A method, approach, system, apparatus and solution that generates electricity from the removal heat of sustainable thermal cycles combined with a renewable thermal energy source.

A convection-driven power generator comprising a flow intake configured to supply fluid to the generator, a flow duct having a duct inlet and a duct outlet wherein the duct outlet is spaced downstream from the duct inlet along the flow duct, the duct inlet being fluidly coupled to the flow intake. A heating chamber fluidly is coupled to the duct outlet so as to receive fluid from the duct outlet, the heating chamber comprising an external wall configured to transmit light radiation incident thereon such that fluid within the heating chamber is heated by the transmitted light radiation. A flow exhaust is fluidly coupled to the heating chamber and configured to exhaust fluid heated by the heating chamber from the heating chamber. A turbine is arranged within the flow duct, downstream of the flow intake, and exposed to fluid flow through the flow duct such that when fluid flows through the flow duct the turbine is caused to rotate by the fluid flow; and at least one lens element is configured to focus the light radiation transmitted by the external wall within the heating chamber.

A convection-driven power generator comprising a flow intake configured to supply fluid to the generator, a flow duct having a duct inlet and a duct outlet wherein the duct outlet is spaced downstream from the duct inlet along the flow duct, the duct inlet being fluidly coupled to the flow intake. A heating chamber fluidly is coupled to the duct outlet so as to receive fluid from the duct outlet, the heating chamber comprising an external wall configured to transmit light radiation incident thereon such that fluid within the heating chamber is heated by the transmitted light radiation. A flow exhaust is fluidly coupled to the heating chamber and configured to exhaust fluid heated by the heating chamber from the heating chamber. A turbine is arranged within the flow duct, downstream of the flow intake, and exposed to fluid flow through the flow duct such that when fluid flows through the flow duct the turbine is caused to rotate by the fluid flow; and at least one lens element is configured to focus the light radiation transmitted by the external wall within the heating chamber.

A downdraft-tornado-wind-chimney and a updraft-tornado-wind-chimney create the compressed-and-high-velocity-air for a rotating-turbine. A photovoltaic-powered-blower and a high-temperature-solar-collectors create the compressed-and-high-velocity-air. A downdraft-tornado-wind-chimney inject the compressed-and-high-velocity-air into a photovoltaic-powered-blower, a high-temperature-solar-collectors and a rotating-turbine. A updraft-tornado-wind-chimney extract the compressed-and-high-velocity-air from a photovoltaic-powered-blower, a high-temperature-solar-collectors and a rotating-turbine. The combination of the updraft-tornado-wind-chimney, a downdraft-tornado-wind-chimney, a photovoltaic-powered-blower, and a high-temperature-solar-collectors drive a rotating-turbine.

A downdraft-tornado-wind-chimney and a updraft-tornado-wind-chimney create the compressed-and-high-velocity-air for a rotating-turbine. A photovoltaic-powered-blower and a high-temperature-solar-collectors create the compressed-and-high-velocity-air. A downdraft-tornado-wind-chimney inject the compressed-and-high-velocity-air into a photovoltaic-powered-blower, a high-temperature-solar-collectors and a rotating-turbine. A updraft-tornado-wind-chimney extract the compressed-and-high-velocity-air from a photovoltaic-powered-blower, a high-temperature-solar-collectors and a rotating-turbine. The combination of the updraft-tornado-wind-chimney, a downdraft-tornado-wind-chimney, a photovoltaic-powered-blower, and a high-temperature-solar-collectors drive a rotating-turbine.

Methods and apparatus, for generating electricity from airflow and thermal energy. In one aspect, an electricity generating apparatus includes a housing including a double-walled section containing a thermal salt to store heat and form a pressure chamber within the housing, a collector coupled with the housing and including two or more inlet channels configured to direct ambient air into the pressure chamber, and a nozzle coupled with the housing configured to direct a convection current of air into the pressure chamber, and a turbine including a rotor and a stator to generate electricity from air flow through the pressure chamber, the rotor having an aerodynamic rotor case and convergent blades and the stator having an aerodynamic stator case and divergent blades, and where the double-walled section containing the thermal salt surrounds at least a portion of the collector and surrounds a portion of the turbine.

A bladeless fluid/vapor includes: (a) three or more turbine discs disposed within a case, wherein each turbine disc has a center opening, a first set of holes substantially equally spaced from one another along a first radius, a second set of holes substantially equally spaced from one another along a second radius, and two or more of the turbine discs have a set of exhaust ports positioned annularly around the center opening; (b) the case includes a main housing, a cover and one or more fluid/vapor inlets oriented to direct a fluid/vapor onto an outer portion of the turbine discs; (c) a drive shaft passing through the center openings of the turbine discs and attached to the turbine discs; (d) a fluid/vapor outlet in the cover; and (e) a set of exhaust holes proximate to and connected to the fluid/vapor outlet that are positioned annularly around the drive shaft.

A bladeless fluid/vapor includes: (a) three or more turbine discs disposed within a case, wherein each turbine disc has a center opening, a first set of holes substantially equally spaced from one another along a first radius, a second set of holes substantially equally spaced from one another along a second radius, and two or more of the turbine discs have a set of exhaust ports positioned annularly around the center opening; (b) the case includes a main housing, a cover and one or more fluid/vapor inlets oriented to direct a fluid/vapor onto an outer portion of the turbine discs; (c) a drive shaft passing through the center openings of the turbine discs and attached to the turbine discs; (d) a fluid/vapor outlet in the cover; and (e) a set of exhaust holes proximate to and connected to the fluid/vapor outlet that are positioned annularly around the drive shaft.

A turbine (1) with flow diverter (2) comprises a support frame (25) adapted to be anchored to a fixed or movable structure, an impeller (3) rotatably mounted about a rotation axis (R) to the support frame (25) and having a front inlet section for the flow and a plurality of blades (4, 4′, 4″, . . . ) adapted to move continuously upon the rotation produced by the flow between a pushing position and an advancing position in correspondence of the front section, a main flow diverter (2) adapted to be anchored to the support frame (25) and having a peripheral wall (7) adapted to at least partially blind the front section with respect to the flow auxiliary diverter (13) extending from a first section (14) facing one or more blades (4′) in the advancing position to a second section (15) facing one or more blades (4) in pushing position. The auxiliary diverter (13) comprises a plurality of substantially curvilinear conduits (16) in reciprocal side by side position along a substantially radial direction, each conduit (16) having a first opened end (16′) facing the blades (4′) in the advancing position and a second opened. end (16″, 16′″) placed in correspondence of the conveying duet (8).

Disclosed are systems and methods for pump control of a closed thermodynamic cycle system, such as a Brayton cycle. Operational parameters such as working fluid temperature, thermal fluid temperature, stream pressure, and power generation may be the basis for controlling a thermal fluid pump rate.