An organic Rankine engine used to power a vehicle is provided with a quick-start system of pumps, electric heaters or pistons to generate a pressure differential across the motor, prior to the engine reaching operating conditions.
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I claim: 1. An organic Rankine cycle engine comprising: (a) an organic working fluid; (b) a boiler capable of exchanging heat between the working fluid and an external heat source and raising the temperature of the working fluid; (c) a motor, having an intake and an exhaust port, capable of being d
I claim: 1. An organic Rankine cycle engine comprising: (a) an organic working fluid; (b) a boiler capable of exchanging heat between the working fluid and an external heat source and raising the temperature of the working fluid; (c) a motor, having an intake and an exhaust port, capable of being driven by the working fluid, whereby the working fluid enters the intake port and exits the exhaust port in a gaseous state; (d) a condenser capable of exchanging heat between the working fluid and an external cooling source and lowering the temperature and pressure of the working fluid, whereby the working fluid is liquefied; (e) a first pump capable of transporting the liquid working fluid from the condenser to the boiler, under pressure; and (f) a means to create a pressure differential across the motor, thereby driving the motor, at start-up, selected from the group consisting of: (i) a second pump, positioned between the boiler and the condenser, and a bypass valve and piping for routing the working fluid around the second pump, when the engine is in full operation; and (ii) a reservoir, located between the boiler and the intake port of the motor, capable of isolating a portion of the working fluid from the bulk of working fluid to be heated in the boiler; a check valve located between the reservoir and the boiler, capable of restricting the flow of the working fluid back to the boiler; and a means to selectively increase the pressure of the working fluid in the reservoir, thereby increasing the pressure of the working fluid at the intake port of the motor. 2. The engine according to claim 1, wherein the second pump, bypass valve and piping to create a pressure differential across the motor is positioned between the boiler and the motor, and is capable of increasing the pressure of the working fluid at the intake port of the motor. 3. The engine according to claim 1, wherein the second pump, bypass valve and piping to create a pressure differential across the motor is positioned between the motor and the condenser, and is capable of decreasing the pressure of the working fluid at the exhaust port of the motor. 4. The engine according to claim 1, wherein the means to create a pressure differential comprises the second pump, bypass valve and piping positioned between the boiler and the motor, capable of increasing the pressure of the working fluid at the intake port of the motor, and a third pump, bypass valve and piping positioned between the motor and the condenser, capable of decreasing the pressure of the working fluid at the exhaust port of the motor, wherein the second and third pumps operate on battery power. 5. The engine according to claim 1, wherein the reservoir, check valve and means to increase the pressure of the working fluid in the reservoir to create a pressure differential across the motor further comprises an electrical heating element, positioned to transfer heat to the portion of the working fluid in the reservoir. 6. The engine according to claim 1, wherein the reservoir, check valve and means to increase the pressure of the working fluid in the reservoir to create a pressure differential across the motor further comprises a means to contract the volume of the reservoir thereby increasing the pressure of the working fluid at the intake port of the motor, at the time of start-up. 7. The engine according to claim 1, wherein the external heat source is combustion gases generated by a burner, and the reservoir, check valve and means to increase the pressure of the working fluid in the reservoir to create a pressure differential across the motor further comprises a valve and piping for directing combustion gases directly to the boiler and for diverting combustion gases away from the boiler and directly to the reservoir; and a heat exchanger located in the reservoir for exchanging heat between the diverted combustion gases and the working fluid in the reservoir. 8. The engine of claim 1, wherein the external heat source supplied to the boiler comprises combustion gases, wherein the combustion gases are (i) directed to a heat exchanger in the boiler, and then (ii) directed to a vortex tube, to produce a cold gas stream and a hot gas stream, and the hot gas stream is used to heat the working fluid, prior to the working fluid entering the intake port of the motor, and the cold gas stream is used to condense the working fluid, after the working fluid exits the exhaust port of the motor. 9. The engine of claim 1, wherein the working fluid has a boiling point of 25째 C. or less, at 1 atmosphere of pressure. 10. The engine of claim 1, wherein the engine is a reciprocating piston driven engine. 11. The engine of claim 10, wherein the engine has a plurality of pistons. 12. The engine of claim 11, wherein the pistons have a diameter of at least six inches. 13. A method of starting-up an organic Rankine engine, having an organic working fluid, a boiler, a motor, a condenser and a first pump for transporting the liquid working fluid from the condenser to the boiler, under pressure, comprising the step of creating a pressure differential across an intake port and an exhaust port of the motor, prior to the temperature of the working fluid being raised by the boiler to an operating level, wherein the pressure differential is created by one or more of the techniques selected from the group consisting of (a) increasing the pressure of the working fluid at the intake port of the motor with an intake pump, positioned between the boiler and the motor; (b) decreasing the pressure of the working fluid at the exhaust port of the motor with an exhaust pump, positioned between the motor and the condenser; (c) providing (i) an external heat source of combustion gases generated by a burner, (ii) a reservoir, located between the boiler and an intake port of the motor, capable of containing a portion of the working fluid; (ii) a check valve located between the reservoir and the boiler, capable of restricting flow of the working fluid back to the boiler; (iii) a valve for diverting the combustion gases away from the boiler and directly to the reservoir; and (iv) a heat exchanger located in the reservoir for exchanging heat between the diverted combustion gases and the working fluid in the reservoir; (d) providing a reservoir, located between the boiler and the intake port of the motor, capable of containing a portion of the working fluid, a check valve located between the reservoir and the boiler, capable of restricting flow of the working fluid back to the boiler; and an electrical heating element, positioned to rapidly transfer heat to the portion of the working fluid in the reservoir, and heating the portion of the working fluid, thereby increasing the pressure of the working fluid at the intake port of the motor; and (e) providing a reservoir, located between the boiler and the intake port of the motor, capable of containing a portion of the working fluid, a means to contract the volume of the reservoir and a check valve located between the reservoir and the boiler, capable of restricting flow of the working fluid back to the boiler, and contracting the volume of the reservoir, thereby increasing the pressure of the working fluid at the intake port of the motor. 14. The method of claim 13, wherein the pressure differential is created by increasing the pressure of the working fluid at the intake port of the motor with an intake pump, positioned between the boiler and the motor, and further comprising the step of bypassing the working fluid around the intake pump when the engine is at a full operating level. 15. The method of claim 13, wherein the pressure differential is created by decreasing the pressure of the working fluid at the exhaust port of the motor with an exhaust pump, positioned between the motor and the condenser, and further comprising the step of bypassing the working fluid around the exhaust pump when the engine is at a full operating level. 16. The method of claim 13, wherein the pressure differential is created by providing a reservoir, located between the boiler and the intake port of the motor, capable of containing a portion of the working fluid, a check valve located between the reservoir and the boiler, capable of restricting flow of the working fluid back to the boiler; and an electrical heating element, positioned to rapidly transfer heat to the portion of the working fluid in the reservoir, and heating the portion of the working fluid with the heating element, thereby increasing the pressure of the working fluid at the intake port of the motor. 17. The method of claim 13, wherein the pressure differential is created by providing a reservoir, located between the boiler and the intake port of the motor, capable of containing a portion of the working fluid, a means to contract the volume of the reservoir and a check valve located between the reservoir and the boiler, capable of restricting flow of the working fluid back to the boiler, and contracting the volume of the reservoir, thereby increasing the pressure of the working fluid at the intake port of the motor. 18. The method of claim 13, further comprising the steps of (i) burning a fuel to create combustion gases; (ii) directing the combustion gases to a heat exchanger in the boiler, and (iii) directing the combustion gases to a vortex tube, to produce a cold gas stream and a hot gas stream, the hot gas stream is used to heat the working fluid, prior to the working fluid entering an intake port of the motor, and the cold gas stream is used to condense the working fluid, after the working fluid exits the exhaust port of the motor. 19. The method of claim 13, wherein the means to create a pressure differential across the motor comprises providing (i) an external heat source of combustion gases generated by a burner, (ii) a reservoir, located between the boiler and an intake port of the motor, capable of containing a portion of the working fluid; (ii) a check valve located between the reservoir and the boiler, capable of restricting flow of the working fluid back to the boiler; (iii) a valve for diverting the combustion gases away from the boiler and directly to the reservoir; and (iv) a heat exchanger located in the reservoir for exchanging heat between the diverted combustion gases and the working fluid in the reservoir. 20. The engine of claim 13, wherein the working fluid has a boiling point of less than 25째 C., at 1 atmosphere of pressure.
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