Steam power plant with heat reservoir and method for operating a steam power plant

The invention claimed is: 1. A steam power plant comprising: a steam generator; a low-pressure turbine receiving steam from the steam generator to drive the turbine; a condenser to condense steam received from the low-pressure turbine to provide a condensate; at least one low-pressure preheater receiving the condensate from the condenser via a condensate line to heat the condensate by steam from the low pressure turbine; a heat reservoir receiving the condensate from the condenser to store the condensate, wherein the heat reservoir is fluidly arranged in parallel to the at least one low-pressure preheater; a feed water container receiving the condensate from the at least one low-pressure preheater via the condensate line and the heat reservoir; and a heat exchanger fluidly arranged to receive the condensate from at least one of the heat reservoir, the at least one low-pressure turbine and the feed water container to heat the condensate to provide heated condensate to the heat reservoir, wherein the heat exchanger uses heated fluid to heat the condensate and wherein the heat exchanger is fluidly arranged in parallel to the at least one low-pressure preheater, and wherein the lower portion of the heat reservoir is fluidly connected to the heat exchanger, fluidly connected to the low-pressure preheater, and fluidly connected to the feed water container. 2. The steam power plant according to claim 1 , wherein the heat exchanger uses steam from the turbine, steam from the steam generator, or auxiliary steam for heating the condensate. 3. The steam power plant according to the claim 1 , wherein the condenser is fluidly connected to the lower portion of the heat reservoir. 4. The steam power plant according to claim 1 , wherein the upper portion of the heat reservoir is fluidly connected to the heat exchanger. 5. The steam power plant according to claim 1 , wherein the heat exchanger is supplied with the steam by a steam supply line. 6. The steam power plant according to claim 1 , further comprising a bypass installed fluidly in parallel to the heat exchanger. 7. The steam power plant according to claim 1 , flintier comprising valves to control the fluid flow between the condenser and the low-pressure preheater, between the condenser and the heat reservoir, between the heat reservoir and the heat exchanger, between the heat exchanger and the feed water container. 8. The steam power plant according to claim 7 , wherein the valves include control valves, shutoff devices and/or choke valves. 9. The steam power plant according to claim 1 , wherein the at least one low-pressure preheater includes a plurality of low-pressure preheaters connected fluidly in series, wherein the heat reservoir is fluidly connected in parallel to one or more of the low-pressure preheaters. 10. A method for operating a steam power plant, the method comprising: condensing steam from a low-pressure turbine upstream of a low-pressure preheater and a heat reservoir to provide a condensate; providing the condensate to the low-pressure preheater and the heat reservoir, wherein the heat reservoir is fluidly connected in parallel with the low-pressure preheater; selectively providing the condensate from the low-pressure preheater and the heat reservoir to a feed water container; and selectively heating, with a heat exchanger using a heated fluid, the condensate provided from at least one of the heat reservoir, the at least one low pressure turbine and the feed water container to provide heated condensate; providing the heated condensate to the heat reservoir, wherein the heat exchanger is fluidly connected in parallel with the low-pressure preheater, bypassing the heat exchanger when providing the condensate from the heat reservoir to the feed water container; blocking the condensate from passing through the at least one low-pressure preheater; discharging the heat reservoir by extracting the heated condensate from the heat reservoir and supplying it downstream of the least one low-pressure preheater bypassing or passing through the heat exchanger; and providing the condensate from upstream of the at east one low-pressure to the heat reservoir. 11. The method according to claim 10 , further comprising: providing preheated condensate downstream of the at least one low-pressure preheater to the heat reservoir through the heat exchanger and recycling the condensate from the heat reservoir back through the heat exchanger. 12. A method for operating a steam power plant, the method comprising: condensing a steam from a low-pressure turbine upstream of a low-pressure preheater and a heat reservoir to provide a condensate; providing the condensate to the low-pressure preheater and the heat reservoir, wherein the heat reservoir is fluidly connected in parallel with the low-pressure preheater; selectively providing the condensate from the low-pressure preheater and the heat reservoir to a feed water container; and selectively heating, with a heat exchanger using a heated fluid, the condensate provided from at least one of the heat reservoir, the at least one low pressure turbine and the feed water container to provide heated condensate; providing the heated condensate to the heat reservoir, wherein the heat exchanger is fluidly connected in parallel with the low-pressure preheater, bypassing the heat exchanger when providing the condensate from the heat reservoir to the feed water container; discharging the heat reservoir by extracting the heated condensate from the heat reservoir and supplying it downstream of the least one low-pressure preheater bypassing the heat exchanger. 13. The method according to claim 10 , further comprising providing the condensate through the at least one low-pressure preheater to the feed water container and circulating the condensate between the heat exchanger and the heat reservoir wherein the exchanger heats the circulating condensate by the heated condensate. 14. A method for operating a steam power plant, the method comprising: condensing steam from a low-pressure turbine upstream of a low-pressure preheater and a heat reservoir to provide a condensate; providing the condensate to the low-pressure preheater and the heat reservoir, wherein the heat reservoir is fluidly connected in parallel with the low-pressure preheater; selectively providing the condensate from the low-pressure preheater and the heat reservoir to a feed water container; and selectively heating with a heat exchanger using a heated fluid, the condensate provided from at least one of the heat reservoir, the at least one low pressure turbine and the feed water container to provide heated condensate; providing the heated condensate to the heat reservoir, wherein the heat exchanger is fluidly connected in parallel with the low-pressure preheater, bypassing the heat exchanger when providing the condensate from the heat reservoir to the feed water container; discharging the heat reservoir by extracting the heated condensate from the heat reservoir and supplying it downstream of the least one low-pressure preheater through the heat exchanger. 15. The method according to claim 10 , further comprising circulating the condensate between the heat exchanger and the heat reservoir wherein the exchanger heats the circulating condensate by the heated condensate. 16. The method according to claim 15 , further comprising selectively blocking the condensate downstream of the low-pressure preheater from fluidly communicating with the heat reservoir or fully communicating with the heat reservoir. 17. The method accordi