Method and system for engine windmilling control

The invention claimed is: 1. A method for controlling windmilling of an engine of an aircraft during flight, the engine being an auxiliary power unit of the aircraft, the method comprising: charging a direct current (DC) source during operation of the engine; during flight of the aircraft, determining that the engine is windmilling and that a fire event is occurring in a vicinity of the engine; when the engine is determined to be windmilling, rotational motion of a rotatable component of the engine is caused by the windmilling and the fire event is occurring, controlling the rotational motion of the rotatable component of the engine by: commanding a circuit element to apply a DC signal from the DC source to an electric starter motor coupled to the rotatable component of the engine; and modulating the DC signal applied to the electric starter motor to reduce the rotational motion of the rotatable component of the engine. 2. The method of claim 1 , wherein controlling the rotational motion of the rotatable component of the engine includes short-circuiting terminals of the electric starter motor to cause the electric starter motor to act as a load on the engine. 3. The method of claim 1 , wherein controlling the rotational motion of the rotatable component of the engine includes maintaining a level of the rotational motion within a range suitable for ignition of the engine. 4. The method of claim 1 , comprising modulating the DC signal to prevent the rotational motion. 5. The method of claim 4 , comprising modulating the DC signal to gradually prevent the rotational motion. 6. The method of claim 1 , comprising modulating the DC signal to reduce the rotational motion below a predetermined threshold. 7. The method of claim 6 , wherein the predetermined threshold corresponds to a predetermined rotational speed of the rotatable component of the engine at or below which a lubricant system of the engine is inactive. 8. The method of claim 1 , comprising determining whether the engine is windmilling by: determining whether a commanded engine operating state corresponds to the engine off state; and determining whether the rotational motion exceeds a predetermined windmilling threshold. 9. The method of claim 1 , comprising determining whether the engine is windmilling by determining whether the aircraft to which the engine is coupled is airborne. 10. The method of claim 9 , wherein determining whether the aircraft is airborne comprises determining an altitude of the aircraft. 11. The method of claim 1 , further comprising, prior to commanding the circuit element to apply the DC signal to the electric starter motor, performing a safety test to assess whether the DC signal can be applied safely. 12. An aircraft system comprising: an auxiliary power unit (APU) for supplying electricity and compressed air; a direct current (DC) signal source chargeable during operation of the APU; an electric starter motor coupled to a rotatable component of the APU; a circuit element coupled to the electric starter motor and a DC signal source; and a control system coupled to the APU and to the circuit element, and configured for: determining whether the APU is windmilling by determining that an inlet duct to the APU is in an open position when the APU is in an off state; detecting that a fire event is occurring in a vicinity of the engine; during flight of the aircraft, when the APU is in the off state, and when rotational motion of the rotatable component of the APU is caused by the windmilling and the fire event is occurring, controlling the rotational motion of the rotatable component of the APU by: commanding a circuit element to apply a DC signal from the DC signal source to the electric starter motor coupled to the rotatable component of the APU; and modulating the DC signal applied to the electric starter motor to reduce the rotational motion of the rotatable component of the APU. 13. The aircraft system of claim 12 , wherein the control system is configured for modulating the DC signal to prevent the rotational motion. 14. The aircraft system of claim 13 , wherein the control system is configured for modulating the DC signal to gradually prevent the rotational motion. 15. The aircraft system of claim 12 , wherein the control system is configured for modulating the DC signal to reduce the rotational motion below a predetermined threshold. 16. The aircraft system of claim 15 , wherein the predetermined threshold corresponds to a predetermined rotational speed of the rotatable component of the APU at or below which a lubricant system of the APU is inactive. 17. The aircraft system of claim 12 , wherein determining whether the APU is windmilling comprises: determining whether a commanded operating state of the APU corresponds to the off state; and determining whether the rotational motion exceeds a predetermined windmilling threshold. 18. The aircraft system of claim 12 , wherein determining whether the APU is windmilling comprises determining whether the aircraft is airborne. 19. The aircraft system of claim 18 , wherein determining whether the aircraft is airborne comprises determining an altitude of the aircraft. 20. The aircraft system of claim 12 , further comprising, prior to commanding the circuit element to apply the DC signal to the electric starter motor, performing a safety test to assess whether the DC signal can be applied safely.