Compressor temperature control system and method

We claim: 1. A process for preventing overheating of a compressor in an aircraft air cycle system, the process comprising: receiving bleed air from a bleed air source; compressing the bleed air, thus elevating the air temperature of the bleed air; releasing the air from a compressor outlet; a turbine configured to receive the air from the compressor into a turbine, and expanding the air resulting in a decreasing the air temperature, the expanded air being released from a turbine outlet, and then being introduced into a cabin of the aircraft; positioning a low-limit control valve between the source of bleed air, the turbine outlet, and the cabin; sensing temperature at different locations in the system; a plurality of sensors positioned in different locations in said system; receiving readings from the plurality of sensors and using the readings to determine an extent of openness of the low-limit control valve to enable a portion of the bleed air to bypass the compressor, thus lowering the compressor operating temperature for the purpose of preventing an overheating of the compressor. 2. The process of claim 1 comprising: utilizing whichever of a determined first, second, or third low-limit valve adjustment based on which of the first, second, and third adjustment has the highest value while an air temperature reading from the cabin supply duct is within a normal temperature range. 3. The process of claim 2 , comprising: utilizing the first low-limit adjustment when an air temperature reading from the cabin supply duct is in a temperature range indicative of being close to an overheat condition. 4. The process of claim 3 , comprising: controlling the low limit valve using the first low-limit adjustment if the air-temperature reading from the second and third sensors are invalid. 5. The process of claim 4 , the process further comprising: controlling the low limit valve using the second low-limit adjustment if the air-temperature reading from the first and third sensors are invalid. 6. The process of claim 5 , the process further comprising: controlling the low limit valve using the third low-limit adjustment if the air-temperature reading from the first and second sensors are invalid. 7. The process of claim 1 , wherein the low limit valve is positioned between the turbine exit and the bleed air source. 8. A process for preventing overheating of a compressor in an aircraft air cycle system, the aircraft air cycle system having a low limit control valve, the process comprising: supplying air to the air cycle system from a bleed air source; taking at least one first air temperature reading from a cabin supply duct sensor; determining a first low limit valve adjustment using the first air temperature readings; taking at least one second air temperature reading from a water extractor outlet sensor; determining a second low limit valve adjustment using the second air temperature reading; taking at least one third air temperature reading from a compressor outlet sensor; determining a third low limit valve adjustment using the third air temperature reading; utilizing one of the first, second, and third low-limit valve adjustments depending on system conditions. 9. The process of claim 8 comprising: utilizing whichever of the first, second, and third low-limit valve adjustments has the highest value while the air temperature reading from the cabin supply duct is within a normal temperature range. 10. The process of claim 8 , comprising: utilizing the first low-limit adjustment when an air temperature reading from the cabin supply duct is in a temperature range indicative of being close to an overheat condition. 11. The process of claim 8 , the process further comprising: controlling the low limit valve using the first low-limit adjustment if the air-temperature reading from the second and third sensors are invalid. 12. The process of claim 8 , the process further comprising: controlling the low limit valve using the second low-limit adjustment if the air-temperature reading from the first and third sensors are invalid. 13. The process of claim 8 , the process further comprising: controlling the low limit valve using the third low-limit adjustment if the air-temperature reading from the first and second sensors are invalid. 14. The process of claim 8 , wherein the low limit valve is controlled to a closed position directing air to the air cycle machine. 15. The process of claim 8 , wherein the low limit valve is controlled to an open position directing air to bypass the air cycle machine. 16. The process of claim 8 , wherein the low limit valve is positioned between the turbine exit and the bleed air source. 17. The process of claim 8 , wherein water is extracted from the air by a water extractor positioned prior to the turbine inlet. 18. A process configured to operate in a system having (i) a source of bleed air; (ii) a compressor configured to receive the bleed air from the source, compress the bleed air, thus elevating the air temperature, and release the air from a compressor outlet; (iii) a turbine configured to receive the air from the compressor, and expand the air resulting in a decreased air temperature, the expanded air being released from a turbine outlet, and then being introduced into a cabin of the aircraft; (iv) a low-limit control valve positioned between the source of bleed air, the turbine outlet, and the cabin; (v) a plurality of sensors positioned in different locations in said system; and (vi) a computer processor, the process comprising: receiving readings from the plurality of sensors into the processor, and responsively moving the low-limit control valve to an extent of openness to enable a portion of the bleed air to bypass the compressor, thus lowering the compressor operating temperature for the purpose of preventing an overheating of the compressor.