초록 ▼

A dual cycle waste heat recovery system includes a high-temperature circuit that utilizes a first working fluid. The first working fluid is heated by a first waste heat source and then expanded through a first expander to produce power. The heat recovery system further includes a low-temperature cir

A dual cycle waste heat recovery system includes a high-temperature circuit that utilizes a first working fluid. The first working fluid is heated by a first waste heat source and then expanded through a first expander to produce power. The heat recovery system further includes a low-temperature circuit that utilizes a second working fluid. The low-temperature circuit also includes a first heat exchanger for heating the second working fluid with heat from the first working fluid and a second heat exchanger for heating the second working fluid with heat from a second waste heat source. A control valve selectively controls the flow of the second working fluid to each of the first and second heat exchangers according to a predetermined set of parameters. An expander receives the second working fluid from the first and second heat exchangers and expands the second working fluid to produce power.

대표청구항 ▼

1. A dual cycle waste heat recovery system, comprising: (a) a high-temperature circuit, comprising: (i) a first working fluid;(ii) a first waste heat source, wherein the first working fluid is heated by the first waste heat source;(iii) a first expander, the first working fluid being expanded throug

1. A dual cycle waste heat recovery system, comprising: (a) a high-temperature circuit, comprising: (i) a first working fluid;(ii) a first waste heat source, wherein the first working fluid is heated by the first waste heat source;(iii) a first expander, the first working fluid being expanded through the first expander to produce power; and(iv) a first sensor for sensing a temperature of the first working fluid, a pressure of the first working fluid, and a mass flow of the first working fluid; and(b) a low-temperature circuit, comprising: (i) a second working fluid;(ii) a first heat exchanger selectively heating the second working fluid, the first working fluid providing heat to the first heat exchanger;(iii) a second heat exchanger configured in parallel with the first heat exchanger, the second heat exchanger selectively heating the second working fluid, a second waste heat source comprising a flow of a heat source fluid providing heat to the second heat exchanger;(iv) a second sensor for sensing a temperature of the heat source fluid, a pressure of the heat source fluid, and a mass flow of the heat source fluid;(v) a control valve for selectively directing the second working fluid to the first and second heat exchangers;(vi) a controller determining a thermal load of the first working fluid according to the temperature, pressure, and mass flow of the first working fluid, the controller determining a thermal load of the heat source fluid according to the temperature, pressure, and mass flow of the heat source fluid; and(vii) a second expander, the second working fluid being expanded through the second expander to produce power, wherein the controller controls the control valve according to the thermal loads of the first working fluid and the heat source fluid to maximize the temperature of the second working fluid entering the second expander. 2. The system of claim 1, wherein the control valve directs at least a portion of the second working fluid to the first heat exchanger when the thermal load of the first working fluid is greater than the thermal load of the heat source fluid. 3. The system of claim 2, wherein the control valve directs at least a portion of the second working fluid to the second heat exchanger when the thermal load of the heat source fluid is greater than the thermal load of the first working fluid. 4. The system of claim 1, the low-temperature circuit further comprising a third heat exchanger for selectively heating the second working fluid with heat from a third waste heat source, wherein the control valve selectively controls the flow of the second working fluid to the first, second, and third heat exchangers. 5. The system of claim 1, wherein the control valve directs the second working fluid to bypass the second heat exchanger when the thermal load of the first working fluid is greater than the thermal load of the heat source fluid. 6. The system of claim 5, wherein the control valve directs the second working fluid to bypass the first heat exchanger when the thermal load of the heat source fluid is greater than the thermal load of the first working fluid. 7. A dual cycle waste heat recovery system, comprising: (a) a high-temperature circuit, comprising: (i) a first working fluid;(ii) a first waste heat source, wherein the first working fluid is heated by the first waste heat source;(iii) a first expander, the first working fluid being expanded through the first expander to produce power; and(iv) a first sensor for sensing a temperature of the first working fluid, a pressure of the first working fluid, and a mass flow of the first working fluid; and(b) a low-temperature circuit, comprising: (i) a second working fluid;(ii) a first heat exchanger selectively heating the second working fluid, the first working fluid providing heat to the first heat exchanger;(iii) a second heat exchanger configured in parallel with the first heat exchanger, the second heat exchanger selectively heating the second working fluid, a second waste heat source comprising a flow of a heat source fluid providing heat to the second heat exchanger, the heat source fluid being one of exhaust gas, engine oil, and engine coolant;(iv) a second sensor for sensing a temperature of the heat source fluid, a pressure of the heat source fluid, and a mass flow of the heat source fluid;(v) a control valve for selectively directing the second working fluid to the first and second heat exchangers;(vi) a controller determining a thermal load of the first working fluid according to the temperature, pressure, and mass flow of the first working fluid, the controller determining a thermal load of the heat source fluid according to the temperature, pressure, and mass flow of the heat source fluid; and(vii) a second expander, the second working fluid being expanded through the second expander to produce power, wherein the controller controls the control valve according to the thermal loads of the first working fluid and the heat source fluid to maximize the temperature of the second working fluid entering the second expander. 8. The system of claim 7, wherein the control valve directs at least a portion of the second working fluid to the first heat exchanger when the thermal load of the first working fluid is greater than the thermal load of the heat source fluid. 9. The system of claim 8, wherein the control valve directs at least a portion of the second working fluid to the second heat exchanger when the thermal load of the heat source fluid is greater than the thermal load of the first working fluid. 10. The system of claim 7, the low-temperature circuit further comprising a third heat exchanger for selectively heating the second working fluid with heat from a third waste heat source, wherein the control valve selectively controls the flow of the second working fluid to the first, second, and third heat exchangers. 11. The system of claim 7, wherein the control valve directs the second working fluid to bypass the second heat exchanger when the thermal load of the first working fluid is greater than the thermal load of the heat source fluid. 12. The system of claim 11, wherein the control valve directs the second working fluid to bypass the first heat exchanger when the thermal load of the heat source fluid is greater than the thermal load of the first working fluid.