초록 ▼

A method and system using at least two different working fluids to be supplied to an expander to cause it to do mechanical work. The expander is started by providing a compressed gaseous working fluid at a sufficient pressure to the expander. At the same time the compressed gaseous working fluid is

A method and system using at least two different working fluids to be supplied to an expander to cause it to do mechanical work. The expander is started by providing a compressed gaseous working fluid at a sufficient pressure to the expander. At the same time the compressed gaseous working fluid is provided to the expander, a second working fluid that is liquid at ambient temperatures is provided to a heater to be heated. The second working fluid is heated to its boiling point and converted to pressurized gas Once the pressure is increased to a sufficient level, the second working fluid is injected into the expander to generate power, and the supply of the first working fluid may be stopped. After expansion in the expander, the working fluids are is exhausted from the expander, and the second working fluid may be condensed for separation from the first working fluid. Control circuitry controls the admission of the first and second working fluids responsive to monitoring the load on the expander.

대표청구항 ▼

1. A power generation unit comprising: a first vessel holding a quantity of a first pressurized gaseous working fluid that is gaseous at ambient temperature, being pressurized to a pressure substantially greater than ambient pressure;a second vessel holding a quantity of a second working fluid that

1. A power generation unit comprising: a first vessel holding a quantity of a first pressurized gaseous working fluid that is gaseous at ambient temperature, being pressurized to a pressure substantially greater than ambient pressure;a second vessel holding a quantity of a second working fluid that is in a liquid state at ambient temperature;a controllable heater in controllable communication with at least said second vessel for heating at least said second working fluid;an expander in controllable communication with said heater and said first vessel, such that said expander can receive said first pressurized gaseous working fluid and/or receive said second working fluid, having been heated by said heater to be vaporized and form a second pressurized gaseous working fluid, said first and/or second pressurized gaseous working fluids being supplied to at least one chamber in said expander where said pressurized gaseous working fluids can expand, causing said expander to produce power;a controller responsive to a control input to determine the power required to be provided by said expander, and for controlling heating of said at least second working fluid in said heater, and flow of said first and second working fluids from the respective vessels to the heater and to said at least one chamber of the expander responsive to the amount of power required; anda mechanically-operated valve for preventing said second working fluid from reaching said expander prior to said second working fluid reaching a predetermined minimum temperature. 2. The power generation unit of claim 1, further comprising a heat exchanger for heating water by recovery of waste heat from an exhaust of the expander. 3. The power generation unit of claim 2, wherein water heated in said heat exchanger is further employed to cool the expander. 4. The power generation unit of claim 2, wherein water heated in said heat exchanger is further heated in said controllable heater. 5. The power generation unit of claim 1, wherein said first working fluid is selected from the group consisting of air, nitrogen, compressed fuel gas, and refrigerants. 6. The power generation unit of claim 5, wherein said first working fluid is compressed fuel gas, and wherein said compressed fuel gas is further employed as fuel for said heater. 7. The power generation unit of claim 1, wherein said expander is a turbine coupled to a generator for producing electrical power. 8. The power generation unit of claim 1, wherein when a control input to the controller requires that said expander produce power at a time when said second working fluid is not heated sufficiently to form a second pressurized gaseous working fluid capable of being expanded in said at least one chamber of said expander to produce the amount of power required, said controller controls flow of said first pressurized working fluid from said first vessel to said at least one chamber of said expander, causing said expander to produce power, and also causes said heater to heat said second working fluid to be vaporized to form a second pressurized gaseous working fluid, and after said second pressurized gaseous working fluid has been formed by vaporizing said second working fluid, controls supply of said second pressurized gaseous working fluid to said at least one chamber of said expander, partially or wholly in lieu of the first pressurized gaseous working fluid, to cause said expander to produce power in response to the control input. 9. The power generation unit of claim 1, further comprising a liquid recovery device for condensing said second pressurized gaseous working fluid following expansion in and exhaust from said expander, and separating said first and second working fluids and supplying at least said second working fluid back to said second vessel. 10. The power generation unit of claim 1 wherein said heater comprises a heating element and a boiler element. 11. The power generation unit of claim 10 wherein the boiler element is a flash boiler. 12. The power generation unit of claim 1, further comprising a nozzle in which streams of the pressurized first working fluid and the second working fluid while in liquid form are combined, such that the second working fluid while in liquid form is effectively atomized prior to supply to said heater. 13. The power generation unit of claim 12, wherein said nozzle comprises a first entry for said stream of said second working fluid that is in a liquid state at ambient temperature, a second entry for said stream of said first working fluid, an exit for the streams after combination, and an internal passageway that extends along a straight line from said first entry to said exit, and wherein said second entry communicates with said internal passageway at an angle to said straight line, whereby said stream of said pressurized first working fluid atomizes said stream of said of said second working fluid. 14. The power generation unit of claim 13, wherein said internal passageway diverges from said first entry to said exit. 15. The power generation unit of claim 1, wherein said power generation unit is configured to propel a vehicle, said expander is a turbine capable of being driven by said working fluids to produce mechanical power, and wherein an output shaft of said turbine is connected to wheels of said vehicle for transmission of power to said wheels. 16. The power generation unit of claim 1, wherein said power generation unit is configured to propel a vehicle, said expander is a turbine capable of being driven by said working fluids to produce mechanical power, wherein an output shaft of said turbine is connected to a generator to produce electrical power, wherein a motor/generator is connected to wheels of said vehicle for transmission of mechanical power to said wheels, and wherein a battery is connected between said generator and said motor/generator to store electrical power provided by said generator and to supply electrical power to said motor/generator. 17. A method for operating an expander responsive to selective supply of two different pressurized gaseous working fluids to at least one chamber of said expander wherein the pressurized gaseous working fluids can expand, causing said expander to produce power, comprising the steps of: providing a supply of a first pressurized working fluid which is gaseous at ambient temperature;providing a supply of a second working fluid that is liquid at ambient temperature, and which can be heated to form a supply of a second pressurized gaseous working fluid;providing a controller which monitors the amount of power that is to be produced by the expander, and performs the following steps in response to a requirement that the expander produce power:if said expander has not been started, starting said expander by supplying said first pressurized gaseous working fluid to said at least one chamber of said expander, causing said expander to produce power;supplying said second working fluid to a boiler in liquid form;applying heat to said boiler to convert said liquid second working fluid to a second pressurized gaseous working fluid; andwhen said second pressurized gaseous working fluid is available, providing said second pressurized gaseous working fluid from said boiler to said at least one chamber of said expander wholly or partially in lieu of said first pressurized gaseous working fluid, causing said expander to produce power, employing a mechanically-operated valve for preventing said second working fluid from reaching said expander prior to said second working fluid reaching a predetermined minimum temperature; andduring operation of the expander, monitoring the requirement for power to be produced by said expander and determining the appropriate amounts of the first and second working fluids to be supplied to said expander. 18. The method of claim 17, wherein said step of providing said first pressurized gaseous working fluid to said expander further comprises the steps of: providing said first pressurized gaseous working fluid to said boiler, further pressurizing said first gaseous working fluid, andproviding said further pressurized first gaseous working fluid to said expander from said boiler. 19. The method of claim 17, wherein a stream of said first and second pressurized gaseous working fluids is exhausted from said expander at a pressure and temperature lower than the pressure and temperature at which they are admitted to the expander, and comprising the further step of: recovering heat from the exhausted stream by admitting the exhausted stream to a heat exchanger, wherein a stream of water is disposed in heat-exchange relationship with the exhausted stream, and thereby heating the stream of water and condensing said second pressurized gaseous working fluid such that it is returned to the liquid state. 20. The method of claim 19, further comprising the steps of separation of said first and second working fluids from the exhausted stream after condensation of the second working fluid, and returning the second working fluid to the supply thereof. 21. The method of claim 19, wherein said stream of water is supplied to the expander after having been heated in said heat exchanger, to further heat the stream of water and to cool the expander. 22. The method of claim 19, wherein said stream of water is supplied to the boiler after having been heated in said heat exchanger, to further heat the stream of water. 23. The method of claim 17, wherein said first working fluid is selected from the group consisting of air, nitrogen, compressed fuel gas, and refrigerants. 24. The method of claim 17, wherein said first working fluid is compressed fuel gas, and wherein said compressed fuel gas is further employed as fuel for said heater. 25. The method of claim 17, wherein said expander is a turbine coupled to a generator for producing electrical power. 26. The method of claim 17, comprising the further step of mixing streams of the first and second working fluids prior to admission of the second working fluid to the boiler, such that the first working fluid atomizes the second working fluid while in liquid form. 27. The method of claim 26, wherein said streams of the pressurized first working fluid and the second working fluid while in liquid form are combined in a nozzle, such that the liquid second working fluid is effectively atomized prior to supply to said heater. 28. The method of claim 27, wherein said nozzle comprises a first entry for said stream of said second working fluid while in liquid form, a second entry for said stream of said pressurized first working fluid, an exit for the streams after combination, and an internal passageway that extends along a straight line from said first entry to said exit, and wherein said second entry communicates with said internal passageway at an angle to said straight line, whereby said stream of said pressurized first working fluid atomizes said stream of said of said second working fluid. 29. The method of claim 28, wherein said internal passageway diverges from said first entry to said exit.