DE19623457A1 - Method for operating a solar power plant with at least one solar steam generator and solar power plant - Google Patents

Abstract

In a process for operating a solar power station (2) with at least one solar steam generator (4) supplied with feed-water, the residual humidity (1-x) of the wet steam is adjusted at the output (12) of the solar steam generator (4) depending on the power (1-x) of the solar radiation. This measure largely avoids overheating of the solar steam generator (4).

Description

The invention relates to a method for operating a solar power plant with at least one solar steamer generator and a solar power plant.

It is known that in solar power plants on the ground falling solar radiation as a heat source for the reshaped served energy conversion. Examples of solar power plants are parabolic trough, tower and dish power plants.

The solar radiation, for example, is on the ground Racks arranged mirrors, the heliostats, on the right ceiver, for example the receiver in the tower of a tower force works or the receivers in a dish power plant there and heats the heat transfer medium. Another Possibility of using solar energy is the solar bundle radiation using parabolic trough collectors and to an absorber tube, which serves as a receiver. If the heat transfer medium, such as water, directly in evaporates the receiver, one speaks of a direct connection damping. With direct evaporation, the receiver is also referred to as a solar steam generator.

From the article "Solar Farm Power Plants and Direct Evaporation in parabolic trough collectors "by M. Müller, Forschungsverbund Solar energy: "Themes 93/94" is known to solar power plants around 70% of the costs from the solar steam generator ger caused. The remaining 30% are accounted for by con conventional system parts. This translates into a cost reduction  decoration on the solar steam generators Total cost of the solar power plant.

High demands are made regarding the constancy of the steam parameters to the steam generator system. For one, there is the risk of overheating in the solar steam generator. Because of The high temperature can damage the solar steam generator arise, which lead to a shorter operating time. As a result, the material requirements are considerable the solar steam generator. Furthermore A regulated water supply must be guaranteed. The even current short lifespan of the solar steam generator due to the high temperature of the solar superheated steam leads to a considerable cost burden of the solar power plant.

Due to the high temperature of the solar superheated steam In the solar steam generator there are losses due to tempera door reflection from the solar steam generator.

The invention is based on the object of a method to operate a solar power plant where the Avoid danger of overheating in a solar steam generator and a significant cost reduction in solar power work takes place. In addition, a solar power plant is to be implemented ren of the procedure.

The first object is achieved according to the invention with a method for operating a solar power plant with we at least a solar steam generator, with the residual moisture (1-x) of the wet steam at an outlet of the solar steam generator gers depending on the solar radiation power is controlled.  

The second object is achieved according to the invention with a solar power plant with at least one solar steam generator ger, with a controller for controlling the residual moisture (1-x) of wet steam at an outlet of the solar steam generator.

In this method of operating a solar power plant with at least one solar steam generator will get the rest moist (1-x) of the wet steam at the outlet of the solar steam generator in Controlled depending on the solar radiation power, that a predetermined residual moisture (1-x) * of the wet steam on Output is present. The existence of the residual moisture (1-x) of the Wet steam at the outlet of the solar steam generator continues from that within the solar steam generator wet steam, d. H. in other words water and steam. Through the Generation and use of wet steam will overheat the avoided solar steam generator. The temperature in the solar This significantly reduces steam generator. As a result the requirement regarding the temperature be reduced consistency to put together the solar steam generator the components. An absorber coating of the solar steam Producer can therefore work in a temperature range ten, which ga an optimal efficiency for absorption guessed.

Radiation losses due to temperature retroreflection can largely avoided. The lower operating level temperature ensures a longer service life for the individual Components of the solar steam generator. This leads to a considerable savings in costs for the solar power plant.

Preferably, a feed water supply for the solar Steam generator controlled. Controlling is a process in which a size as an input size, d. H. the solar radiation line size, other than the original size, due to which the  Control influences peculiar laws. In particular The feed water supply for the solar steamer becomes special producer regulated.

A device for continuous detection is preferred the solar radiation power provided. It will be like this radiant power either continuously or off repeatedly groping continuously.

In particular, is a donor device for a command variable (1-x) * of the residual moisture (1-x) of the wet steam. The Command variable (1-x) * is fed to the controller from the outside and has the value of the specified residual moisture (1-x) * of the wet steam at the outlet of the solar steam generator.

In a further embodiment is in front of the solar steamer a device for continuous acquisition of the Mas Senstroms M of the feed water supply provided.

A feed water valve is preferably used as the actuating device for the mass flow M of the feed water supply for the solar Steam generator provided.

In particular, a control device for setting the Feed water valve provided.

To further explain the invention, the Ausfü Example of the drawing referenced in the only one Figure a section of a solar power plant with a solar Steam generator is shown schematically.

According to the figure, a solar power plant 2 , for example a parabolic trough, tower or dish power plant, comprises a solar steam generator 4 . The solar steam generator 4 is feed water fed via a feed line 6 . In the feed line 6 , a feed water valve 8 in the flow direction as a control device for the mass flow M of the feed water supply for the solar steam generator 4 and a device 10 for the continuous detection of the mass flow M of the feed water supply are arranged one behind the other.

From the solar steam generator 4 , it is discharged from an outlet 12 via a derivative 14 of the steam generated in the solar steam generator 4 . The wet steam has the rest moist (1-x), where x is the steam content.

Between the device 10 for continuously detecting the mass flow M of the feed water supply and the feed water valve 8 as an actuating device for the mass flow M of the feed water supply for the solar steam generator 4 , an electrical signal line 16 is connected. In the electrical Si signal line 16 , a control device 18 for adjusting the feed water valve 8 is arranged.

A device is switched over 20 ei ne electrical signal line 22 to the control device 18th The device 20 continuously detects the solar radiation power and supplies the values of the solar radiation power as an input variable to the control device 18 .

In addition, a transmitter device 24 for a reference variable (1-x) * of the residual moisture (1-x) of the wet steam via an electrical signal line 26 on the control device 18 switches ge.

To operate the solar power plant 2 , the residual moisture (1-x) of the wet steam at the outlet 12 of the solar steam generator 4 is controlled as a function of the solar radiation power.

At any point in time of operation, a predetermined residual moisture (1-x) * of the wet steam should be present at the outlet 12 of the solar steam generator 4 .

The control takes place according to the functional combination hillside

With
h _a enthalpy of the wet steam at the outlet 12 of the solar evaporator 4 in kJ / kg,
h _e enthalpy of the feed water before it is fed into the solar evaporator 4 in kJ / kg,
Q solar net heat input in kW,
H mass flow of the feed water supply for the solar steam generator 4 in kg / s,
h ′ enthalpy of saturated feed water in kJ / kg,
x the steam content of the wet steam at the outlet 12 of the solar steam generator 4 dimensionless
and r the heat of vaporization of the feed water in kJ / kg.

The steam content x at the output 12 of the solar steam generator 4, and thus the residual moisture (1-x) * of the wet steam, is predetermined as a constant input variable for the control. Further for a selected operating pressure of the sola ren steam generator 4 constant inputs for the control are the enthalpy h 'of the saturated feed water and the heat of vaporization r of the feed water. The variable input variables of the control are the solar net heat input Q and the enthalpy h _{e of} the feed water before it enters the solar steam generator 4 .

If the pressure in the solar steam generator 4 changes during operation, the enthalpy h 'of the saturated feed water and the heat of vaporization r of the feed water are variable input variables of the control.

The constant and variable input variables of the control are made available to the control device 18 . The net heat input is calculated from the solar radiation power, which is continuously detected with the device 20 and switched to the control device 18 . In the calculation of the solar net heat supply in the control device 18 also go into specific sizes of the solar steam generator 4 , such as geometry and material properties, of which, for. B. depend on the heat losses of the solar steam generator 4 .

With the device 10 for continuously detecting the mass flow M of the feed water supply, the pressure p and the temperature T of the feed water can be continuously detected and switched to the control device 18 via the electrical signal line 16 . In the Steuereinrich device 18 , the enthalpy h _{e of} the feed water before entering the solar steam generator 4 is then calculated with the aid of a steam table deposited in the same. In addition, the enthalpy h 'of the saturated feed water and the heat of vaporization r of the feed water are made available by means of the stored steam table.

The desired guide value (1-x) * for the steam content x, and thus for the residual moisture (1-x) of the wet steam at the output 12 of the solar evaporator 4 , is switched with the transmitter device 24 via the electrical signal line 26 to the Steuereinrich device 18 .

For the desired residual moisture content (1-x) * of the wet steam from the gear 12 of the solar steam generator 4 is thus the entspre sponding mass flow M are calculated the feed water supply to the solar steam generator 4 in the control means 18th

This calculated value for the mass flow M is compared with the mass flow M continuously detected by the device 10 . After the comparison the control is as the output device 18, a manipulated variable y on the feed water valve 8 as an actuator for the mass flow M of the feedwater supply connected, so that the mass flow M is the mains water supply is changed so that at the output 12 of the solar steam generator 4, the Desired residual moisture (1-x) * of the wet steam is present. To control the residual moisture (1-x) of the wet steam, the mass flow M feed water supply for the sola ren steam generator 4 is thus regulated.

In a further embodiment, the feed water supply can be controlled by dispensing with a continuous detection of the mass flow M of the feed water supply with the device 10 .

Several solar steam generators can also be connected in series are switched, so that the control according to this Figure also for each of the one behind the other switched solar steam generator can be used. There is depending on a variety of solar steam generators the steam generator is individually controlled.

Every downstream solar steam generator receives the Outlet mass flow of the upstream solar steam generator  gers and an individually controlled feed water flow, the is controlled so that at the outlet of the steam generator before given residual moisture (1-x) * of the wet steam is present.

Claims (8)

1. A method for operating a solar power plant ( 2 ) with at least one solar steam generator ( 4 ), the rest of which is moist (1-x) of the wet steam at an outlet ( 12 ) of the solar steam generator ( 4 ) depending on the solar beam performance is controlled. 2. A method of operating a solar power plant ( 2 ) according to claim 1, in which a feed water supply for the solar steam generator ( 4 ) is controlled. 3. A method for operating a solar power plant ( 2 ) according to claim 1, wherein the feed water supply for the solar steam generator ( 4 ) is regulated. 4. Solar power plant ( 2 ) with at least one solar steam generator ( 4 ), with a controller for controlling the residual moisture (1-x) of the wet steam at an output ( 12 ) of the solar steam generator ( 4 ) according to any one of the preceding claims. 5. Solar power plant ( 2 ) according to claim 4, with a device ( 20 ) for continuously detecting the solar radiation stung. 6. Solar power plant ( 2 ) according to claim 4 or 5, with a Ge bereinrichtung ( 24 ) for a reference variable (1-x) * the rest of the moisture (1-x) of the wet steam. 7. Solar power plant ( 2 ) according to one of claims 4 to 6, with a device arranged in front of the solar steam generator ( 4 ) Vorrich ( 10 ) for continuously detecting the mass flow M of the feed water supply. 8. Solar power plant ( 2 ) according to one of claims 4 to 7, with a feed water valve ( 8 ) as an adjusting device for the mass flow M of the feed water supply for the solar steam generator ( 4 ).