Multi-evaporator trans-critical cooling systems

What is claimed is: 1. A multi-evaporator cooling system, comprising: a compressor circuit that generates multiple levels of evaporating pressures, the circuit comprising at least one compressor configured to compress a refrigerant to a first pressure; a heat exchanger configured to receive the compressed refrigerant from the at least one compressor and cool the compressed refrigerant; a first evaporator circuit configured to receive the compressed refrigerant from the heat exchanger, expand the compressed refrigerant to a second pressure that is lower than the first pressure, and return the refrigerant to the compressor circuit; and a second evaporator circuit configured to receive the compressed refrigerant from the heat exchanger, expand the compressed refrigerant to a third pressure that is lower than the second pressure, and return the refrigerant to the compressor circuit; wherein the first and second evaporator circuits each comprise a respective expansion device and heat load heat exchanger, wherein refrigerant from each heat load heat exchanger passes to a respective first and second ejector at approximately the respective second and third pressures, expands in each of the first and second ejectors, and passes to an inlet of a compressor of the at least one compressor circuit. 2. The cooling system as claimed in claim 1 , wherein the at least one compressor comprises a first compressor that compresses the refrigerant to the first pressure and receives the refrigerant at an inlet thereto from the first evaporator circuit. 3. The cooling system as claimed in claim 2 , wherein: the first evaporator circuit comprises: a first expansion device that expands the compressed refrigerant from the first pressure to the second pressure; and a first evaporator that receives the expanded refrigerant from the first expansion device; and the second evaporator circuit comprises: a second expansion device that expands the compressed refrigerant from the first pressure to the third pressure; and a second evaporator that receives the expanded refrigerant from the second expansion device. 4. The cooling system as claimed in claim 3 , wherein the first evaporator circuit comprises: a first loop that includes the first expansion device; a second loop that includes a first expander that is coupled to the first compressor via a first shaft; and a set of valves arranged to direct refrigerant through the first loop, the second loop, or both the first and second loops based on ambient conditions experienced at least in the heat exchanger. 5. The cooling system as claimed in claim 2 , wherein the at least one compressor comprises a second compressor that compresses the refrigerant to at least the second pressure and receives the refrigerant at an inlet thereto from the second evaporator circuit. 6. The cooling system as claimed in claim 5 , wherein the heat exchanger comprises: a first heat exchanger that receives refrigerant from the first compressor; and a second heat exchanger that receives refrigerant from the second compressor. 7. The cooling system as claimed in claim 1 , wherein the first and second evaporator circuits each comprise a respective expansion device and heat load heat exchanger, wherein refrigerant from each heat load heat exchanger passes to a respective first and second turbine at approximately the respective second and third pressures, expands in each of the first and second turbines, and passes to an inlet of a compressor of the at least one compressor circuit, wherein the compressor is coupled to the first and second turbines via a shaft such that power generated in the first and second turbines drives the compressor. 8. A method of cooling, comprising: generating multiple levels of evaporating pressures in a compressor circuit, the circuit comprising at least one compressor configured to compress a refrigerant to a first pressure; cooling the compressed refrigerant in a heat exchanger from the at least one compressor; receiving the compressed refrigerant from the heat exchanger and in a first evaporator circuit that is configured to expand the compressed refrigerant to a second pressure that is lower than the first pressure, and return the refrigerant to the compressor circuit; and receiving the compressed refrigerant from the heat exchanger and in a second evaporator circuit that is configured to expand the compressed refrigerant to a third pressure that is lower than the second pressure, and return the refrigerant to the compressor circuit; wherein the first and second evaporator circuits each comprise a respective expansion device and heat load heat exchanger, wherein refrigerant from each heat load heat exchanger passes to a respective first and second turbine at approximately the respective second and third pressures, expands in each of the first and second turbines, and passes to an inlet of a compressor of the at least one compressor circuit, wherein the compressor is coupled to the first and second turbines via a shaft such that power generated in the first and second turbines drives the compressor. 9. The method as claimed in claim 8 , further comprising receiving the refrigerant at an inlet of a first compressor from the first evaporator circuit and compressing the refrigerant to the first pressure. 10. The method as claimed in claim 9 , wherein: the first evaporator circuit comprises: a first expansion device that expands the compressed refrigerant from the first pressure to the second pressure; and a first evaporator that receives the expanded refrigerant from the first expansion device; and the second evaporator circuit comprises: a second expansion device that expands the compressed refrigerant from the first pressure to the third pressure; and a second evaporator that receives the expanded refrigerant from the second expansion device. 11. The method as claimed in claim 10 , wherein the first evaporator circuit comprises: a first loop that includes the first expansion device; a second loop that includes a first expander that is coupled to the first compressor via a first shaft; and a set of valves arranged to direct refrigerant through the first loop, the second loop, or both the first and second loops based on ambient conditions experienced at least in the heat exchanger. 12. The method as claimed in claim 9 , further comprising receiving the refrigerant at an inlet of a second compressor from the second evaporator circuit and compressing the refrigerant to at least the second pressure. 13. The method as claimed in claim 12 , wherein the heat exchanger comprises: a first heat exchanger that receives refrigerant from the first compressor; and a second heat exchanger that receives refrigerant from the second compressor. 14. The method as claimed in claim 8 , wherein the first and second evaporator circuits each comprise a respective expansion device and heat load heat exchanger, wherein refrigerant from each heat load heat exchanger passes to a respective first and second ejector at approximately the respective second and third pressures, expands in each of the first and second ejectors, and passes to an inlet of a compressor of the at least one compressor circuit. 15. A cooling system, comprising: at least one heat sink; multiple heat sources; a compressor circuit that generates multiple levels of evaporating pressures; and multiple evaporators coupled with the multiple heat sources to form at least first and second evaporator circuits and configured to operate at the multiple levels of evaporating pressures; wherein the first evaporator circuit in