Method for air flow fault and cause identification

What is claimed is: 1. A method of identifying faults in an air-cooled system, the air-cooled system including a first temperature sensor configured to detect a temperature of an exhaust heat, a second temperature sensor configured to detect a temperature of a heat sink secured to a heat-generating component, the heat sink having fins, each with a surface area configured to transfer heat to or from air surrounding the heat sink, and an air flow sensor configured to detect a rate of air flow through an air-cooling device, the method comprising: measuring a first series of temperatures with the first temperature sensor to produce a first time series of first measured temperature values; measuring a second series of temperatures with the second temperature sensor to produce a second time series of second measured temperature values; measuring a series of rates of air flow with the air flow sensor to produce a time series of measured air flow rate values; and identifying a fault in response to at least one of: the first time series of the first measured temperature values being outside an acceptable range of a first target value, the second time series of the second measured temperature values being outside an acceptable range of a second target value, and the time series of the measured air flow rate values being outside an acceptable range of a third target value. 2. The method of claim 1 , wherein identifying the fault includes calculating a difference between consecutive measured values in the first time series to produce a first series of consecutive difference values related to the first measured temperature. 3. The method of claim 2 , wherein identifying the fault includes calculating a difference between consecutive measured values in the second time series to produce a second series of consecutive difference values related to the second measured temperature. 4. The method of claim 3 , wherein identifying the fault includes calculating a difference between consecutive measured values in the time series of the measured air flow rate to produce a series of consecutive difference values related to the measured air flow rate. 5. The method of claim 4 , further comprising determining a first type of fault based upon: the first series of consecutive difference values related to the first measured temperature are above the acceptable range of the first target value, the second series of consecutive difference values related to the second measured temperature are above the acceptable range of the second target value, and the series of consecutive difference values related to the measured air flow rate are within the acceptable range of the third target value. 6. The method of claim 4 , further comprising determining a second type of fault based upon: the first series of consecutive difference values related to the first measured temperature are within the acceptable range of the first target value, the second series of consecutive difference values related to the second measured temperature are above the acceptable range of the second target value, and the series of consecutive difference values related to the measured air flow rate are within the acceptable range of the third target value. 7. The method of claim 4 , further comprising determining a third type of fault based upon: the first series of consecutive difference values related to the first measured temperature are above the acceptable range of the first target value, the second series of consecutive difference values related to the second measured temperature are above the acceptable range of the second target value, and the series of consecutive difference values related to the measured air flow rate are below the acceptable range of the third target value. 8. The method of claim 4 , further comprising determining a fourth type of fault based upon: at least one consecutive difference value related to the measured air flow rate is below the acceptable range of the third target value. 9. The method of claim 1 , wherein the air-cooled system further includes a third temperature sensor configured to detect a temperature of ambient air, the method further comprising measuring a third series of temperatures with the third temperature sensor to produce a third time series of third measured temperature values. 10. The method of claim 9 , wherein the first target value is created by calculating a predicted exhaust heat temperature and the second target value is created by calculating a predicted heat sink temperature. 11. The method of claim 10 , wherein the predicted exhaust heat temperature and predicted heat sink temperature are calculated by a prediction model, the prediction model configured to generate the predicted exhaust heat temperature and predicted heat sink temperature based upon the time series of measured air flow rate values, the third time series of third measured temperature values, a system load value, and design parameters of the air-cooled system. 12. The method of claim 11 , wherein the prediction model is based upon an energy balance relationship according to the equation: Q=cmΔT. 13. A detection system for identifying faults in an air-cooled system of the type used to cool air-cooled equipment having a heat sink secured to a heat-generating component, the heat sink having fins, each with a surface area configured to transfer heat to or from air surrounding the heat sink, the detection system comprising: an air-cooling device configured to direct air over the heat sink; a first temperature sensor configured to detect a temperature of an exhaust heat associated with the air-cooled equipment; a second temperature sensor configured to detect a temperature of the heat sink; an air flow sensor configured to detect a rate of air flow through the air-cooling device; and a controller in communication with the first temperature sensor, the second temperature sensor, and the air flow sensor, the controller being configured to measure a first series of temperatures with the first temperature sensor to produce a first time series of first measured temperature values, measure a second series of temperatures with the second temperature sensor to produce a second time series of second measured temperature values, measure a series of rates of air flow with the air flow sensor to produce a time series of measured air flow rate values, and identify a fault in response to at least one of: the first time series of the first measured temperature values being outside an acceptable range of a first target value, the second time series of the second measured temperature values being outside an acceptable range of a second target value, and the time series of the measured air flow rate values being outside an acceptable range of a third target value. 14. The detection system of claim 13 , wherein identifying the fault includes calculating a difference between consecutive measured values in the first time series to produce a first series of consecutive difference values related to the first measured temperature, calculating a difference between consecutive measured values in the second time series to produce a second series of consecutive difference values related to the second measured temperature, and calculating a difference between consecutive values in the time series of the measured air flow rate values to produce a series of consecutive difference values related to the measured air flow rate. 15. The detection system of claim 14 , wherein the controller is configured to determine a first type of fault based upon: the fir