System and method for a variable speed cooling fan on a skid mounted compressor

The invention claimed is: 1. A system for powering a fan heat exchanger said system comprising: an equipment skid; an internal combustion engine mounted on the equipment skid and an engine cooling system that cools the engine by an engine cooling fluid; a compressor mounted on the equipment skid, powered by the internal combustion engine and connectable to a source of gas so that operation of the compressor produces compressed gas; a cooler mounted on the equipment skid, the cooler including one cooling stage connected to the engine cooling system to receive the engine cooling fluid and an other cooling stage connected to the compressor to receive the compressed gas, the cooler also including a fan powered by the internal combustion engine via a variable speed electromagnetic drive to direct air flow across the one cooling stage to remove heat from the engine cooling fluid and across the other cooling stage to remove heat from the compressed gas; a plurality of temperature sensors including one temperature sensor positioned to determine a temperature of an output of the one cooling stage and an other sensor positioned to determine a temperature of an output of the other cooing stage; and at least one adjusting device connected to the variable speed electromagnetic drive and operable in response to the temperature determined by the one sensor and the other sensor to operate the variable speed electromagnetic drive in a way that increases a speed of rotation of the rotating fan when the temperature detected by at least one of the plurality of temperature sensors exceeds a predetermined temperature to thereby increase the speed of rotation of the rotating fan and produce increased air flow across the one cooling stage and the other cooling stage to increase an amount of heat removed from the compressed gas and the engine cooling fluid. 2. The system of claim 1 further comprising: a first pulley mounted on the crankshaft of the internal combustion engine; a second pulley mounted on the variable speed electromagnetic drive and aligned with the first pulley; and a belt interconnecting the first and second pulley and capable of transmitting rotational energy from the first pulley to the second pulley. 3. The system of claim 2 wherein the compressor comprises at least a first compression stage and a second compression stage for compressing the gas; wherein the one cooling stage is a first cooling stage, an output of the first compression stage is in fluid communication with an input of the first cooling stage, the output of the first cooling stage is in fluid communication with an input of the second compression stage and an output of the second compression stage is in fluid communication with an input on a second cooling stage. 4. The system of claim 3 wherein the one temperature sensor is a first temperature sensor and further comprising a second temperature sensor at the output of the second cooling stage; the adjusting device including one or more electric solenoids operable to adjust the speed of rotation of the fan; and a controller in electronic communication with the first and second temperature sensors and the one or more solenoids; wherein when the temperature of the first temperature sensor or the second temperature sensor exceeds the predetermined temperature, the controller controls operation of the one or more electric solenoids to increase the speed of rotation of the fan. 5. The system of claim 4 further comprising: an idler pulley operable to provide tension in the belt. 6. The system of claim 4 further comprising: a third cooling stage in the cooler, the other cooling stage being a fourth cooling stage; wherein the third cooling stage is in fluid communication with an outlet on an intercooler and an inlet of the intercooler, and the fourth cooling stage is in fluid communication with an engine cooling fluid outlet on the internal combustion engine and an engine cooling fluid inlet on the internal combustion engine. 7. The system of claim 1 wherein the adjusting device is an electric solenoid that adjusts the variable speed electromagnetic drive so that the variable speed electromagnetic drive causes the rotating fan to continue rotating, but at a faster or slower speed of rotation. 8. The system of claim 1 wherein the adjusting device is an electric solenoid that adjusts a distance between two plates in the variable speed electromagnetic drive to change the speed of rotation of the rotating fan so that the rotating fan rotates faster or slower. 9. The system of claim 1 wherein the adjusting device is operable to alternatively increase and decrease slippage between two parts of the variable speed electromagnetic drive so that the increase in the slippage causes the rotating fan to continue rotating but at a slower speed of rotation, and the decrease in the slippage causes the rotating fan to continue rotating but at a faster speed of rotation. 10. A method for driving a fan on a skid mounted fan heat exchanger, the method comprising: directing gas to a compressor provided on an equipment skid and driven by operation of an internal combustion engine, the equipment skid also being provided with a cooler that includes the fan, the internal combustion engine including a cooling system that utilizes a engine cooling fluid to cool the internal combustion engine; compressing the gas through operation of the compressor to produce compressed gas; cooling the compressed gas produced by the compressor in a gas cooling stage by air flow produced through rotation of the fan and cooling the engine cooling fluid from the internal combustion engine in a fluid cooling stage by the air flow produced through rotation of the fan, the fan being rotated by operation of the internal combustion engine via a magnetic variable speed clutch; measuring a temperature of an output of the gas cooling stage and measuring a temperature of an output of the fluid cooling stage; and increase a speed of rotation of the rotating fan when the temperature measured at the output of the gas cooling stage and/or when the temperature measured at the output of the fluid cooling stage exceeds a predetermined temperature to thereby increase the speed of rotation of the rotating fan and produce increased air flow across the gas cooling stage and the fluid cooling stage to increase an amount of heat removed from the compressed gas and the engine cooling fluid, and the increase of the speed of rotation of the rotating fan comprising operating at least one adjusting device connected to the variable speed electromagnetic drive to operate the variable speed electromagnetic drive in a way that increases the speed of rotation of the rotating fan. 11. The method of claim 10 further comprising: providing a belt between a drive pulley on a crank shaft of the internal combustion and the magnetic variable speed clutch. 12. The method of claim 11 further comprising: measuring the temperature at the output of the gas; and decreasing the speed of rotation of the rotating fan when the temperature measured at the output of the gas cooling stage drops below a predetermined level. 13. The method of claim 11 further comprising: a turbo powered by exhaust leaving the internal combustion engine to produce pressurized air, and an intercooler that cools the pressurized air by intercooler cooling fluid, the method further comprising measuring the temperature of the intercooler cooling fluid; and increasing the speed of rotation of the rotating fan when the measured temperature of the intercooler cooling fluid exceeds a predetermined level. 14. The