Scroll compressors with different volume indexes and systems and methods for same

What is claimed is: 1. A compressor arrangement, comprising: a plurality of refrigerant compressors connected in parallel circuit, each refrigerant compressor having a volume index, the plurality of refrigerant compressors including at least a first compressor and a second compressor, wherein each of the first compressor and the second compressor include a single inlet, a single outlet, and a single flowpath extending between the single inlet and the single outlet, and wherein each of the first compressor and the second compressor includes a housing and a respective internal electrical motor to drive a respective compressor body contained within said housing, the first compressor having a different volume index than the second compressor, wherein the volume index of the first compressor and the second compressor is fixed and non-variable, and wherein the plurality of compressors share a common suction line and share a common discharge line, each of the respective compressor bodies of the first and second compressors being driven only by the respective internal electrical motor thereof. 2. The compressor arrangement of claim 1 , wherein the first and second compressors are scroll compressors. 3. The compressor arrangement of claim 2 , wherein in relative relation between the first and second compressors, each first compressor has a higher isentropic efficiency at a high temperature range for saturated condensing temperature, and wherein each second compressor has a higher isentropic efficiency at a low temperature range for saturated condensing temperature, the high temperature range being higher than the low temperature range. 4. The compressor arrangement of claim 3 , wherein each first compressor is substantially optimized for air cooling, and wherein each second compressor is substantially optimized for water cooling. 5. The compressor arrangement of claim 3 , further comprising: a controller in operative communication with the refrigerant compressors for individually turning refrigerant compressors on and off; the controller configured to selectively operate the first and second compressors in response to a demand load and a determination of different saturated condensing temperature conditions. 6. The compressor arrangement of claim 5 , wherein the controller selects between the first and second compressors or combination thereof based on maximizing isentropic efficiency. 7. The compressor arrangement of claim 6 , wherein, when determined to be in the high temperature range, the controller operating the first compressor to the extent necessitated by the demand load, and operating the second compressor only as necessary to meet the demand load when the first compressor is already operating; and when determined to be in the low temperature range, the controller operating the second compressor to the extent necessitated by a demand load, and operating the first compressor only as necessary to meet the demand load when the second compressor is already operating. 8. The compressor arrangement of claim 5 , further comprising at least one sensor adapted to sense an environmental condition indicative of the high and low temperature ranges, the sensor in communication with the controller, the controller determining whether a high or low temperature range exists based on sensed environmental conditions of the at least one sensor. 9. The compressor arrangement of claim 8 , wherein the plurality of refrigerant compressors is integrated in a cooling system, the cooling system including: an expansion unit including an expansion valve and an expansion unit heat exchanger, the expansion unit arranged in fluid series with the plurality of refrigerant compressors; and a condenser interposed between the expansion unit and the plurality of refrigerant compressors; wherein the plurality of refrigerant compressors compress a refrigerant fluid, which is condensed in the condenser, then expanded in the expansion unit and then returned to the plurality of refrigerant compressors. 10. The compressor arrangement of claim 9 , wherein said at least one sensor is a pressure sensor in communication with a refrigerant suction line upstream of the plurality of refrigerant compressors, the controller determining whether a high or low temperature range exists based upon sensed pressure. 11. The compressor arrangement of claim 10 , wherein the controller selectively operates the first and second compressors on a factor other than maximizing isentropic efficiency when in an intermediate temperature range intermediate of the high and low temperature ranges. 12. The compressor arrangement of claim 5 , wherein the controller uses the demand load to determine saturated condensing temperature, wherein the demand load is indicative of saturated condensing temperature with a relative higher demand load indicating a higher saturated condensing temperature and a relative lower demand load indicating a lower saturated condensing temperature. 13. The compressor arrangement of claim 5 , wherein the controller uses at least one of a temperature sensor and seasonal date information to determine saturated condensing temperature. 14. The compressor arrangement of claim 2 , further comprising a common mounting rail, with both first and second refrigerant compressors commonly mounted on the mounting rail. 15. The compressor arrangement of claim 1 , wherein the compressor housing of the first compressor completely encloses compressor bodies of the first compressor and wherein the compressor housing of the second compressor completely encloses compressor bodies of the second compressor. 16. The compressor arrangement of claim 1 , further comprising a common refrigerant suction pipe connecting inlet ports of each of the refrigerant compressors in a bank, and a compressed refrigerant pipe connecting the outlet ports of each of the refrigerant compressors in the bank. 17. The compressor arrangement of claim 1 , wherein the first and second compressors are screw compressors. 18. The compressor arrangement of claim 1 , further comprising an expansion unit, wherein the expansion unit is operable independent of the plurality refrigerant compressors. 19. The compressor arrangement of claim 1 , wherein the plurality of refrigerant compressors is arranged in a first bank of compressors, and a second plurality of refrigerant compressors is arranged in a second bank of compressors, the second bank of compressors being independently operable from the first bank of compressors. 20. A method of compressing refrigerant, comprising: arranging at least two refrigerant compressors in fluid parallel having different built in fixed, non-variable volume indexes, wherein each compressor of the at least two compressors has a single inlet, a single outlet, and a single flowpath extending between the inlet and the outlet, and wherein each of the at least two compressors includes a housing and a respective internal independent electrical motor to drive a respective compressor body contained within said housing, and wherein the plurality of compressors share a common suction line and share a common discharge line, each of the respective compressor bodies of the at least two compressors being driven only by the respective internal independent electrical motor thereof; and selectively operating the at least two refrigerant compressors based on saturated condensing temperature. 21. The method of claim 20 , further comprising: sensing a suction pressure upstream of the at least refr