Method and apparatus for generating electricity using a nuclear power plant

The invention claimed is: 1. A method for the generation of electricity by means of a nuclear power plant, and a liquid vaporization apparatus, the method comprising the steps of: a) producing thermal energy by means of the nuclear power plant, and the thermal energy is used to vaporize water or to heat water vapor, the water vapor formed is expanded in a first turbine, and the first turbine is used to drive an electricity generator for the production of electricity; b) vaporizing a cryogenic liquid sourced from a cryogenic storage facility to produce a pressurized gas; c) heating the pressurized gas to form a heated pressurized fluid; and d) expanding the heated pressurized fluid in a second turbine for the production of electricity wherein in step c) to heat the pressurized gas, a proportion of the thermal energy produced in step a) is used for the heating of the pressurized gas, by employing a proportion of the water vapor to be delivered to the first turbine of the nuclear power plant, or a proportion of the heat of the water vapor to be delivered to the first turbine of the nuclear power plant for the heating of the pressurized gas, wherein the proportion of the thermal energy used for heating of the pressurized gas is no more than 30% of the thermal energy produced. 2. The method as claimed in claim 1 , wherein the only gas which expands in the second turbine is the heated pressurized fluid. 3. A method for the generation of electricity and the storage of energy, wherein: i) during a first period, the method comprises the steps as claimed in claim 1 , ii) during a second period: a) producing thermal energy by means of the nuclear power plant and using the thermal energy to generate electricity; b) using electrical and/or mechanical energy generated by the power plant to produce the cryogenic liquid, and c) storing the cryogenic liquid in the cryogenic storage facility. 4. The method as claimed in claim 3 , wherein the second period corresponds to a period of lower electricity demand and/or a period in which the electricity price is lower than in the first period. 5. The method as claimed in claim 3 , wherein, during the second period, the first turbine generates electricity, which is used to produce the cryogenic liquid. 6. The method as claimed in claim 3 , wherein, during the first period, no cryogenic liquid is produced or added to the cryogenic storage facility. 7. The method as claimed in claim 3 , wherein, during the second period, the cryogenic liquid sourced from the cryogenic storage facility is not vaporized. 8. The method as claimed in claim 3 , wherein, during the second period, the heated pressurized fluid is not expanded in the second turbine. 9. The method as claimed in claim 3 , wherein the cryogenic liquid is selected from the group consisting of liquefied air, liquefied atmospheric gases, and combinations thereof. 10. An integrated electricity generating apparatus, comprising: a nuclear power plant having a steam turbine that is configured to drive a first electrical generator; a liquefaction unit in electrical communication with the first electrical generator, such that the liquefaction unit can receive electricity from the first electrical generator; a cryogenic liquid storage facility in fluid communication with the liquefaction unit; a vaporization unit in fluid communication with the cryogenic liquid storage facility; a heat exchanger configured to heat a cryogenic liquid sourced from the cryogenic liquid storage facility against hot gases sourced from the nuclear power plant; and a second turbine configured to receive a vaporized fluid from a means for preheating the cryogenic liquid, wherein the second turbine is configured to drive a second electrical generator, wherein the cryogenic liquid is selected from the group consisting of liquefied air, liquefied atmospheric gases, and combinations thereof. 11. A method for the generation of electricity and the storage of energy, the method comprising a first period and a second period, A) wherein the first period comprises the steps of: producing thermal energy using a nuclear power plant; vaporizing a cryogenic liquid sourced from a cryogenic liquid storage facility to form a pressurized gas; using a first proportion of the thermal energy from the nuclear power plant to create steam that is then expanded in a first turbine, wherein the first turbine is used to drive an electricity generator for the production of electricity; using a second proportion of the thermal energy from the nuclear power plant to heat the pressurized gas; and expanding the pressurized gas in a second turbine for the production of electricity, B) wherein the second period comprises the steps of: producing thermal energy by means of the nuclear power plant, and using the thermal energy to generate electricity; using electrical and/or mechanical energy generated by the nuclear power plant to produce the cryogenic liquid; and storing the cryogenic liquid in the cryogenic storage facility, wherein the cryogenic liquid is selected from the group consisting of liquefied air, liquefied atmospheric gases, and combinations thereof. 12. The method as claimed in claim 11 , wherein the second proportion of the thermal energy constitutes no more than 30% of the thermal energy produced by the nuclear power plant. 13. The method as claimed in claim 11 , wherein the step of using electrical and/or mechanical energy generated by the nuclear power plant to produce the cryogenic liquid further comprises the step of sending electricity to an air liquefaction facility configured to liquefy atmospheric air.