heat storage provided, wherein the charging circuit preferably via a heat exchanger to the guide for heat transfer medium or working medium is coupled. This allows the heat transfer medium cool down to the operating point temperature of the steam turbine or the working medium can be so far cooling down, that this Heat transfer medium, which is heated by the working fluid to the operating point temperature the steam turbine is broken. At the same time, the heat storage can be load, whereby a temperature is reached, which in turn in the unloading process in the heat transfer medium can reach the temperature operating point of the steam turbine.

Out For the same reason, it is advantageous if a discharge circuit for the heat storage is provided, which over a heat exchanger to a heat transfer medium circuit for the Steam turbine is coupled. It can be then directly the heat transfer medium by means of the heat accumulator heat.

at an embodiment comprises the solar collector device trough collectors, in particular Heat transfer medium is directly evaporable in the trough collectors.

Of the heat storage is then preferably designed as a storage for sensitive heat.

It can also be provided that the Solar collector means comprises a Turmreceivereinrichtung, wherein Also focused on the receiver solar radiation bundled by heliostats becomes.

It is then conveniently a guide provided for heating a working medium, wherein the guide by a receiver of the tower receiver device is performed.

Further is it cheap if a heat transfer medium circuit to the leadership coupled by working medium. About the working medium, at which is, for example, air, then can be the heat transfer medium heat, so in turn overheated Heat transfer medium vapor to generate, which drives the steam turbine.

Of the heat storage is then preferably loadable by means of heated working medium.

It is also cheap if the heat storage so to the heat transfer medium circuit coupled is that in a discharge heat at heat transfer medium is deliverable. This can be done then directly the heat transfer medium heat.

at the heat storage it can be a memory for sensible heat act or make a memory for latent heat. A latent heat storage can be Use here advantageous because the temperature of the heated working fluid above the temperature the heat transfer medium lies, to which the working medium gives off heat. It will be one Phase change material for the latent heat storage selected its phase change temperature above the temperature operating point the steam turbine is located.

The The following description of preferred embodiments is used in conjunction with the drawing of the closer Description of the invention. Show it:

1 a schematic representation of a first embodiment of a solar thermal power plant according to the invention;

2 a schematic temperature (T) -warm (Q) diagram for an embodiment of the method according to the invention in connection with the solar thermal power plant according to 1 ;

3 A second embodiment of a solar thermal power plant according to the invention;

4 a TQ diagram for explaining the method according to the invention in connection with the solar thermal power plant according to 3 if a heat storage is used for sensible heat and

5 a TQ diagram, if alternatively a latent heat storage is used.

A first embodiment of a solar thermal power plant according to the invention, which in 1 shown schematically and there as a whole with 10 is designated comprises a collector direction 12 , by means of a heat transfer medium such as water is solar thermal heated.

In the embodiment according to 1 includes the collector device 12 a plurality of trough collectors 14 which are in a collector strand 16 are connected in series.

There may be a plurality of parallel-connected collector strands 16 be provided.

The heat transfer medium flows through a gutter collector 14 each in an absorber tube 18 on which the solar radiation is concentrated. The heat transfer medium is heated.

In the collector device 12 is coupled liquid heat transfer medium. In the collector device 12 Then the heat transfer medium is evaporated and overheated. A collector string 16 is composed of an evaporator section and a superheater section.

In 2 schematically a temperature (T) heat (Q) diagram is shown. At an entry point 20 enters liquid heat transfer medium and in particular water in a collector strand 16 one. When heat is applied, the heat transfer medium heats up and upon reaching the boiling point, it evaporates. It then results in an area 22 a two-phase flow in the TQ diagram, in which both liquid heat transfer medium and vaporous heat transfer medium is present. In this area, the temperature of the heat transfer medium is substantially constant. At the end of the evaporator section liquid heat transfer medium is separated from the vaporous heat transfer medium and the vaporous heat transfer medium fed to the superheater section, where it is further heated (range 24 in 2 ).

An exit 26 the collector device 12 , on which superheated heat transfer medium can be dispensed, is via a guide line 28 to a steam turbine 30 coupled. This is operated at a certain operating temperature.

The steam turbine 30 in turn drives a generator 32 on, over which can generate electricity.

A heat transfer medium circuit 34 is closed by that of the steam turbine 30 a line 36 back to the collector device 12 leads.

In the line 36 is a pump 38 arranged, with the (liquid) heat transfer medium from the steam turbine 30 to the collector device 12 is transportable.

In the line 36 is also the pump 38 upstream, a heat exchanger 40 arranged, which, for example, to a cooling tower 42 is coupled. About the heat exchanger 40 in connection with the cooling tower 42 can be vaporous heat transfer medium, which still in the steam turbine 30 removed fluid is contained, condense.

In 2 is the temperature operating point of the steam turbine 30 with the reference number 44 shown. The heat transfer medium is supplied so that this operating point is maintained with close tolerances, so that the steam turbine operates at an optimized operating point.

It should also be noted that on the abscissa according to 2 the amount of heat Q is applied. Under normal irradiation conditions, the amount of heat transferred to the heat transfer medium decreases along a collector strand 16 to. The abscissa axis therefore also corresponds at least approximately to the distance along a collector strand 16 , At the same time, the abscissa coordinate is also proportional to a time coordinate under constant irradiation conditions, as when in a collector string 16 coupled heat transfer medium volume is considered, this when passing through the collector strand 16 Absorbs heat and a transition from the liquid state to a two-phase state and finally takes place in the overheated state.

At the in 1 the embodiment shown, the heat transfer medium in the collector device 12 directly evaporated.

According to the invention is a heat storage 46 provided, via which can perform a heat buffer storage. In "normal" radiation conditions, the heat storage 46 , as explained in more detail below, charged. In deteriorating irradiation conditions, which are due for example to cloud cover, the heat storage is at least partially discharged, that is, heat is transferred to the heat transfer medium to the operation of the steam turbine 30 be able to maintain at the operating temperature for at least a while.

This is the heat storage 46 by means of a charging circuit 48 via a heat exchanger 50 to the management 48 for the heat transfer medium from the collector device 12 to the steam turbine 30 coupled. The heat transfer medium is above the heat exchanger 50 in a charge heat to a storage medium of the heat storage 46 from. For this purpose, the storage medium or an intermediate medium flows through the charging circuit 48 which is connected to the heat exchanger 50 and to the heat storage 46 is coupled. The storage medium or the intermediate medium may then be the heat exchanger 50 flow through to absorb heat and can also heat storage 46 flow through to store heat there (by heating storage medium via the intermediate carrier medium or heated storage medium in the heat accumulator 46 is recorded).

In the charging circuit 48 is a pump 52 arranged over which the liquid storage medium or the liquid intermediate carrier medium in the charging circuit 48 is transportable to the heat exchanger 50 To be able to absorb heat.

In the heat storage 46 it is in particular a heat storage for sensitive heat. For example, a heat transfer oil can be used as the liquid storage medium. As a solid storage medium salts can be used.

To the heat storage 46 is also a discharge circuit 54 coupled. This in turn is connected to a heat exchanger 56 coupled, which to the heat transfer medium circuit 34 is coupled. In the discharge circuit 54 sits a pump 58 , over the heated storage medium or intermediate medium in the discharge circuit 54 through the heat exchanger 56 can be transported to deliver heat to the heat transfer medium.

The discharge circuit 54 is so on the heat storage 46 coupled, just from the heat storage 46 liquid storage medium can be coupled out or an intermediate carrier medium on storage medium of the heat storage 46 is heated and then through the heat exchanger 56 is feasible.

At the in 1 embodiment shown is the heat exchanger 56 to a line 60 of the heat transfer medium circuit 34 coupled. This line 60 turn is over a turnoff 62 to the management 28 coupled. A first entrance of this branch 62 is to the heat exchanger 50 coupled while a second input to the heat exchanger 56 is coupled. An exit of the branch 62 leads to the steam turbine 30 ,

Further, the line 60 to a line 64 coupled, which of the heat exchanger 40 to the collector device 12 leads. A coupling point 66 the line 60 is the pump 38 downstream with the line 64 connected.

About the line 60 can heat transfer medium on the temperature operating point of the steam turbine 30 feed when the collector device 12 no heat transfer medium of the required temperature provides, because, for example, a cloud cover is present. The heat transfer medium in the pipe 60 is doing over the heat storage 46 heated.

According to the invention, a control and regulating device 68 provided, via which the mass flow rate of heat transfer medium through the collector device 12 control and / or fix. This in turn allows the temperature of the heat transfer medium, which at the output 26 the collector device 12 is taken, control or regulate.

The control and regulation device 68 can thereby all collector strands 16 upstream, so as to the total mass flow through the collector device 12 to control.

But it can also be alternatively or additionally provided that each individual collector strand 26 its own control and regulation device 70 having the various control and regulating devices 70 in particular by a higher-level institution 72 be coordinated.

It is important that the steam turbine 30 Heat transfer medium on the temperature operating point 44 is supplied, since a steam turbine is optimized for their respective operating point.

According to the invention, in "normal operation", if sufficient irradiation conditions are present, the heat transfer medium in the collector device 12 heated to a temperature which is above the temperature operating point 44 lies. This heating is by the mass flow through the collector device 12 controlled. The temperature difference is typically in the range between 30 K and 50 K. The temperature operating point 44 a steam turbine 30 typically ranges between 400 ° C and 550 ° C.

The heat transfer medium is inventively heated to a higher temperature than it is for the power plant process on the steam turbine 30 necessary is. The heat transfer medium is above the heat exchanger 50 its excess energy to the heat storage 46 from, that is the heat transfer medium, which then the steam turbine 30 is supplied via the charging circuit 48 cooled. At the same time, the heat accumulator loads 46 on.

If then heat transfer medium in the unloading operation on the heat storage 46 is heated, then the temperature operating point can be 44 for the steam turbine 30 reach, that is also in the unloading operation can be the temperature operating point 44 for the steam turbine 30 reach, since just in normal operation, the heat transfer medium on the Ar Beitspunkkttemperatur the downstream steam power process on the steam turbine 30 was heated out.

According to the invention, it can thus be achieved that even in unloading the normal operating point temperature of the steam turbine 30 is reached.

Furthermore, it can be achieved that between normal operation (corresponding to the charging operation of the heat storage 46 ) and discharge operation (for example, at reduced irradiation conditions for the collector device 12 ) there is no significant pressure attack.

In 2 is schematically the TQ curve 74 for the storage medium of the heat storage 46 shown, if it is a sensitive storage medium. The heat transfer medium is through the collector device 12 to a temperature above the temperature operating point 44 heated. The storage medium absorbs the corresponding excess heat.

Also shown is a curve 76 for the heat transfer medium in unloading operation. About the heat storage 46 the heat transfer medium can evaporate and overheat. The heat is the heat transfer medium just above the heat storage 46 fed. As in normal operation (charging operation of the heat storage 46 ) the storage medium to a temperature above the temperature operating point 44 is heated, then in the unloading operation of the heat storage 46 the heat transfer medium in the pipe 60 on the temperature operating point 44 heat what's through the point 78 is indicated. This heating takes place without significant pressure drop.

According to the invention is characterized provided a method for buffering thermal energy, in which also in the unloading operation of the heat storage, the process temperature for the Heat transfer medium the process temperature the heat transfer medium in normal operation.

One corresponding buffer can be on simple and inexpensive Realize way.

Basically, besides sensitive storage media also latent storage media can be used.

In a second embodiment of a solar thermal power plant according to the invention, which in 3 is shown schematically and designated there as a whole with 80, in turn, a collector device 82 provided, which a Turmreceivereinrichtung 84 and a heliostat field 86 with a plurality of heliostats 88 includes. The heliostats 88 bundle solar radiation and direct it to a receiver 90 , which concerning the heliostats 88 elevated (on a tower) is arranged.

In the embodiment shown, the receiver 90 flows through a working medium such as air. This is a leadership 92 through the receiver 90 guided. In the management 92 sits a pump 94 to provide for the transport of air as a working medium.

In the receiver is heated to a temperature of about 800 ° C, if there are good irradiation conditions.

The management 92 with the heated air then leads to a heat exchanger 96 , to which a heat storage 98 is coupled. At the heat accumulator is, as already described above in connection with the first embodiment, a charging circuit 100 with a pump 102 as well as a discharge circuit 104 with a pump 106 coupled.

About the charging circuit 100 can the heat storage 98 load, with the charging circuit 100 to the heat exchanger 96 is coupled.

To the management 92 is another heat exchanger 110 coupled. This heat exchanger 110 is to a heat transfer medium circuit 112 coupled, so that heat transfer medium can be heated in the heat transfer medium via the working medium.

In the heat transfer medium circuit 112 sits a steam turbine 114 which is a generator 116 drives. Furthermore, sitting in the heat transfer medium 112 a heat exchanger 118 , which with a cooling tower 120 connected is. About the heat exchanger 118 can be vaporous heat transfer medium, which from the steam turbine 114 is removed, condense out.

Further, a pump 122 provided to liquid heat transfer medium in the heat transfer medium circuit 112 to transport.

The discharge circuit 104 is via a heat exchanger 124 to the heat transfer medium circuit 112 coupled, so that in an unloading heat transfer medium in the heat transfer medium 112 by means of the heat accumulator 98 heat to the steam turbine 114 Heat transfer medium at the temperature operating point of the steam turbine 114 to be able to supply.

The heat exchanger 118 is to the heat transfer medium circuit 112 via a docking station 126 and a docking station 128 connected. A line 130 in which the heat exchanger 124 for the heat storage 98 is arranged with the coupling points 126 and 128 connected, so that in the discharge operation of the heat exchanger 124 the function of the heat exchanger 110 can take over.

According to the invention, in turn, as above in connection with the 1 described, performed a solar thermal heating, which ensures that the working temperature is higher than that of the downstream steam power process. For this purpose, the working fluid is heated to a higher temperature than it is for the temperature operating point 132 ( 4 and 5 ) of the steam turbine 114 is required. For example, the working fluid (such as air) passes through the heat exchanger 96 In normal Einstrahlungungsbedigungen of a temperature of about 800 ° C to a temperature of about 600 ° C cooled. In the heat exchanger 110 then gives the cooled working fluid a part of its heat to the heat transfer medium in the heat transfer medium 112 to produce superheated steam, then the steam turbine 114 is operated.

This is exemplary in 4 shown in a TQ diagram:
The curve 134 is the corresponding TQ curve of the gaseous working medium air. The more heat is supplied, for example, the more heliostats 88 their radiation on the receiver 90 bundling, the higher the temperature in the working medium. In practice, the mass flow is controlled or regulated on the working medium in order to achieve a substantially constant temperature in the working medium. The working medium heats the heat transfer medium, its TQ curve with the reference numeral 136 is provided. Again, one can see the two-phase region with almost constant temperature and the overheating area. The temperature operating point 132 the steam turbine 114 is drawn.

In the heat storage 98 the storage medium is heated during charging. For a sensitive storage medium this is in 4 through the bend 138 indicated. As mentioned, the temperature at which the working fluid passes through the heat exchanger 96 above the temperature necessary to reach the temperature operating point. According to the invention, this is a control and regulating device 140 provided by means of the mass flow of working fluid through the receiver 90 is controlled and / or regulated so that just the corresponding temperature is adjusted.

In unloading operation, the heat storage 98 over the discharge circuit 104 and the heat exchanger 124 Heat to the heat transfer medium in the heat transfer medium 112 from. This is through the bend 142 in 4 indicated. It can be seen again that the temperature operating point 132 for the heat transfer medium in the heat transfer medium circuit 112 can reach, since just the working medium was heated above a temperature for the temperature operating point 132 is required and the excess heat through the heat exchanger 96 to the heat storage 98 was delivered.

In 5 are the same conditions as in 4 shown when the heat storage 98 is a latent heat storage. Such a latent heat storage can be according to the embodiment 3 Use advantageous because the temperature of the air as the working medium (curve 134 ) is above the temperature of the heat transfer medium.

The TQ curve of the latent heat storage is denoted by the reference numeral 144 Mistake. An appropriate storage medium is used whose phase change temperature is above the temperature operating point 132 is, for example, at a temperature difference of 30 K to 50 K, so in the unloading the temperature operating point 132 for the heat transfer medium in the heat transfer medium circuit 112 is reachable.

Again, the same process temperature for the steam power process can be achieved if the heat transfer medium in the heat transfer medium 112 about the unloading operation of the heat accumulator 98 is heated, compared to the case when the heat transfer medium in the heat transfer medium circuit 112 over the working medium by means of the heat exchanger 110 is heated. These same temperature conditions can be achieved without significant pressure loss.

Claims (35)

Process for the solar thermal recovery of electrical energy, in which solar thermal heated heat transfer medium of a steam turbine at a defined temperature operating point is supplied, characterized in that the heat transfer medium or a working medium which heats the heat transfer medium is heated solar thermal to a temperature which corresponds to a temperature of the heat transfer medium corresponds above the temperature operating point of the steam turbine, and that by means of the heat transfer medium or working medium, a heat storage is charged, which is upstream of the steam turbine. Method according to claim 1, characterized in that that the Temperature difference between the temperature to which the heat transfer medium or the working medium is heated solar thermal, and the temperature operating point the steam turbine is at least 20K. Method according to claim 2, characterized in that that the Temperature difference is at least 25 K. Method according to claim 2 or 3, characterized that the Temperature difference is in the range between 30 K and 60 K. Method according to one of the preceding claims 1 to 4, characterized in that the temperature difference between the temperature to which the heat transfer medium or the working medium is heated, and the temperature operating point of the steam turbine so chosen will that the Pressure during charging of the heat accumulator and the pressure at a discharge of the heat storage substantially are the same. Method according to one of the preceding claims 1 to 5, characterized in that the heat transfer medium or the working medium for heating the heat transfer medium solar thermal on a higher one Temperature is heated as for the steam turbine process is needed. Method according to Claim 6, characterized that this Heat transfer medium or the working medium solar heated to a temperature which is a temperature above the inlet temperature of Heat transfer medium corresponds to the steam turbine. Method according to one of the preceding claims 1 to 7, characterized in that in a discharge of the heat storage Heat transfer medium the steam turbine is supplied at the temperature operating point. Method according to one of the preceding claims 1 to 8, characterized in that the temperature of the solar thermal heated heat transfer medium or working medium whose mass flow is controlled and / or regulated. Method according to one of the preceding claims 1 to 9, characterized in that the heat storage via a Charging circuit is charged. Method according to one of the preceding claims 1 to 10, characterized in that the Heat storage over a Discharge circuit is discharged. Method according to one of the preceding claims 1 to 11, characterized in that the heat transfer medium is evaporated directly solar thermal. Method according to claim 12, characterized in that that heat transfer medium is heated in a gutter collector device. Method according to claim 12 or 13, characterized that the heat storage sensible heat stores. Method according to one of claims 1 to 12, characterized that heat transfer medium and / or working medium heated in a Turmreceivereinrichtung becomes. Method according to claim 15, characterized in that that as Working medium air is used, which heat to heat transfer medium in a heat transfer medium emits. Method according to claim 16, characterized in that the existence Charging circuit for the heat storage to a working medium guide is coupled. Method according to claim 16 or 17, characterized the existence Discharge circuit for the heat storage coupled to the heat transfer medium circuit becomes. Method according to one of claims 15 to 18, characterized that the heat storage sensible heat stores. Method according to one of claims 15 to 19, characterized that the heat storage latent heat stores. Solar thermal power plant, comprising a collector device ( 12 ; 82 ), by means of which a heat transfer medium or a working medium, by means of which heat transfer medium can be heated, can be heated solar-thermally, a steam turbine ( 30 ; 114 ), the heat transfer medium vapor can be supplied, and a heat storage ( 46 ; 98 ), characterized by a control and regulating device ( 68 ; 70 . 72 ; 140 ), via which the mass flow through the collector device ( 12 ; 82 ) is controllable and / or controllable such that the heat transfer medium or the working fluid can be heated to a higher temperature than the temperature operating point ( 44 ; 132 ) of the steam turbine ( 30 ; 114 ) and that the heat storage ( 46 ; 98 ) to a tour ( 28 ; 92 ) is coupled for the thus heated heat transfer medium or working medium. Solar thermal power plant according to claim 21, characterized in that a charging circuit ( 48 ; 100 ) for the heat storage ( 46 ; 98 ) is provided. Solar thermal power plant according to claim 22, characterized in that the charging circuit ( 48 ; 100 ) via a heat exchanger ( 50 ; 96 ) to the leadership ( 28 ; 92 ) for heat transfer medium or labor medium is coupled. Solar thermal power plant according to one of claims 21 to 23, characterized in that a discharge circuit ( 54 ; 104 ) for the heat storage ( 46 ; 98 ) is provided. Solar thermal power plant according to claim 24, characterized in that the discharge circuit ( 54 ; 104 ) via a heat exchanger ( 56 ; 124 ) to a heat transfer medium circuit ( 34 ; 112 ) for the steam turbine ( 30 ; 114 ) is coupled. Solar thermal power plant according to one of claims 21 to 25, characterized in that the collector device ( 12 ) Gutter collectors ( 14 ). Solar thermal power plant according to claim 26, characterized in that in the trough collectors ( 14 ) Heat transfer medium is directly evaporable. Solar thermal power plant according to claim 26 or 27, characterized in that the heat accumulator ( 46 ; 98 ) is designed as a storage for sensitive heat. Solar thermal power plant according to one of claims 21 to 25, characterized in that the solar collector device ( 82 ) a tower receiver device ( 84 ). Solar thermal power plant according to claim 29, characterized in that a guide ( 92 ) is provided for heating a working medium. Solar thermal power plant according to claim 30, characterized in that a heat transfer medium circuit ( 112 ) to the leadership ( 92 ) is coupled for working medium. Solar thermal power plant according to claim 30 or 31, characterized in that the heat storage ( 98 ) Is loadable by solar thermal heated working medium. Solar thermal power plant according to claim 31 or 32, characterized in that the heat accumulator ( 98 ) to the heat transfer medium circuit ( 112 ) is coupled, so that in a discharge heat to heat transfer medium can be delivered. Solar thermal power plant according to one of claims 29 to 33, characterized in that the heat accumulator ( 98 ) is a storage for sensitive heat. Solar thermal power plant according to one of claims 29 to 34, characterized in that the heat accumulator ( 98 ) is a latent heat storage.