A system for heating one or more components of a heat recovery steam generator that includes a heat-transferring conduit that fluidly connects a high-pressure section of a flow path to a low-pressure section of the flow path. The flow path is defined by a housing of the heat recovery steam generator and configured to direct a heat-containing medium. The heat-transferring conduit is configured to receive the heat-containing medium from the flow path such that the heat-containing medium flows through the heat-transferring conduit via a pressure differential between a first pressure of the heat-containing medium at the high-pressure section and a second pressure of the heat-containing medium at the low-pressure section. The heat-transferring conduit is further configured to heat the one or more components of the heat recovery steam generator via directing the heat-containing medium to be in heating contact with the one or more components.

A steam turbine plant of the present invention includes a heat source device that heats a low temperature fluid by a heat source medium to obtain a high temperature fluid, a steam generating device that generates steam by heat exchange with the high temperature fluid, a steam turbine that is driven by the steam, a heating flow path that is disposed on an outer surface of a casing of the steam turbine, a high temperature fluid supply passage that is branched from a flow path of the high temperature fluid in the steam generating device, is connected to the heating flow path, and supplies the high temperature fluid to the heating flow path, and a high temperature fluid flow rate regulating device that regulates a flow rate of the high temperature fluid flowing through the high temperature fluid supply passage.

This steam turbine is provided with: a steam turbine rotor which extends in an axial direction; a pair of bearings which support the steam turbine rotor in such a way as to be capable of rotating about the axial direction; a steam turbine casing which encloses the steam turbine rotor between the pair of bearings; a casing support unit which supports the steam turbine casing from below; and a first heating unit: which is provided on the casing support unit and which is capable of heating the casing support unit.

An induction heater is employed with a gas turbine engine in order to heat a static component of the gas turbine engine. The heating of the static component is performed such that the clearance space between the static component and a rotating component remains constant during steady state conditions and transient conditions.

A steam turbine plant and an operating method thereof, and a combined cycle plant and an operating method thereof, include: a turbine; steam supply lines that supply main steam to the turbine; a steam control valve and an intercept valve provided to the steam supply lines; and a first auxiliary steam supply line that supplies auxiliary steam to the turbine via the steam supply lines which are located farther downstream than the steam control valve and the intercept valve.

This steam turbine blade is provided with: a blade body (61) extending in a radial direction and having an airfoil profile in a cross section perpendicular to the radial direction; and a heater (H) including a heating wire disposed so as to extend along a trailing edge (Er) of the airfoil profile in the blade body (61). This configuration makes it possible to further mitigate an efficiency drop due to moisture attached to the surface of the steam turbine blade (60).

A thermal management system includes a heat exchanger defining a confined volume for thermal transfer between a first flow within a first passage and a second flow within a second passage. A first conduit outside the confined volume communicates the first flow to the first passage of the heat exchanger. A thermal transfer augmenter is attached to the first conduit.

A thermal management system includes a heat exchanger defining a confined volume for thermal transfer between a first flow within a first passage and a second flow within a second passage. A first conduit outside the confined volume communicates the first flow to the first passage of the heat exchanger. A thermal transfer augmenter is attached to the first conduit.

An additively manufactured impingement structure for a component is provided. The control structure includes an impingement wall positioned between an outer wall and an inner wall, a plurality of impingement holes defined in the impingement wall, the impingement holes providing fluid communication from a fluid distribution passageway, the impingement holes defined in the impingement wall at an apex of one or more support struts, the one or more support struts defining a plurality of domed structures, each of the plurality of domed structures including a hemisphere-like shape, and a discharge housing defining a discharge plenum and a plurality of discharge ports, the discharge plenum being in fluid communication with an impingement gap, the impingement gap defined between the impingement wall and the outer wall.

An additively manufactured impingement structure for a component is provided. The control structure includes an impingement wall positioned between an outer wall and an inner wall, a plurality of impingement holes defined in the impingement wall, the impingement holes providing fluid communication from a fluid distribution passageway, the impingement holes defined in the impingement wall at an apex of one or more support struts, the one or more support struts defining a plurality of domed structures, each of the plurality of domed structures including a hemisphere-like shape, and a discharge housing defining a discharge plenum and a plurality of discharge ports, the discharge plenum being in fluid communication with an impingement gap, the impingement gap defined between the impingement wall and the outer wall.