Compressor control for increased efficiency

The invention claimed is: 1. A compressor system, comprising: a compressor, wherein the compressor includes one or more mechanical unloaders; a variable frequency drive, connected to the compressor and controlling the speed of the compressor; a mechanical unloader control connected to the one or more mechanical unloaders; at least one sensor measuring operational parameters; a memory configured to store a map of compressor efficiency based on compressor speed and mechanical unloading; and a processor that: receives the operational parameters, first, determines a desired compressor speed from the map of compressor efficiency based on energy consumption to operate the compressor at the desired compressor speed across mechanical unloading levels under the received operational parameters, and directs the variable frequency drive to operate the compressor at the desired compressor speed, then, when operating the compressor at the desired compressor speed, determines whether a compressor capacity exceeds a compressor load, and when the compressor capacity exceeds the compressor load, directs the mechanical unloader control to operate the one or more mechanical unloaders to reduce the capacity of the compressor. 2. The compressor system of claim 1 , wherein the compressor is a screw compressor. 3. The compressor system of claim 1 , wherein the one or more mechanical unloaders comprises a slide valve. 4. The compressor system of claim 1 , wherein the at least one sensor measuring operational parameters comprises a first temperature sensor measuring a suction temperature and a second temperature sensor measuring a discharge temperature. 5. The compressor system of claim 4 , wherein the first temperature sensor is located at an inlet of the compressor. 6. The compressor system of claim 4 , wherein the second temperature sensor is located at an outlet of the compressor. 7. The compressor system of claim 4 , wherein the processor determines whether the compressor capacity exceeds compressor load by comparing the discharge temperature to a set point temperature. 8. A control system for a compressor, comprising: a variable frequency drive; at least one sensor measuring operational parameters; an actuator connected to a mechanical unloader of the compressor; a memory configured to store a map of compressor efficiency based on compressor speed and mechanical unloading; and a processor, connected to the variable frequency drive, the at least one sensor, the actuator, and the memory, wherein the processor: receives operational parameters, first, determines a desired compressor speed from the map of compressor efficiency based on energy consumption to operate the compressor at the desired compressor speed across mechanical unloading levels under the received operational parameters, and provides the desired compressor speed to the variable frequency drive, then, determines whether a compressor capacity exceeds a compressor load, and commands the actuator to reduce the capacity of the compressor using the mechanical unloader when the compressor capacity exceeds the compressor load. 9. The control system of claim 8 , wherein the at least one sensor comprises a first temperature sensor and a second temperature sensor; and the operational parameters comprise a suction temperature measured by the first temperature sensor and a discharge temperature measured by the second temperature sensor. 10. The control system of claim 9 , wherein the processor: receives a current compressor speed from the variable frequency drive, determines a flow rate through the compressor, and wherein determining the desired compressor speed is further based on the flow rate through the compressor. 11. The control system of claim 9 , wherein determining whether a compressor capacity exceeds a compressor load comprises comparing the discharge temperature to a set point temperature. 12. The control system of claim 8 , wherein the mechanical unloader of the compressor is a slide valve. 13. A compressor system, comprising: a compressor, wherein the compressor includes one or more mechanical unloaders; a variable frequency drive, connected to the compressor and controlling the speed of the compressor; a mechanical unloader control connected to the one or more mechanical unloaders; at least one sensor measuring operational parameters; a memory configured to store a map of compressor efficiency based on compressor speed and mechanical unloading; and a processor that: receives the operational parameters, determines a desired compressor speed from the map of compressor efficiency based on energy consumption without respect to the mechanical unloading component of the map to operate the compressor at the desired compressor speed under the received operational parameters, directs the variable frequency drive to operate the compressor at the desired compressor speed, determines whether a compressor capacity exceeds a compressor load when operating the compressor at the desired compressor speed, and directs the mechanical unloader control to operate the one or more mechanical unloaders to reduce the capacity of the compressor when the compressor capacity exceeds the compressor load. 14. A control system for a compressor, comprising: a variable frequency drive; at least one sensor measuring operational parameters; an actuator connected to a mechanical unloader of the compressor; a memory configured to store a map of compressor efficiency based on compressor speed and mechanical unloading; and a processor, connected to the variable frequency drive, the at least one sensor, the actuator, and the memory, wherein the processor: receives operational parameters, determines a desired compressor speed from the map of compressor efficiency based on energy consumption without respect to the mechanical unloading component of the map to operate the compressor at the desired compressor speed under the received operational parameters, provides the desired compressor speed to the variable frequency drive, determines whether a compressor capacity exceeds a compressor load, and commands the actuator to reduce the capacity of the compressor using the mechanical unloader when the compressor capacity exceeds the compressor load. 15. A method for controlling the capacity of a compressor, comprising: receiving operational parameters; based on the operational parameters, retrieving a map of compressor efficiency based on compressor speed and mechanical unloading; first, determining a desired compressor speed from the map of compressor efficiency based on energy consumption to operate the compressor at the desired compressor speed across mechanical unloading levels under the received operational parameters; and commanding a variable frequency drive to operate the compressor at the desired compressor speed; then, when the compressor is operating at the desired compressor speed, comparing a compressor capacity to a compressor load; and when the compressor capacity exceeds the compressor load, increasing the extent to which one or more mechanical unloaders reduce the capacity of the compressor. 16. The method of claim 15 , wherein the operational parameters comprise a suction temperature from a first temperature sensor and a discharge temperature from a second temperature sensor. 17. The method of claim 16 , wherein the first temperature sensor is located at an inlet of the compressor. 18. The method of claim 16 , wherein the second temperature sensor is located at an