Combined cycle gas turbine plant comprising a waste heat steam generator and fuel preheating step

The invention claimed is: 1. A combined cycle power plant comprising: a waste heat steam generator comprising a multiplicity of heating surfaces which are: arranged in an exhaust gas duct of a gas turbine; and wherein the multiplicity of heating surfaces are connected to one another to form a three-stage pressure system, the waste heat steam generator comprising a low-pressure stage, an intermediate-pressure stage and a high-pressure stage for a water-steam circuit of a steam turbine, wherein each of the low-pressure stage, intermediate-pressure stage and high-pressure stage comprises respectively at least one heating surface for preheating, for evaporating, and for superheating, wherein the intermediate-pressure stage is configured to operate on a once-through principle in which an intermediate-pressure evaporator generates steam in a single pass therethrough and without a steam drum, wherein a water-steam separator, which is arranged between an outlet of an evaporator heating surface of the intermediate-pressure evaporator and an inlet of a superheater heating surface of a superheater of the intermediate-pressure stage and in which excess water can be separated from the steam, is provided with a branching-off line for diverting the excess water, wherein the branching-off line is connected to a heat exchanger circuit for preheating fuel for the gas turbine such that a defined quantity of excess water separated in the water-steam separator is introduced into the heat exchanger circuit, and wherein during load operation the combined cycle power plant is configured to feed a water mass flow to the waste heat steam generator such that the evaporator heating surface of the intermediate-pressure stage is oversupplied and thus the defined quantity of excess water, which is heated but not evaporated in the evaporator heating surface, is diverted via the water-steam separator to the heat exchanger circuit for preheating the fuel for the gas turbine. 2. The combined cycle power plant as claimed in claim 1 , wherein the branching-off line comprises a recirculation pump. 3. The combined cycle power plant as claimed in claim 1 , wherein tubes of an intermediate pressure economizer transition directly, with no physical separation, into tubes of the intermediate-pressure evaporator. 4. A method for operating a combined cycle power plant comprising a waste heat steam generator comprising a multiplicity of heating surfaces which are: arranged in an exhaust gas duct of a gas turbine; and wherein the multiplicity of heating surfaces are connected to one another to form a three-stage pressure system, the waste heat steam generator comprising a low-pressure stage, an intermediate-pressure stage and a high-pressure stage for a water-steam circuit of a steam turbine, wherein each of the low-pressure stage, intermediate-pressure stage and high-pressure stage comprises respectively at least one heating surface for preheating, for evaporating, and for superheating, wherein the intermediate-pressure stage is configured to operate on a once-through principle in which an intermediate-pressure evaporator generates steam in a single pass therethrough and without a steam drum, wherein a water-steam separator, which is arranged between an outlet of an evaporator heating surface of the intermediate-pressure evaporator and an inlet of a superheater heating surface of a superheater of the intermediate-pressure stage and in which excess water can be separated from the steam, is provided with a branching-off line for diverting the excess water, wherein the branching-off line is connected to a heat exchanger circuit for preheating fuel for the gas turbine such that a defined quantity of excess water separated in the water-steam separator is introduced into the heat exchanger circuit, the method comprising: during load operation of the combined cycle power plant, feeding a water mass flow to the waste heat steam generator such that the evaporator heating surface of the intermediate-pressure stage is oversupplied and thus the defined quantity of excess water, which is heated but not evaporated in the evaporator heating surface, is diverted via the water-steam separator to the heat exchanger circuit for preheating the fuel for the gas turbine. 5. The method as claimed in claim 4 , wherein a feedwater flow rate is controlled to control the water mass flow, the method further comprising controlling the feedwater flow rate to ensure the defined quantity of excess water is sufficient for preheating the fuel.