Method and device for cooling steam turbine generating facility

The invention claimed is: 1. A cooling method for a steam turbine generating facility comprising an opposed-flow single casing steam turbine which is arranged on a higher pressure side of a low pressure turbine and in which a plurality of turbine parts are housed in a single casing and a dummy seal isolates the plurality of turbine parts from one another, the steam turbine generating facility cooling the dummy seal and a rotor shaft arranged on an inner side of the dummy seal, the method comprising: supplying cooling steam generated in the steam turbine generating facility to a cooling steam supply path formed in the dummy seal, the cooling steam having a temperature lower than a temperature of working steam which has been supplied to each of the plurality of turbine parts of the opposed-flow single casing steam turbine and has passed through a first-stage stator blade, the cooling steam having a pressure which is not less than a pressure of the working steam which has passed through the first-stage stator blade, and cooling the dummy seal and the rotor shaft by introducing the cooling steam to a plurality of clearances formed between the dummy seal and the rotor shaft via the cooling steam supply path and streaming the cooling steam in the clearances against the steam from an exit of the first-stage stator blade, wherein: the opposed-flow single casing steam turbine includes a first turbine part and a second turbine part which are provided symmetrically in the single casing and are driven by the same working steam; the cooling steam supply path is arranged between a steam inlet part of the first turbine part and a steam inlet part of the second turbine part; in said cooling the dummy seal and the rotor shaft, the cooling steam supplied via the cooling steam supply path is configured to branch off, the cooling steam branched off being configured to stream into each of a pair of the clearances arranged symmetrically; the steam turbine generating facility comprises a very-high-pressure turbine, a high pressure turbine which is driven by high pressure steam obtained by reheating discharge steam of the very-high-pressure turbine, an intermediate pressure turbine which is driven by intermediate pressure steam obtained by reheating discharge steam of the high pressure turbine, and the low pressure turbine which is driven by discharge steam of the intermediate pressure turbine; the high pressure turbine is formed as the opposed-flow single casing steam turbine and includes a first high pressure turbine part and a second high pressure turbine part which are provided symmetrically in the single casing; the cooling steam supply path of the high pressure turbine is arranged between a steam inlet part of the first high pressure turbine part and a steam inlet part of the second high pressure turbine part; in said supplying the cooling steam, the discharge steam of the very-high-pressure turbine is configured to be supplied to the cooling steam supply path of the high pressure turbine as the cooling steam; and in said cooling the dummy seal and the rotor shaft, the discharge steam of the very-high-pressure turbine supplied via the cooling steam supply path as the cooling steam is configured to branch off, the discharge steam of the very-high-pressure turbine branched off being configured to stream into each of the pair of the clearances of the high pressure turbine. 2. The cooling method according to claim 1 , wherein the rotor shaft is formed by joining split members which are made of different materials, and wherein a joint section at which the split members are joined to form the rotor shaft is formed facing the clearances, the joint section being cooled by the cooling steam. 3. The cooling method according to claim 1 , wherein: the intermediate pressure turbine is formed as the opposed-flow single casing steam turbine and includes a first intermediate pressure turbine part and a second intermediate pressure turbine part which are provided symmetrically in the single casing; the cooling steam supply path of the intermediate pressure turbine is arranged between a steam inlet part of the first intermediate pressure turbine part and a steam inlet part of the second intermediate pressure turbine part; in said supplying the cooling steam, the discharge steam of the high pressure turbine is configured to be supplied to the cooling steam supply path of the intermediate pressure turbine as the cooling steam; and in said cooling the dummy seal and the rotor shaft, the discharge steam of the high pressure turbine supplied via the cooling steam supply path as the cooling steam is configured to branch off, the discharge steam of the high pressure turbine branched off being configured to stream into each of the pair of the clearances of the intermediate pressure turbine. 4. A cooling device for a steam turbine generating facility comprising an opposed-flow single casing steam turbine which is arranged on a higher pressure side of a low pressure turbine and in which a plurality of turbine parts are housed in a single casing and a dummy seal isolates the plurality of turbine parts from one another, the steam turbine generating facility cooling the dummy seal and a rotor shaft arranged on an inner side of the dummy seal, the device comprising: a cooling steam supply path formed in the dummy seal and configured to open to a plurality of clearances between the dummy seal and the rotor shaft; and a cooling steam pipe connected to the cooling steam supply path so as to supply cooling steam generated in the steam turbine generating facility to the cooling steam supply path at a temperature lower than that of working steam which has been supplied to each of the plurality of turbine parts of the opposed-flow single casing steam turbine and has passed through a first-stage stator blade and at a pressure not less than the pressure of the working steam at an exit of the first-stage stator blade, wherein: the cooling steam is configured to stream into the clearances between the dummy seal and the rotor shaft via the cooling steam supply path to cool the dummy seal and the rotor shaft; the opposed-flow single casing steam turbine includes a first turbine part and a second turbine part which are provided symmetrically in the single casing and are driven by the same working steam; the cooling steam supply path is arranged between a steam inlet part of the first turbine part and a steam inlet part of the second turbine part; the cooling steam supplied via the cooling steam supply path branches off, the cooling steam branched off streaming into each of a pair of the clearances arranged symmetrically; the steam turbine generating facility comprises a very-high-pressure turbine, a high pressure turbine which is driven by high pressure steam obtained by reheating discharge steam of the very-high-pressure turbine, an intermediate pressure turbine which is driven by intermediate pressure steam obtained by reheating discharge steam of the high pressure turbine, and the low pressure turbine which is driven by discharge steam of the intermediate pressure turbine; the high pressure turbine is formed as the opposed-flow single casing steam turbine and includes a first high pressure turbine part and a second high pressure turbine part which are provided symmetrically in the single casing; the cooling steam supply path of the high pressure turbine is arranged between a steam inlet part of the first high pressure turbine part and a steam inlet part of the second high pressure turbine part; the discharge steam of the very-high-pressure turbine is configured to be supplied to the cooling steam supply path of the high pressure turbine as the cooling steam; and the discharge steam of the very-high-pressure turbine supplied via the cooling steam supply path as the cooling steam