초록 ▼

A closed loop system for generating mechanical energy at high efficiencies. The system can have a heating source, a superheater, an expander, a receiver, an absorber, a desorber, and regenerator with pumps and controls. The superheater heats a working fluid (a refrigerant or steam). A positive liqu

A closed loop system for generating mechanical energy at high efficiencies. The system can have a heating source, a superheater, an expander, a receiver, an absorber, a desorber, and regenerator with pumps and controls. The superheater heats a working fluid (a refrigerant or steam). A positive liquid/vapor expander expands a low temperature refrigerant, or steam vapor to the saturated state (having both liquid and vapor parts) utilizing a low-pressure sub-atmospheric exhaust sink. An absorber, generates a low-pressure sub-atmospheric sink using chemosorption which involves the exothermic reaction/absorption of ammonia refrigerant in water. The desorber is used to reconstitute inlet vapor (for reuse) and the regenerator recovers heat generated by chemosorption. The system can meet electrical power needs for residences, businesses or office buildings. The system can supply electrical energy to power grids, and can be an alternative power generation plants.

대표청구항 ▼

We claim: 1. A method for generating mechanical energy at high efficiencies, comprising the steps of: using a thermal generator for heating an ammonia-refrigerant to produce a heated and pressurized vapor having a temperature within a range of approximately 575째 F. to approximately 700째 F., at a pr

We claim: 1. A method for generating mechanical energy at high efficiencies, comprising the steps of: using a thermal generator for heating an ammonia-refrigerant to produce a heated and pressurized vapor having a temperature within a range of approximately 575째 F. to approximately 700째 F., at a pressure of approximately 72 psi to approximately 120 psi; using a positive displacement expander, having a fixed expansion ratio, for receiving and expanding the heated and pressurized vapor, as received from the thermal generator, against a low pressure subatmospheric sink in order to produce a mechanical work energy; using said mechanical work energy to rotate a shaft coupled with an electrical generator to produce electrical power; using a receiver for receiving and separating a liquid part and a vapor part of a saturated vapor discharge which exits from the positive displacement expander; using an absorber to generate a low pressure sub-atmospheric sink, at using an absorber to generate a low pressure sub-atmospheric sink, at approximately 0.2 bar as used by the positive displacement expander for expansion of the heated and pressurized gas at an inlet to the expander, to the saturated vapor discharge at an exit from the expander having a temperature between approximately-90 F. and approximately-70째 F., a liquid part of the saturated vapor discharge is approximately 60% and a vapor part of the saturated vapor discharge is approximately 40%; using a desorber for heating and separating the vapor part from liquid produced from the absorber, and providing a resultant vapor to the thermal generator for reuse; using a pump for moving absorbent liquid produced from the absorber to the desorber; using a regenerator consisting of a heat exchanger with cooling and vaporization components, which recovers heat energy contained in a liquid stream received from the desorber, to heat and vaporize the liquid part of the ammonia-refrigerant received from the receiver in order to provide a resultant vapor to the heat generator for reuse; and using a second pump to transfer the ammonia-refrigerant from the receiver to the regenerator, wherein the method generates mechanical energy at high efficiencies. 2. The method of claim 1, further comprising the step of: providing a scroll expander having a fixed expansion ratio as the positive displacement expander. 3. The method of claim 1, further comprising the step of: providing a rotary vane expander having a fixed expansion ratio as the positive displacement expander. 4. The method of claim 1, further comprising the step of: providing a Wankel-type engine having a fixed expansion ratio as the positive displacement expander. 5. A closed loop system for generating mechanical energy at high efficiencies using an ammonia-refrigerant as the working fluid, comprising: a thermal generator for heating an ammonia-refrigerant to produce a heated and pressurized vapor having a temperature within a range of approximately 575째 F. to approximately 700째 F., at a pressure of approximately 72 psi to approximately 120 psi; a positive displacement expander having a fixed expansion ratio, for receiving and expanding the heated and pressurized vapor against a low pressure sub-atmospheric sink in order to produce mechanical work energy; a shaft coupled with an electrical generator, wherein rotating the shaft by the mechanical work energy causes the electrical generator produce electrical power; a receiver for receiving and separating a liquid part and a vapor part of a saturated vapor discharge which exits from the positive displacement expander; an absorber to generate a low pressure sub-atmospheric sink, at approximately 0.2 bar as used by the positive displacement expander for expansion of the heated and pressurized gas at an inlet to the expander, to the saturated vapor discharge at an exit from the expander having a temperature between approximately-90 F and approximately-70째 F. , a liquid part of the saturated vapor discharge is approximately 60% and a vapor part of the saturated vapor discharge is approximately 40%; a desorber for heating and separating the vapor part from liquid produced from the absorber, and providing a resultant vapor to the thermal generator for reuse; a pump for moving absorbent liquid produced from the absorber to the desorber; a regenerator consisting of a heat exchanger with cooling and vaporization components, which recovers heat energy contained in a liquid stream received from the desorber, to heat and vaporize the liquid part of the ammonia-refrigerant received from the receiver in order to provide a resultant vapor to the heat generator for reuse; and a second pump to transfer the ammonia-refrigerant from the receiver to the regenerator. 6. The system of claim 5, wherein the positive displacement expander includes: a scroll expander having a fixed expansion ratio. 7. The system of claim 5, wherein the positive displacement expander includes: a rotary vane expander having a fixed expansion ratio. 8. The system of claim 5, wherein the positive displacement expander includes: a Wankel-type engine having a fixed expansion ratio. 9. A method for generating mechanical energy at high efficiencies, comprising the steps of: using a thermal generator for heating an ammonia-refrigerant to produce a heated and pressurized vapor having a temperature within a range of approximately 575째 F. to approximately 700째 F., at a pressure of approximately 72 psi to approximately 120 psi; using a positive displacement expander, having a fixed expansion ratio, for receiving and expanding the heated and pressurized vapor, as received from the thermal generator, against a low pressure subatmospheric sink in order to produce a mechanical work energy; using said mechanical work energy to rotate a shaft coupled with an electrical generator to produce electrical power; using a receiver for receiving and separating a liquid part and a vapor part of a saturated vapor discharge which exits from the positive displacement expander; using an absorber to generate a low pressure sub-atmospheric sink, at approximately 0.2 bar as used by the positive displacement expander for expansion of the heated and pressurized gas at an inlet to the expander, to the saturated vapor discharge at an exit from the expander having a temperature between approximately-90 F and approximately-70째 F., a liquid part of the saturated vapor discharge is approximately 60% and a vapor part of the saturated vapor discharge is approximately 40%; using a heat exchanger, which is positioned within the absorber for cooling an absorption process in the absorber and recovering a heat produced as a result of the absorption process for heating the liquid part received from the receiver prior to delivery to a regenerator for reuse; using a desorber for heating and separating the vapor part from liquid produced from the absorber, and providing a resultant vapor to the thermal generator for reuse; using a pump for moving absorbent liquid produced from the absorber to the desorber; using the regenerator consisting of another heat exchanger with cooling and vaporization components, which recovers heat energy contained in a liquid stream received from the desorber, to heat and vaporize the liquid part of the ammonia-refrigerant received from the receiver in order to provide a resultant vapor to the heat generator for reuse; and using a second pump to transfer the ammonia-refrigerant from the receiver to the regenerator via the heat exchanger installed within the absorber, wherein the method generates mechanical energy at high efficiencies. 10. The method of claim 9, further comprising the step of: providing a scroll expander having a fixed expansion ratio as the positive displacement expander. 11. The method of claim 9, further comprising the step of: providing a rotary vane expander having a fixed expansion ratio as the positive displacement expander. 12. The method of claim 9, further comprising the step of: providing a Wankel-type engine having a fixed expansion ratio as the positive displacement expander. 13. A closed loop system for generating mechanical energy at high efficiencies using an ammonia-refrigerant as the working fluid, comprising: a thermal generator for heating an ammonia-refrigerant to produce a heated and pressurized vapor having a temperature within a range of approximately 575째 F. to approximately 700째 F., at a pressure of approximately 72 psi to approximately 120 psi; a positive displacement expander having a fixed expansion ratio, for receiving and expanding the heated and pressurized vapor against a low pressure sub-atmospheric sink in order to produce mechanical work energy; a shaft coupled with an electrical generator, wherein rotating the shaft by the mechanical work energy causes the electrical generator produce electrical power; a receiver for receiving and separating a liquid part and a vapor part of a saturated vapor discharge which exits from the positive displacement expander; an absorber to generate a low pressure sub-atmospheric sink, at approximately 0.2 bar as used by the positive displacement expander for expansion of the heated and pressurized gas at an inlet to the expander, to the saturated vapor discharge at an exit from the expander having a temperature between approximately-90 F and approximately-70째 F. , a liquid part of the saturated vapor discharge is approximately 60% and a vapor part of the saturated vapor discharge is approximately 40%; a heat exchanger, which is positioned within the absorber for cooling an absorption process in the absorber and recovering a heat produced as a result of the absorption process for heating the liquid part received from the receiver prior to delivery to a regenerator for reuse; a desorber for heating and separating the vapor part from liquid produced from the absorber, and providing a resultant vapor to the thermal generator for reuse; a pump for moving absorbent liquid produced from the absorber to the desorber; the regenerator consisting of another heat exchanger with cooling and vaporization components, which recovers heat energy contained in a liquid stream received from the desorber, to heat and vaporize the liquid part of the ammonia-refrigerant received from the receiver in order to provide a resultant vapor to the heat generator for reuse; and a second pump to transfer the ammonia-refrigerant from the receiver to the regenerator via a heat exchanger installed within the absorber. 14. The system of claim 13, wherein the positive displacement expander includes: a scroll expander having a fixed expansion ratio. 15. The system of claim 13, wherein the positive displacement expander includes: a rotary vane expander having a fixed expansion ratio. 16. The system of claim 13, wherein the positive displacement to expander includes: a Wankel-type engine having a fixed expansion ratio.