Solar thermal power system

The invention claimed is: 1. A solar thermal power system, comprising: a solar receiver; a thermal energy storage arrangement including a thermal energy storage fluid circulated through the solar receiver to store thermal energy in the thermal energy storage fluid, the thermal energy storage arrangement further comprising: a first storage tank to store relatively hot thermal energy storage fluid and, a second storage tank to store relatively cold thermal energy storage fluid, a multistage steam turbine, operable using a variable pressure steam generated by a primary steam generator arrangement using thermal energy stored in the thermal energy storage fluid, for driving an electrical generator to produce electrical power; the primary steam generator arrangement supplying a high pressure steam of a desired pressure, produced from the thermal energy stored in the thermal energy storage fluid, to a high pressure turbine inlet of the multistage steam turbine, for steam exit from the multistage steam turbine at a turbine stage downstream of a high pressure turbine outlet; a secondary steam generator arrangement having a reheat assembly and operated in parallel with the primary steam generator arrangement, with the secondary steam generator arrangement supplying an intermediate pressure steam, produced from thermal energy stored in the thermal energy storage fluid received from the thermal energy storage arrangement through the reheat assembly of the secondary steam generator, with the intermediate pressure steam and the steam exiting from the turbine stage downstream of the high pressure turbine outlet, both, mixing prior to supply to the reheat assembly for heating and supply to an intermediate pressure turbine inlet of the multistage steam turbine; and wherein relatively hot thermal energy storage fluid results in relatively cold thermal energy storage fluid upon use of the thermal energy stored in the relatively hot thermal energy storage fluid in the primary steam generator arrangement to generate the high pressure steam, with the resultant relatively cold thermal energy storage fluid directly supplied to the second storage tank from the primary steam generator arrangement. 2. The solar thermal power system as claimed in claim 1 , wherein the thermal energy storage arrangement supplies the relatively cold thermal energy storage fluid from the second storage tank to the solar receiver for heating. 3. The solar thermal power system as claimed in claim 1 , wherein the primary steam generator arrangement is operable to receive relatively hot thermal energy storage fluid from a first storage tank for use to generate the high pressure steam of the desired pressure for supply to the high pressure turbine inlet of the multistage steam turbine. 4. The solar thermal power system as claimed in claim 1 , wherein the secondary steam generator arrangement is operable to receive relatively hot thermal energy storage fluid from the first storage tank through the reheat assembly for use to generate an intermediate pressure steam. 5. The solar thermal power system as claimed in claim 1 , wherein relatively hot thermal energy storage fluid results in relatively cold thermal energy storage fluid upon use of the thermal energy stored in the relatively hot thermal energy storage fluid in the secondary steam generator arrangement to generate the intermediate pressure steam, with the resultant relatively cold thermal energy storage fluid directly supplied to the second storage tank from the secondary steam generator arrangement. 6. The solar thermal power system as claimed in claim 1 , wherein the primary steam generator arrangement comprises a high pressure economizer, a high pressure evaporator and a superheater communicably configured to utilize the thermal energy stored in the relatively hot thermal energy storage fluid received from the first storage tank to generate the high pressure steam of the desired pressure. 7. The solar thermal power system as claimed in claim 1 , wherein the secondary steam generator arrangement comprises an intermediate pressure economizer, an intermediate pressure evaporator and a superheater communicably configured to utilize the thermal energy stored in the relatively hot thermal energy storage fluid received from the first storage tank through the reheat assembly to generate the intermediate pressure steam. 8. The solar thermal power system as claimed in claim 1 , wherein the steam from an intermediate pressure turbine outlet is supplied to a low pressure turbine inlet of the multistage steam turbine. 9. The solar thermal power system as claimed in claim 1 further comprising a conditioning arrangement for conditioning the steam exiting from the multistage steam turbine, wherein the conditioning arrangement comprises: a condenser to condense the steam exiting from the multistage turbine to obtain water; low and high pressure heater arrangements configured to heat the water supplied to the low and high pressure heater arrangements by the condenser; and a feed water supply operable to supply high pressure feed-water to the primary and secondary steam generator arrangements. 10. A solar thermal power system, comprising: a solar receiver; a thermal energy storage arrangement including a thermal energy storage fluid circulated through the solar receiver to store thermal energy in the thermal energy storage fluid, the thermal energy storage arrangement further including, a first storage tank to store relatively hot thermal energy storage fluid and, a second storage tank to store relatively cold thermal energy storage fluid, for thermal energy storage arrangement supply of the relatively cold thermal energy storage fluid from the second storage tank to the solar receiver for heating; a multistage steam turbine, operable using variable pressure steams generated using thermal energy stored in the thermal energy storage fluid, for driving an electrical generator to produce electrical power, wherein the multistage steam turbine is operable using variable pressure steams generated by, a primary steam generator arrangement supplied the relatively hot thermal energy storage fluid from the first storage tank for use to generate a high pressure steam of a desired pressure for supply to a high pressure turbine inlet of the multistage steam turbine, for steam exit from a turbine stage downstream of a high pressure turbine outlet; a secondary steam generator arrangement having a reheat assembly and operated in parallel with the primary steam generator arrangement, with the secondary steam generator arrangement supplied the relatively hot thermal energy storage fluid from the first storage tank through the reheat assembly for use to generate an intermediate pressure steam, the intermediate pressure steam and the steam exiting the turbine stage downstream of the high pressure turbine outlet, both, mixing for supply to the reheat assembly for heating prior to supply to an intermediate pressure turbine inlet of the multistage steam; and wherein relatively hot thermal energy storage fluid results in relatively cold thermal energy storage fluid upon use of the thermal energy stored in the thermal energy storage fluid by the primary steam generator arrangement to generate the high pressure steam, with the resultant relatively cold thermal energy storage fluid directly supplied to the second storage tank from the primary steam generator arrangement. 11. The solar thermal power system as claimed in claim 10 , wherein relatively hot thermal energy storage fluid results in relatively cold thermal energy storage fluid upon use of the thermal energy stored in the thermal energy storage fluid by the seconda