Abstract: The invention relates to systems and methods including an energy conversion system for storage and recovery of energy using compressed gas, a source of recovered thermal energy, and a heat-exchange subsystem in fluid communication with the energy conversion system and the source of recovered thermal energy.

Abstract: The invention relates to power generation and energy storage and recovery. In particular, the invention relates to compressed gas energy storage and recovery systems using staged pneumatic conversion systems for providing narrow pressure ranges to a hydraulic motor.

Abstract: A thermodynamic machine including an enclosure containing a working gas and having heat exchange surfaces therein, displacement structure moveable within the enclosure in order to displace the working gas in the enclosure and consecutively place the working gas in contact and out of contact with each of the heat exchange surfaces in order to perform consecutive stages of a thermodynamic cycle; and a mechanical power unit subject to pressure of the working gas, the displacement structure causes consecutive passage of a chamber in front of the different heat exchange surfaces, the chamber containing a quantity of working gas that is essentially constant, at least the majority of which is generally stationary in relation to the displacement structure.

Abstract: An installation and method for the conversion of thermal energy into mechanical energy. The installation includes at least two closed containers, a converter for the conversion of flow energy into mechanical energy, a switching system as well as a supply line, a discharge line and a heat supply system. Each time, the converter is supplied with a fluid under high pressure and temperature from one container and the temperature-reduced fluid is then collected in another container. As soon as the other container is filled and the first container becomes empty, these containers are exchanged or replaced by other containers.

Abstract: Apparatus (10) for storing energy, comprising: compression chamber means (24) for receiving a gas; compression piston means (25) for compressing gas contained in the compression chamber means; first heat storage means (50) for receiving and storing thermal energy from gas compressed by the compression piston means; expansion chamber means (28) for receiving gas after exposure to the first heat storage means; expansion piston means (29) for expanding gas received in the expansion chamber means; and second heat storage means (60) for transferring thermal energy to gas expanded by the expansion piston means. The cycle used by apparatus (10) has two different stages that can be split into separate devices or combined into one device.

Abstract: An apparatus for storing energy includes a compression chamber for receiving a gas, a compression piston for compressing gas contained in the compression chamber, a first heat store for receiving and storing thermal energy from gas compressed by the compression piston, an expansion chamber for receiving gas after exposure to the first heat store, an expansion piston for expanding gas received in the expansion chamber, and a second heat store for transferring thermal energy to gas expanded by the expansion piston. The cycle used by the apparatus has two different stages that can be split into separate devices or combined into one device.

Abstract: The invention relates to systems and methods for rapidly and isothermally expanding gas in a cylinder. The cylinder is used in a staged hydraulic-pneumatic energy conversion system and includes a gas chamber (pneumatic side) and a fluid chamber (hydraulic side) and a piston or other mechanism that separates the gas chamber and fluid chamber while allowing the transfer of force/pressure between each opposing chamber. The gas chamber of the cylinder includes ports that are coupled to a heat transfer subassembly that circulates gas from the pneumatic side and exchanges its heat with a counter flow of ambient temperature fluid from a reservoir or other source.

Abstract: A power plant for burning a fuel in a low pressure combustion chamber to produce electrical power. A first compressor supplies compressed air through a first heat exchanger to add heat to the compressed air. The heated compressed air is passed through a first turbine to drive a first electric generator. The first turbine outlet is passed through a second heat exchanger in series with the first heat exchanger to further heat the compressed air. The compressed air is then passed through a second turbine to drive a second electric generator and produce electric power. The outlet from the second turbine is passed through a first combustor to produce the hot gas flow through the second heat exchanger. The outlet from the second heat exchanger is passed through a second combustor before passing through the first heat exchanger. The outlet from the first heat exchanger is passed through a heat recovery steam generator to generate steam to drive another turbine and another generator.

Abstract: The invention relates to systems and methods for rapidly and isothermally expanding and compressing gas in energy storage and recovery systems that use open-air hydraulic-pneumatic cylinder assemblies, such as an accumulator and an intensifier in communication with a high-pressure gas storage reservoir on a gas-side of the circuits and a combination fluid motor/pump, coupled to a combination electric generator/motor on the fluid side of the circuits. The systems use heat transfer subsystems in communication with at least one of the cylinder assemblies or reservoir to thermally condition the gas being expanded or compressed.

Abstract: An intermediate duct (108) is connected between first and second positive displacement machines (104, 106). An inlet duct (107) is connected to the first positive displacement machine (104). An outlet duct (109) is connected to the second positive displacement machine (106). A heater (102) raises the temperature and pressure of a gaseous working fluid in the intermediate duct (108). There is a kinematic connection (111) between the first and second positive displacement machines (104, 106) and the arrangement is such that, in operation, the first positive displacement machine (104) causes the working fluid to flow through the intermediate duct (108) to the second positive displacement machine (106), the heated working fluid drives the second positive displacement machine (106), and the second positive displacement machine (106) drives the first positive displacement machine (104) via the kinematic connection (111). The positive displacement machines include at least one orbiting piston.

Abstract: The invention relates to systems and methods for rapidly and isothermally expanding and compressing gas in energy storage and recovery systems that use open-air hydraulic-pneumatic cylinder assemblies, such as an accumulator and an intensifier in communication with a high-pressure gas storage reservoir on a gas-side of the circuits and a combination fluid motor/pump, coupled to a combination electric generator/motor on the fluid side of the circuits. The systems use heat transfer subsystems in communication with at least one of the cylinder assemblies or reservoir to thermally condition the gas being expanded or compressed.

Abstract: This invention provides heat engines based on various structures of internal combustion engines, such as a four-stroke piston-type combustion engine, two-stroke piston-type combustion engine, rotary combustion engine, or a free-piston type combustion engine. Said heat engine is provided with at least a heating chamber per piston or rotor, a heat exchanger unit disposed within said heating chamber through which thermal energy is extracted from a heat source and at least a port leading to a working chamber space from said heating chamber, and has a significantly increased heat transfer duration from the heat source to the working fluid within said heating chamber without increasing the number of strokes per power stroke in a cycle. Additionally, said heat engine is provided with an over expansion mechanism in conjunction with a compression means for intake charge.

Abstract: An indirect-fired gas turbine power plant comprises a compressor; a turbine mechanically coupled to the compressor; a furnace; a heat exchanger inside the furnace and fluidly coupled at an inlet end to the compressor and at an outlet end to the turbine; and means for forming a gas barrier around a portion of the heat exchanger to impede combustion products from contacting the heat exchanger. Such means can be a plurality of gas discharge manifolds located around a portion of the heat exchanger. The manifolds can be coupled to heated working gas exhausted by the turbine.

Abstract: A method to pre-heat gas at gas Pressure Reducing Stations. A first step involve providing at least one electrical line heater having a flow path for passage of natural gas through electrical heating elements. A second step involves passing the high pressure cold natural gas stream along electrical heating elements and heating it up before de-pressurization. A third step involves the expansion of the high pressure heated gas in a enclosed vessel that houses a gas expander and power generator. The expansion of the gas generates shaft work which is converted into electrical power by the power generator and the expanded low pressure gas cools the power generator. This process results in the recovery of energy to replace the slipstream of natural that is presently used to pre-heat gas at Pressure Reduction Stations.

Abstract: The invention relates to an arrangement for obtaining electrical energy from low temperature or waste heat. The heat energy is then converted into electrical energy. Two heat exchangers (1, 2) are configured as two pressure vessels and are connected to a gas-pressure machine (4) built into a pressure vessel (3). Process gas is introduced into the heat exchangers (1, 2) at a pressure of 20 to 200 MPa and thereafter, simultaneously, heat is introduced via a flow channel (7) into the heat exchanger (1) and the cold is introduced into the heat exchanger (2) via a flow channel (8).

Abstract: A modified Brayton Cycle Engine employs solar radiation to heat a metal hydride material in a storage unit. Hydrogen driven from the metal hydride material is recombined with the material at a controlled rate in an exothermic reaction for heating a compressible Brayton working fluid for driving a turbine to which an electric generator is coupled for converting solar radiation to electricity. A compressor, also coupled to the turbine, compresses the Brayton working fluid before it is heated by the solar radiation. Heat from a solar MHD generator may also be used to heat the Brayton working fluid.

Abstract: The invention relates to systems and methods for rapidly and isothermally expanding gas in a cylinder. The cylinder is used in a staged hydraulic-pneumatic energy conversion system and includes a gas chamber (pneumatic side) and a fluid chamber (hydraulic side) and a piston or other mechanism that separates the gas chamber and fluid chamber while allowing the transfer of force/pressure between each opposing chamber. The gas chamber of the cylinder includes ports that are coupled to a heat transfer subassembly that circulates gas from the pneumatic side and exchanges its heat with a counter flow of ambient temperature fluid from a reservoir or other source.

Abstract: A high efficiency harmonic engine based on a resonantly reciprocating piston expander that extracts work from heat and pressurizes working fluid in a reciprocating piston compressor. The engine preferably includes harmonic oscillator valves capable of oscillating at a resonant frequency for controlling the flow of working fluid into and out of the expander, and also preferably includes a shunt line connecting an expansion chamber of the expander to a buffer chamber of the expander for minimizing pressure variations in the fluidic circuit of the engine. The engine is especially designed to operate with very high temperature input to the expander and very low temperature input to the compressor, to produce very high thermal conversion efficiency.

Abstract: A gas turbine plant, wherein a plurality of first gas turbines positioned coaxially with compressors and a second gas turbine positioned coaxially with a generator are rotated by a coolant heated by heat energy provided by the fission of a coated particle fuel. A flow in a bypass passage is controlled by controlling the opening of bypass valves of (n?1) in quantity which bypass the first gas turbines on up to (n?1) shafts in starting. Accordingly, the rotational speeds of the first gas turbines on up to (n) shafts are increased to a rated rotational speed in order starting at the initial stage on the upstream side of a high temperature gas-cooled reactor toward the lower stage for each shaft.

Abstract: An HVAC system includes a fluid driven turbine configured to drive a centrifugal compressor and a permanent magnet motor/generator; a battery electrically connected to the permanent magnet motor/generator; and a controller for the battery and the motor/generator. The turbine, compressor and generator are coaxially positioned along a rotatable shaft. The controller is configured to cause the motor/generator to draw electrical power from the battery or to supply electrical power to the battery in order to rotate the shaft at an efficient speed. The motor/generator is configured to supply electrical power to charge the battery when driven by the turbine and is configured to drive the rotation of the compressor when supplied by electrical power from the battery.

Abstract: A novel engine for producing power from a temperature differential with additional benefits of low cost, high efficiency, quiet operation minimal wear of components, and the ability to produce power or cooling from low grade heat sources.

Abstract: A compact heat pump system and a heat pump operation method, which can avoid the occurrence of surging in a compressor at startup of a heat pump and can directly supply vapor of a working medium produced by the compressor to an external heat-utilizing facility. The heat pump system comprises an evaporator for recovering heat of an external heat source to a working medium supplied as liquid water from the exterior via a water feed channel, thereby evaporating the working medium, a compressor for compressing the working medium evaporated in the evaporator and increasing temperature of the evaporated working medium, and a driving unit for giving motive power to drive the compressor.

Abstract: A heat engine enclosing a chamber in housing has two zones maintained at different temperatures. The first zone receives heat energy from an external power source. The second zone is connected to the hot zone by two conduits, such that a fluid (e.g., air, water, or any other gas or liquid) filling the chamber can circulate between the two zones. The expansion of the fluid in the hot zone and the compression of the fluid in the cold zone drive the rotation of the housing to provide a power output. The fluid may be pressurized to enhance efficiency. A cooling fluid provided in a stationary reservoir maintains a preferred operating temperature difference between the hot zone and the cold zone. A heat storage structure containing a fluid with a high heat capacity may be provided as a heat reservoir.

Abstract: A heat energy recovery apparatus include a compressor which has a piston for compressing sucked-in working gas; a heat exchanger which makes the working gas compressed by the compressor absorb heat of high temperature fluid; an expander which has a piston to be moved under pressure by expansion of the heat-absorbed working gas; and an accumulator which stores the working gas compressed by the compressor when required output is low or heat receiving capacity of the working gas is small. The apparatus preferably include a blocking unit which blocks discharge of the working gas from the expander when the heat receiving capacity of the working gas is small and the compressed working gas to the accumulator is being stored.

Abstract: A power plant that burns a dirty fuel like coal to produce a hot gas stream, and directs the hot gas stream into a turbine to produce power. Located between the combustor and the turbine is at least two heat reservoirs that operate in parallel. When a first heat reservoir is being supplied with hot gas stream from the combustor to collect heat therein, the second and parallel heat reservoir is discharging its stored heat into a hot gas stream that leads into the turbine to produce power. When the heat reservoir delivering the hot gas stream to the turbine is low, the gas flow paths are switched such that the heat reservoir with the low heat storage in charged while the near fully charged heat reservoir then delivers heat to drive the turbine.

Abstract: A closed-cycle gas turbine power generator system with a combined cycle system with a neutral gaseous primary motive medium and a secondary phase change medium with a lower pressure sub-system having a counter-rotating compressor module in combination with a counter-rotating gas turbine module, and with a higher pressure sub-system having a counter-rotating compressor module and a counter-rotating gas turbine module wherein the phase change medium in liquid form is injected into the compressor modules during compression of the primary motive medium with the phase change medium changing to a gas to form a compressed gaseous mixture that is heated by the heat source and supplied to the gas turbine module of the higher pressure sub-system for partial expansion and combining with a heated portion of the compressed gaseous mixture from the compressor module for final expansion in the lower pressure gas turbine modules.

Abstract: The invention relates to an apparatus that includes a first heat exchanger for heating a first heat transfer medium in a first form from a first temperature to a second higher temperature to provide an increased pressure gas, a first mechanical device configured to use the increased pressure gas to provide mechanical energy to one or more primary components, and one or more additional mechanical devices configured to use the increased pressure gas to provide mechanical energy to one or more secondary components. The mechanical device produces spent gas, and a conversion device is operably associated with at least one of the mechanical devices to convert the spent gas to the first form for re-use.

Abstract: A combustion turbine power generation system (10) includes a combustion turbine assembly (11) including a main compressor (12) constructed and arranged to receive ambient inlet air, a main expansion turbine (14) operatively associated with the main compressor, combustors (16) constructed and arranged to receive compressed air from the main compressor and to feed the main expansion turbine, and an electric generator (15) associated with the main expansion turbine for generating electric power. A compressed air storage (18) stores compressed air. A heat exchanger (24) is constructed and arranged to receive a source of heat and to receive compressed air from the storage so as to heat compressed air received from the storage. An air expander (28) is associated with the heat exchanger and is constructed and arranged to expand the heated compressed air for producing additional electric power.

Abstract: During operation of a power plant, which basically comprises a gas turbogroup, a compressed air accumulator, an air turbine which is equipped with at least one generator, the compressed air which is extracted from the compressed air accumulator is directed through a heat exchanger which operates on the downstream side of the gas turbogroup, and is thermally conditioned there. This thermally conditioned compressed air then charges the air turbine for producing a quantity of electricity. Furthermore, the power plant is extended by a steam turbine, which in combined operation is operated with steam which is produced from the exhaust gases of the gas turbogroup.

Abstract: An apparatus and method for converting a differential in thermal energy between a first thermal source having a thermal conducting fluid and a second thermal source having a thermal conducting fluid is provided. The apparatus emplys a first vessel and a second vessel. Each of the vessels contain a gas under pressure The vessels contain heat exchanging coils that are connected to the thermal sources by fluid lines. A plurality of cooperating valves regulate the flow of the thermal conducting fluid from the first and second thermal sources to the first and second vessels. The valves alternate between first and second operating positions. In the first position, the valves permit a flow of thermal conducting fluid from the first thermal source to the first vessel and from the second thermal source to the second vessel and prevent a flow of thermal conducting fluid from the first thermal source to the second vessel and from the second thermal source to the first vessel.

Abstract: A steam generator includes a submersible burner compartment with at least one burner subassembly and an associated submersible primary ignition means. The burner subassembly also has an associated infrared primary flame monitoring subassembly. The primary flame monitoring system and primary ignition means are all housed within the burner compartment whereby when the burner compartment is filled with water, the burners are all submerged. The infrared flame monitoring subassembly is electronically coupled to a primary monitoring device and a fuel feed pipe is couple to the burner subassembly. A super heater compartment is coupled to and receives steam exhausted from the burner compartment. The super heater compartment has at least one burner subassembly located therein. An associated submersible secondary ignition means and an associated infrared secondary flame monitoring subassembly are provided for each burner subassembly.

Abstract: A closed cycle recuperator microturbine and an open cycle heat generating system for supplying heat for driving the turbine includes a pair of valves fluidly connected to the compressor inlet and compressor outlet for bleeding air therefrom when the microturbine engine is operating in the lower power operating envelope of the operating conditions of the microturbine engine while the open cycle heat generating system maintains the thermodynamic conditions of the microturbine engine operating substantially a constant value whereby the fuel consumption of the microturbine engine is enhanced during the low power conditions. The microturbine engine serves to power an electric generator and a ECU heater.

Abstract: Heat differential power systems and apparatus for powering liquid cooling systems and/or generating electrical power in a data processing system or a telecommunication system are presented. A number of embodiments are presented. In each embodiment a heat differential power system is implemented which utilizes the heat created a heat-generating component such as a microprocessor within the data processing or telecommunications system and the resulting heat differential created with other parts of the system as power to operate the heat differential power system and convert thermal energy into mechanical and/or electrical energy for powering a liquid cooling system, fans, other electrical components, and/or extending the battery life in a portable data processing or telecommunications system.

Abstract: A system for the control of an indirectly heated gas turbine comprising a primary system of controlling the temperature of heated compressed gas entering the expander, and an independent secondary system which includes a safety valve for instantaneous release of heated compressed gas to the atmosphere. The primary system controls system gas temperature and power output by modulating a flow of unheated compressed gas which bypasses the heat exchanger and mixes with the heated gas leaving the heat exchanger to produce a lower temperature gas entering the expander. The secondary system provides a backup means of overspeed prevention, and includes a safety valve to instantly discharge to the atmosphere hot compressed gas upstream of the expander by being responsive to the speed of the turbine. The safety valve includes a frangible membrane clamped between parallel flanges within the ducting, and further includes a dagger assembly for rupturing the membrane.

Abstract: A waste heat recovery system comprising ducting to which hot gas is communicated, means to supply lower temperature diluent gas to the ducting, to mix with the hot gas, and produce a reduced temperature mixed gas stream, a vaporizer in communication with the ducting, to receive the stream and to transfer heat from the stream to a working fluid in the vaporizer to vaporize said fluid, and a blower operating to displace the stream through the vaporizer.

Abstract: A power plant for a use device wherein liquid nitrogen and a heated transfer fluid are alternately used to expand and contract a liquid metal like mercury to drive a piston, a crankshaft, and subsequent drive apparatus. A control device is timed with operation of the piston to control various solenoid valves and pumps to cause liquid nitrogen to flow into a jacket around a reservoir containing the liquid metal thereby causing it to cool and move the piston in a return stroke. When appropriate, the heated transfer fluid is pumped into a different enclosure of the jacket to force out remaining nitrogen and thereby to heat the liquid metal and move the piston in a power stroke. The process continues so as to provide continuous power to the use device.

Abstract: A closed cycle thermodynamic apparatus (10) is provided for powering a combustion machine. The apparatus (10) has a compressor (12) for compressing a working medium from a reservoir (14) at temperature T1. The temperature of the working medium increases during compression and reaches temperature T2 when leaving the compressor (12). It is then expanded in an expander (16) for turning the machine. In this manner mechanical work is extracted from the working medium. The apparatus (10) has a first heat exchanger (18) and a second heat exchanger (20) connected to the compressor (12) and the expander (16) in a closed cycle. It also has a burner (22) and a third heat exchanger (24). Air, as a Heat transfer medium, at ambient temperature T5 is induced into the second exchanger (20) to cool the working medium by receiving heat therefrom. The temperature of the working medium decreases from T4 to T1 before entering the compressor (12) for repeating the cycle.

Abstract: The present invention provides apparatus and methods for producing both heat and electrical energy by burning fuels in a stove or boiler using a novel arrangement of a surface heat exchanger and microturbine-powered generator and novel surface heat exchanger. The equipment is particularly suited for use in rural and relatively undeveloped areas, especially in cold regions and highlands.

Abstract: Embodiments of the invention include a sleeved heat engine that can be used in a fluidized bed combustion system and a fluidized bed combustion system with heat engines. In one embodiment, a heat engine includes an enclosed cylinder, a fixed charge of gas in the cylinder, a piston in the cylinder, and a sleeve spaced apart from and surrounding part of the cylinder. The sleeve defines a passage along part of the cylinder to carry, for example, combustion air introduced into a fluidized bed combustion chamber. In another embodiment, a system includes a combustion chamber, a bed of sand in the combustion chamber, multiple air passages penetrating the combustion chamber such that air entering the combustion chamber through the passages passes through the sand, and multiple heat engines disposed along the combustion chamber such that at least a part of each heat engine is exposed to sand in the bed of sand.

Abstract: A single phase vapor cycle apparatus has a reservoir containing a supply of heated vapor, a turbine for producing a work output, and a compressor downstream of the turbine. The turbine receives the vapor from the reservoir and expands the vapor at an incoming temperature and pressure so that the vapor is exhausted from the turbine at a first temperature and pressure below the incoming temperature and pressure. The compressor receives vapor exhausted from the turbine. Heat is exchanged between vapor entering the compressor and vapor being compressed in the compressor so that the vapor in the compression process is cooled and the vapor entering the compressor is heated to a temperature above the first temperature. The compressed vapor is delivered to the reservoir.

Abstract: A method and apparatus for providing a steam boiler/combuster and gasifier that uses a primary dirty fuel, such as waste materials, or high-polluting fossil fuels, and a secondary low-polluting fuel, such as biomass fuels for co-generation of electricity while reducing harmful emissions. The primary fuel is burned in the combuster to create steam in the steam boiler. The steam turns a steam turbine thereby powering a first generator. The dirty exhaust from the combuster is scrubbed by a gasifier. The secondary fuel and oxygen are added to the dirty exhaust in the gasifier creating gas and ash. The gas powers an engine that turns a second generator and releases a cleaner exhaust.

Abstract: A wellbore method which, in certain aspects, includes providing with a primary system a fluid with microorganisms, the primary system including introduction apparatus, with the introduction apparatus introducing the fluid with microorganisms into an earth formation bearing hydrocarbons, the microorganisms for facilitating removal of the hyrdrocarbons from the earth formation bearing hydrocarbons, effecting heat exchange between the fluid with microorganisms and heat transfer fluid that has traversed an earth loop of an earth loop heat exchange system, the earth loop heat exchange system with an earth loop extending from an earth surface down into the earth with the heat transfer fluid flowable through the earth loop and heat transfer apparatus for transferring heat between the fluid with the microorganisms and the heat transfer fluid; and, in certain asepcts wherein effecting the heat exchange between said fluid with microorganisms and the heat transfer fluid prolongs life of and/or enhances activity of the m

Abstract: The invention relates to a method and to a device for cooling the inflow area (37) of the shaft of a steam turbine (10). According to the invention, a partial mass flow m1 is branched off upstream of a feed device (23) that supplies the steam to the steam turbine (10). Said partial mass flow is cooled and then guided to the feed device (23), from where it is supplied to the steam turbine (10)t together with the remaining mass flow m2. The inventive method and device allow for a simplified control and design of the turbine.

Abstract: A combined cycle power plant includes a gasifier for converting biomass material, low grade coal, etc., to combustible gases and producing heat, an internal combustion engine coupled to a generator for burning the combustible gases and driving said generator which produces power. The internal combustion engine rejects heat and produces hot exhaust gases. A vaporizer containing an organic fluid is responsive to the hot exhaust gases for vaporizing the organic fluid and producing vaporized organic fluid which is supplied to an organic vapor turbine coupled to a generator. The turbine expands the vaporized organic fluid driving the generator and producing expanded vaporized organic fluid which is condensed in a condenser. The condensate produced by the condenser is returned to the vaporizer. At least some of the heat rejected by the internal combustion engine is transferred the condensate.

Abstract: A heat engine (10) achieves operational efficiencies by: 1) recovering waste heat from heat engine expander (14) to preheat heat-engine working fluid, 2) using super-heated working fluid from compressor (402) to pre-heat heat-engine working fluid, and 3) using reject heat from condenser (93) and absorber (95) to heat the heat-engine boiler (12). A dual heat-exchange generator (72) affords continuous operation by using gas-fired heat exchanger (212) to heat generator (72) when intermittent heat source (40), e.g., solar, is incapable of heating generator (72). The combination of heat engine (10) and absorption and compression heat transfer devices (60, 410) allows use of low-temperature heat sources such as solar, bio-mass, and waste heat to provide refrigeration, heating, work output including pumping and heating of subterranean water and electrical generation.

Abstract: An externally fired gas turbine system according to the present invention has a compressor for compressing ambient air and producing compressed air, an air heat exchanger for heating the compressed air to produce heated compressed air, a turbine for expanding the heated compressed air to produce heat depleted expanded air, and a generator connected to the turbine for generating electricity. According to the present invention, the system also includes combustible products producing apparatus for processing fuel to produce combustible products that include combustible gases and an external combustion chamber for burning the combustible products and transferring heat to the air heat exchanger and producing heat depleted combustion products. The system also includes a closed Rankine cycle steam power plant having a water heat exchanger for vaporizing water and producing steam using heat contained in the heat depleted combustion products.

Abstract: Reheat of reheat regenerative steam power cycle increases its efficiency by increasing the average temperature of heat reception. In spite of such an increase in efficiency, reheating increases the irreversibility of feed water heaters by using superheated steam of a greater temperature difference in the regenerative cycle. This invention introduces some modifications to the regular reheat regenerative steam power cycle that reduces the irreversibility of the regenerative process. The invention applies reversible reheating in addition to the regular reheating and uses smaller temperature differences across feed water heaters than the regular cycle. A comparison study between the regular reheat regenerative cycle and the invented cycle is done. The results indicate that a gain in efficiency of up to 2.5% is obtained when applying invented cycle at the same conditions of pressure, temperatures, number of reheating stages, and feed water heaters.

Abstract: The generation of electric power and the separation of a feed gas mixture containing oxygen and nitrogen are carried out by combusting an oxidant gas and fuel in a combustion engine to generate shaft work and a hot exhaust gas, utilizing the shaft work to drive an electric generator to provide the electric power, compressing the feed gas mixture and separating the resulting compressed feed gas mixture into two or more product gas streams with differing compositions, heating one of the product gas streams by indirect heat exchange with the hot exhaust gas, and work expanding the resulting heated product gas stream to generate shaft work and yield an expanded product gas stream. The feed gas mixture can be air and the combustion engine can be a gas turbine combustion engine, and the air separation process preferably is operated independently of the gas turbine combustion engine.

Abstract: An elevated pressure power plant or system is disclosed that provides for cleanly and efficiently oxidizing or combusting a fuel, such as a fossil fuel, as follows. The fuel and an oxidant are passed to a reaction chamber, and the fuel is oxidized in the chamber at a pressure that is preferably substantially within a range of from approximately 700 psia to approximately 2000 psia and that is more preferably substantially within a range of from approximately 850 psia to approximately 1276 psia. A coolant is passed to the reaction chamber in a heat exchange relationship with the fuel and oxidant. The pressure of the reaction chamber is selected so that it is greater than or equal to a liquid-vapor equilibrium pressure of carbon dioxide at the temperature at which the coolant is passed to the reaction chamber.

Abstract: The invention relates to a method and an apparatus for the conversion of low-grade heat into mechanical energy, in particular electricity. To this end a working medium is heated in a closed circulation system causing the working medium to expand. The expansion produces mechanical energy. The heat remaining in the working medium is abstracted by a cooling medium in counterflow, to be reutilized for the production of mechanical energy. This makes its possible to achieve a high degree of efficiently. Due to cooling the working medium contracts and this contributes to the achievement of a high degree of efficiency. The working medium is preferably a paraffine.