Method for operating a linear concentrator solar power plant, and linear concentrator solar power plant

The invention claimed is: 1. A method for operating a linearly concentrating solar power plant, in which the linearly concentrating solar power plant is a parabolic trough solar power plant or a Fresnel power plant and a heat transfer medium flows through a pipeline loop having at least one receiver, the heat transfer medium having a flow velocity which is such that the flow in the pipeline loop is turbulent and/or the heat transfer medium being able to be heated uniformly from all sides so that no inadmissible temperature differences occur within the pipeline loop, wherein at least part of the heat transfer medium, upon exit from the pipeline loop, is extracted and is recirculated into the pipeline loop, wherein that part of the heat transfer medium which is recirculated into the pipeline loop is mixed, before introduction into the pipeline loop, with the heat transfer medium delivered to the pipeline loop, and wherein, to mix that part of the heat transfer medium which is recirculated into the pipeline loop and the heat transfer medium delivered to the pipeline loop, a tank is used as mixing device, into which the recirculated part of the heat transfer medium and the delivered heat transfer medium are introduced and out of which a mixture of recirculated heat transfer medium and of delivered heat transfer medium is fed into the pipeline loop and wherein the tank is also configured as an emptying tank, wherein during the operation of the linearly concentrating solar power plant, the tank is partly filled and the non-filled volume is dimensioned such that the heat transfer medium contained in the pipeline loop can flow out into the emptying tank. 2. The method according to claim 1 , wherein the heat transfer medium is a salt melt. 3. The method according to claim 2 , wherein the salt melt is a mixture of potassium nitrate and sodium nitrate. 4. The method according to claim 2 , wherein the salt melt is a mixture of 40% by weight of potassium nitrate and 60% by weight of sodium nitrate. 5. The method according to claim 1 , wherein the tank is a central tank into which the recirculated heat transfer medium and the heat transfer medium to be delivered to a plurality of pipeline loops are introduced and fully mixed and out of which the pipeline loops are fed. 6. The method according to claim 1 , wherein, in night time operation, the recirculated part of the heat transfer medium is dimensioned such that the mixture, delivered to the pipeline loop, of recirculated heat transfer medium and of delivered heat transfer medium has a temperature which lies at most 20% of the temperature value in ° C. above the solidification temperature. 7. The method according to claim 1 , wherein the linearly concentrating power plant comprises a solar array in which a heat transfer medium is heated by incident solar radiation and said solar array comprises a plurality of series-connected receivers, through which the heat transfer medium is conducted. 8. A linearly concentrating solar power plant with at least one pipeline loop having at least one receiver in which a heat transfer medium flowing through the pipeline loop is heated by irradiating solar energy, the at least one pipeline loop configured to carry hot heat transfer medium from the at least one receiver and cold heat transfer medium to the at least one receiver, wherein a tank is connected to the pipeline loop and the tank is configured as a mixing device, wherein at least part of the hot heat transfer medium, upon exit from the pipeline loop, is extracted and is recirculated into the pipeline loop, wherein that part of the heat transfer medium which is recirculated into the pipeline loop is mixed in the tank, before introduction into the pipeline loop, with cold heat transfer medium delivered to the pipeline loop, wherein the tank which is also configured as an emptying tank, the tank volume being sized such that, in addition to being used for mixing, the total volume of heat transfer medium contained in the pipeline loop can flow out into the emptying tank. 9. The linearly concentrating solar power plant according to claim 8 , wherein the solar power plant comprises a multiplicity of pipeline loops, and the tank is provided as a central tank, into which the heat transfer medium to be recirculated from the pipeline loops and the heat transfer medium to be delivered into the pipeline loops are introduced and out of which the mixture of recirculated heat transfer medium and of heat transfer medium to be delivered is fed into the pipeline loops and the linearly concentrating solar power plant is a parabolic trough solar power plant or a Fresnel power plant. 10. The linearly concentrating solar power plant according to claim 8 , wherein the heat transfer medium is extracted out of the tank by means of an immersion pipe. 11. The linearly concentrating solar power plant according to claim 8 , wherein the linearly concentrating power plant comprises a solar array in which a heat transfer medium is heated by incident solar radiation and said solar array comprises a plurality of series-connected receivers, through which the heat transfer medium is conducted.