초록 ▼

A six stroke high thermal efficiency engine and a method for operating such an engine are disclosed. Oxygen or oxygen-enriched air is used as the oxidizer, heat is recovered from the two exhaust strokes, superheated steam is used in the second power stroke, and high levels of exhaust gas from stroke

A six stroke high thermal efficiency engine and a method for operating such an engine are disclosed. Oxygen or oxygen-enriched air is used as the oxidizer, heat is recovered from the two exhaust strokes, superheated steam is used in the second power stroke, and high levels of exhaust gas from stroke four are recirculated. Lean burn combustion is utilized to produce an oxygen rich exhaust which results in very low levels of particulates, unburned hydrocarbons, and carbon monoxide. Due to high thermal efficiency, carbon dioxide emissions are reduced per unit of power output. Use of oxygen or oxygen-enriched air as the oxidizer produces an exhaust containing very low levels of nitrogen oxides. The engine is insulated to conserve heat, resulting in reduced engine noise. An engine with high thermal efficiency, quiet operation, and low emissions is the result.

대표청구항 ▼

1. A six stroke internal combustion engine comprising: (a) At least one combustion chamber bounded by a cylinder, a cylinder head, and a piston reciprocally connected to a crankshaft through a connecting rod,(b) a recirculated exhaust intake valve connected to a recirculated exhaust gas conduit, whe

1. A six stroke internal combustion engine comprising: (a) At least one combustion chamber bounded by a cylinder, a cylinder head, and a piston reciprocally connected to a crankshaft through a connecting rod,(b) a recirculated exhaust intake valve connected to a recirculated exhaust gas conduit, where the recirculated exhaust intake valve is configured for allowing exhaust gas to be recirculated to the combustion chamber,(c) an oxidizer injection valve connected to an oxidizer accumulator through an oxidizer conduit, where the oxidizer injection valve is configured for controlling the flow of oxidizer composed of greater than 80% to and including 97% oxygen by volume entering the combustion chamber,(d) a fuel injection valve connected to a fuel conduit, where the fuel injection valve is configured for controlling the flow of fuel entering the combustion chamber,(e) a means for igniting a mixture of fuel and oxidizer composed of greater than 80% to and including 97% oxygen by volume is provided within the combustion chamber proximate top dead center within the combustion chamber,(f) a combustion exhaust valve connecting the combustion chamber with a steam super heater exchanger through a combustion exhaust conduit,(g) a superheated steam valve connected to a superheated steam conduit, where the superheated steam valve is configured for controlling the flow of superheated steam to the combustion chamber from the steam super heater exchanger,(h) a steam exhaust valve connecting the combustion chamber with a heat recovery heat exchanger through a steam exhaust conduit, where the steam exhaust valve is configured for controlling the flow of steam exhaust from the combustion chamber, and(i) a heat recovery system configured for generating superheated steam for return to the combustion chamber through the superheated steam conduit and generating cooled combustion exhaust gas for return to the combustion chamber through the recirculated exhaust gas conduit. 2. The engine of claim 1 wherein the heat recovery system comprises: (a) a steam super heater exchanger configured for receiving combustion exhaust from a fourth stroke through the combustion exhaust conduit and exchanging heat from the combustion exhaust with the steam from the steam conduit to produce superheated steam for return to the combustion chamber through the superheated steam conduit;(b) a vaporizer heat exchanger configured for receiving partially cooled combustion exhaust from the steam super heater exchanger through a partially cooled exhaust conduit and exchanging heat from the partially cooled combustion exhaust with partially heated water from a partially heated water conduit;(c) an exhaust gas heat exchanger configured for receiving further cooled combustion exhaust from the vaporizer heat exchanger through a further cooled exhaust conduit and cooling the further cooled combustion exhaust for return to the combustion chamber as recirculated exhaust gas through the recirculated exhaust gas conduit;(d) a heat recovery heat exchanger configured for receiving partially depressurized steam from a sixth stroke through the steam exhaust conduit and exchanging heat from the partially depressurized steam with water from a water conduit;(e) a condenser heat exchanger configured for receiving partially depressurized and cooled steam from the heat recovery heat exchanger through a partially cooled steam conduit and condensing the partially depressurized and cooled steam to water stored in a condensed steam reservoir. 3. The engine of claim 1 wherein the ignition of the mixture of the fuel and said oxidizer composed of greater than 80% to and including 97% oxygen by volume is initiated by the heat and temperature due to compression within the combustion chamber. 4. The engine of claim 1 wherein the ignition of the mixture of the fuel and said oxidizer composed of greater than 80% to and including 97% oxygen by volume is initiated by an electrical discharge from a spark plug. 5. The engine of claim 1 wherein the fuel is a mixture of hydrocarbon and hydrogen. 6. A method of operating an internal combustion engine having a piston moving reciprocally inside a cylinder and driving a crankshaft to provide a six stroke cycle, the method comprising the steps of: performing a first-stroke cycle having: (a) a first event in which the piston travels inside the cylinder in the direction toward the crankshaft with a recirculated exhaust intake valve open, an oxidizer injection valve controllably throttling an oxidizer composed of greater than 80% to and including 97% oxygen by volume into a combustion chamber, and with a fuel injection valve, a steam exhaust valve, a superheated steam valve, and a combustion exhaust valve closed,(b) a second event in which both the recirculated exhaust intake valve and the oxidizer injection valve are closed proximate the end of the piston travel;performing a second-stroke cycle having: (a) a first event in which the piston inside the cylinder travels away from the crankshaft compressing a mixture of recirculated exhaust gas and said oxidizer composed of greater than 80% to and including 97% oxygen by volume with the recirculated exhaust intake valve, the oxidizer injection valve, the steam exhaust valve, and the combustion exhaust valve closed and with the fuel injection valve controllably throttling fuel into the combustion chamber to create a combustible mixture of fuel and said oxidizer composed of greater than 80% to and including 97% oxygen by volume,(b) a second event in which combustion of the fuel and said oxidizer composed of greater than 80% to and including 97% oxygen by volume is initiated proximate the end of the piston travel away from the crankshaft;performing a third-stroke cycle having: (a) a first event in which the recirculated exhaust intake valve, the fuel injection valve, the oxidizer injection valve, the steam exhaust valve, the super heated steam valve, and the combustion exhaust valve are closed, with the piston traveling toward the crankshaft due to the expansion of the combusting fuel and oxidizer mixture;(b) a second event in which the combustion exhaust valve opens proximate the end of the piston travel toward the crankshaft;performing a fourth-stroke cycle having: (a) a first event in which the combusted gases are discharged through the open combustion exhaust valve into a steam super heater exchanger, followed by a vaporizer heat exchanger, followed by an exhaust gas heat exchanger, followed by partial return of the exhaust gas to the first stroke as the piston advances away from the crankshaft, the first event ending as the piston nears its end of travel away from the crankshaft,(b) a second event in which the combustion exhaust valve closes proximate top dead center,(c) a third event in which the superheated steam valve opens to controllably meter superheated steam into the combustion chamber proximate the end of travel of the piston away from the crankshaft;performing a fifth-stroke cycle having: (a) a first event in which the superheated steam valve closes and the pressure exerted by this steam inside the combustion chamber, coupled with the pressure resulting from the heat from cooling the surfaces surrounding the combustion chamber, forces the piston to travel toward the crankshaft,(b) a second event in which the steam exhaust valve is opened proximate the end of travel of the piston toward the crankshaft;performing a sixth-stroke cycle having: (a) a first event in which the steam in the combustion chamber exhausts through the steam exhaust valve to the heat recovery heat exchanger, followed by the condenser heat exchanger, followed by condensed water flow through the other side of the heat recovery heat exchanger as the piston travels away from the crankshaft,(b) a second event in which the steam exhaust valve closes proximate the end of travel of the piston away from the crankshaft,(c) a third event in which the recirculated exhaust intake valve opens proximate the end of travel of the piston away from the crankshaft. 7. The method of claim 6 further comprising the heating of water and of steam by the combustion exhaust and by the steam exhaust to produce superheated steam and cooled exhaust gas in the heat recovery system for return to the engine. 8. The method of claim 6 in which the combustion exhaust from engine stroke four discharges through a combustion exhaust conduit to a steam super heater exchanger and the heat from the combustion exhaust is used to super heat the steam for return to the combustion chamber. 9. The method of claim 6 in which the steam exhaust from stroke six discharges through a steam exhaust conduit to a heat recovery heat exchanger and the heat from this steam exhaust is used to preheat water flowing to the heat recovery heat exchanger followed by a vaporizer heat exchanger followed by a steam super heater exchanger. 10. The engine of claim 1 wherein the fuel is 100% hydrocarbon. 11. The engine of claim 1 wherein the fuel is 100% hydrogen.