Heat transfer device

The invention claimed is: 1. A device for heat transfer, comprising a low temperature heat exchanger ( 3 ) and a high temperature heat exchanger ( 5 ), the heat exchangers ( 3 , 5 ) being connected to one another by means of a connecting line such that a heat transfer medium flows through the high temperature heat exchanger ( 5 ) and through the low temperature heat exchanger ( 3 ) in succession, wherein at least one dwell time tank ( 19 ) is arranged in the connecting line, and wherein the low-temperature heat exchanger ( 3 ) is an evaporator and the high temperature heat exchanger ( 5 ) is a super heater. 2. The device as claimed in claim 1 , wherein the high temperature heat exchanger ( 5 ) and the low temperature heat exchanger ( 3 ) in each case form a section of one heat exchanger, and the connecting line branches off from the region, through which the heat transfer medium flows, of the low temperature heat exchanger and issues into that region of the high temperature heat exchanger through which the heat transfer medium flows. 3. The device as claimed in claim 2 , wherein the region, through which the heat transfer medium flows, between the low temperature heat exchanger ( 3 ) and the high temperature heat exchanger ( 5 ) has a flow barrier, and the connecting line connects the regions, through which the heat transfer medium flows, of the low temperature heat exchanger ( 3 ) and of the high temperature heat exchanger ( 5 ) to one another, so that the heat transfer medium flows out of the section forming the high temperature heat exchanger ( 5 ), via the connecting line, into the section forming the low temperature heat exchanger ( 3 ) or out of the section forming the low temperature heat exchanger ( 3 ), via the connecting line, into the section forming the high temperature heat exchanger ( 5 ). 4. The device as claimed in claim 1 , wherein the dwell time tank ( 19 ) comprises at least two storage cells ( 25 ), and the individual storage cells ( 25 ) are connected to one another in the direction from the low temperature heat exchanger ( 3 ) to the high temperature heat exchanger ( 5 ) in each case via a connection from the lower region of a first storage cell ( 25 ) to the upper region of an adjacent second storage cell ( 25 ). 5. The device as claimed in claim 4 , wherein the connection between two storage cells ( 25 ) comprises a cell interspace ( 31 ), the connection from the cell interspace ( 31 ) to the upper region of the second storage cell ( 25 ) being formed with an overflow ( 47 ) and that from the cell interspace ( 31 ) to the lower region of the first storage cell ( 25 ) being formed by a partition ( 41 ) with an orifice ( 33 ), so that, in the case of a throughflow of the storage cells ( 25 ) from the high temperature heat exchanger ( 5 ) to the low temperature heat exchanger ( 3 ), the liquid flows in each case through the orifice ( 33 ) in the lower region of the partition ( 41 ) into the cell interspace and via the overflow ( 47 ) out of the cell interspace ( 31 ) into the second storage cell ( 25 ) or, in the case of a flow in the opposite direction, flows via the overflow ( 47 ) into the cell interspace ( 31 ) and through the orifice ( 33 ) in the lower region of the partition ( 41 ) out of the cell interspace ( 41 ) into the first storage cell ( 25 ). 6. The device as claimed in claim 4 , wherein at least one storage cell ( 25 ) is closed by means of a cover ( 51 ), so that a gas space ( 49 ) is formed between the liquid in the storage cell ( 25 ) and the cover ( 51 ). 7. The device as claimed in claim 6 , wherein a pipeline ( 53 ) branches off from at least one gas space ( 49 ) and is immersed into the liquid of a storage cell ( 25 ) positioned nearer to the low temperature heat exchanger ( 3 ) or into the liquid in the connection of two adjacent storage cells ( 25 ), at least one of the adjacent storage cells ( 25 ) having a lower temperature than the temperature of the storage cell ( 25 ) from the gas space ( 49 ) of which the pipeline ( 53 ) branches off. 8. The device as claimed in claim 7 , wherein, in addition, a pipeline branches off from at least one gas space ( 49 ) of a storage cell ( 25 ) and is immersed into the liquid of a storage cell ( 25 ) which is positioned nearer to the high temperature heat exchanger ( 5 ). 9. The device as claimed in claim 4 , wherein all the storage cells ( 25 ) are closed by means of a cover ( 51 ), and a pipeline ( 53 ) branches off at the cover ( 51 ) from all the storage cells ( 25 ), apart from that positioned nearest to the low temperature heat exchanger ( 3 ), and issues in the adjacent storage cell ( 25 ) positioned nearer to the low temperature heat exchanger ( 3 ) or in the connection of the storage cell ( 25 ) to the adjacent storage cell ( 25 ) which is positioned nearer to the low temperature heat exchanger ( 3 ), and a gas outlet ( 55 ) branches off from the cover ( 51 ) of the storage cell ( 25 ) which is positioned nearest to the low temperature heat exchanger ( 3 ). 10. The device as claimed in claim 4 , wherein all the storage cells ( 25 ) are closed by means of a cover ( 51 ), and a pipeline branches off out of the cover ( 51 ) from all the storage cells ( 25 ), apart from that positioned nearest to the high temperature heat exchanger ( 5 ), and is immersed into the liquid of the adjacent storage cell ( 25 ) which is positioned nearer to the high temperature heat exchanger ( 5 ). 11. The device as claimed in claim 7 , wherein, at least one end, immersed into the liquid, of the pipeline ( 53 ), a gas distributor is formed, by means of which gas flowing through the pipeline ( 53 ) is distributed in the form of small bubbles in the liquid. 12. The device as claimed in claim 7 , wherein the pipelines ( 53 ) branching off from the cover ( 51 ) are immersed at least into the lower third of the liquid when the storage cell ( 25 ) is filled as far as the overflow ( 47 ). 13. The device as claimed in claim 7 , wherein a compressor, by means of which the gas is transported into the liquid of the adjacent storage cell ( 25 ) or into the cell interspace ( 31 ), is accommodated in the pipeline ( 53 ). 14. The device as claimed in claim 4 , wherein a device for conveying the liquid is arranged in the connection between two adjacent storage cells ( 25 ). 15. The device as claimed in claim 1 , wherein an adding point for a regeneration catalyst ( 75 ) is positioned upstream of a dwell time tank ( 19 ). 16. The device as claimed in claim 15 , wherein a control unit or regulating unit is comprised, by means of which the addition of the regeneration catalyst is controlled and/or regulated. 17. The device as claimed in claim 1 , wherein the heat transfer medium is a molten salt. 18. The device as claimed in claim 17 , wherein the regeneration catalyst is water. 19. A solar power plant comprising the device as claimed in claim 1 as an evaporator and superheater.