Air cycle machine with bearing failure detection

What is claimed is: 1. A bearing monitoring system comprising: thin foil hydrodynamic bearings; a flow passage configured to permit a working fluid to pass over at least one surface of the thin foil hydrodynamic bearings; a first thermocouple located in the flow passage at a first position upstream relative to a segment of the thin foil hydrodynamic bearings and configured to measure a first temperature of the working fluid; a second thermocouple located in the flow passage at a second position downstream relative to the segment of the thin foil hydrodynamic bearings and configured to measure a second temperature of the working fluid; and a control device in communication with the first thermocouple and the second thermocouple, the control device configured to (i) compute a temperature gradient across the thin foil hydrodynamic bearings from the first temperature and the second temperature, (ii) compare the temperature gradient against a known value, and (iii) if the temperature gradient exceeds the known value the control device is configured to provide an alert. 2. The bearing monitoring system of claim 1 , wherein the thin foil hydrodynamic bearings are at least one of journal bearings and thrust bearings. 3. The bearing monitoring system of claim 1 , wherein the known value is about 50° F./10° C. 4. The bearing monitoring system of claim 1 , wherein the thin foil hydrodynamic bearings includes a first thin foil bearing and a second thin foil bearing, wherein the flow passage is configured to permit the working fluid to pass over at least one surface of the first thin foil bearing and at least one surface of the second thin foil bearing, and the first position is upstream of a segment of the first thin foil bearing and the second position is upstream of a segment of the second thin foil bearing. 5. The bearing monitoring system of claim 4 , further comprising: a third thermocouple located in the flow passage at a third position downstream relative to the segment of the second thin foil bearing and configured to measure a third temperature of the working fluid; and the control device is further configured to compute a second temperature gradient from the second temperature and the third temperature, (ii) compare the second temperature gradient against the known value, and (iii) if the second temperature gradient exceeds the known value the control device is configured to provide an alert. 6. The bearing monitoring system of claim 5 , wherein the control device is further configured to determine which of the first thin foil bearing and the second thin foil bearing includes a fault. 7. The bearing monitoring system of claim 4 , further comprising: a third thermocouple located in the flow passage at a third position downstream relative to the segment of the second thin foil bearing and configured to measure a third temperature of the working fluid; a fourth thermocouple located in the flow passage at a fourth position downstream relative to the segment of the first thin foil bearing and upstream relative to the segment of the second thin foil bearing and configured to measure a fourth temperature of the working fluid; and the control device is further configured to compute a second temperature gradient from the third temperature and the fourth temperature, (ii) compare the second temperature gradient against the known value, and (iii) if the second temperature gradient exceeds the known value the control device is configured to provide an alert. 8. The bearing monitoring system of claim 1 , configured with an air cycle machine of an aircraft.