Abstract: Disclosed illustrative embodiments include systems and methods for power peaking with energy storage. In an illustrative, non-limiting embodiment, a power plant includes a thermodynamic piping circuit having a working fluid contained therein, and the working fluid has a flow direction and a flow rate. Power plant components are interposed in the thermodynamic piping circuit. The power plant components include a compressor system, a recuperator system, a heat source, a turbine system, a heat rejection system, and a thermal energy storage system. A valving system is operable to selectively couple the heat rejection system, the thermal energy storage system, and the compressor system in thermohydraulic communication with the working fluid maintaining the flow direction and the flow rate to implement a thermodynamic cycle chosen from a Brayton cycle, a combination Brayton cycle/refrigeration cycle, and a Rankine cycle.
Abstract: Disclosed illustrative embodiments include systems and methods for power peaking with energy storage. In an illustrative, non-limiting embodiment, a power plant includes a thermodynamic piping circuit having a working fluid contained therein, and the working fluid has a flow direction and a flow rate. Power plant components are interposed in the thermodynamic piping circuit. The power plant components include a compressor system, a recuperator system, a heat source, a turbine system, a heat rejection system, and a thermal energy storage system. A valving system is operable to selectively couple the heat rejection system, the thermal energy storage system, and the compressor system in thermohydraulic communication with the working fluid maintaining the flow direction and the flow rate to implement a thermodynamic cycle chosen from a Brayton cycle, a combination Brayton cycle/refrigeration cycle, and a Rankine cycle.
Abstract: Disclosed illustrative embodiments include systems for part load control of electrical power generating systems and methods of operating a system for part load control of electrical power generating systems. A representative system includes a computer controller system operatively coupled to an electrical power generator and programmed to control a compressor inlet pressure responsive to a level of electrical power output requested of the electrical power generator, and a reservoir with supercritical fluid, responsive to the computer controller system and in fluid communication with the electrical power generating system between a compressor outlet and an expander inlet, and between an expander outlet and a compressor inlet.
Abstract: Disclosed illustrative embodiments include modular power infrastructure networks, distributed electrical power infrastructure networks, methods for operating a modular power infrastructure network, and methods for fabricating a modular power infrastructure network.
Type:
Grant
Filed:
March 15, 2013
Date of Patent:
May 19, 2015
Assignee:
SuperCritical Technologies, Inc.
Inventors:
Chal S. Davidson, Joshua C. Walter, Steven A. Wright
Abstract: Disclosed illustrative embodiments include modular power infrastructure networks, distributed electrical power infrastructure networks, methods for operating a modular power infrastructure network, and methods for fabricating a modular power infrastructure network.
Type:
Grant
Filed:
March 15, 2013
Date of Patent:
September 2, 2014
Assignee:
SuperCritical Technologies, Inc.
Inventors:
Chal S. Davidson, Steven A. Wright, Robert L. Fuller
Abstract: Disclosed illustrative embodiments include modular power infrastructure networks, distributed electrical power infrastructure networks, methods for operating a modular power infrastructure network, and methods for fabricating a modular power infrastructure network.