Gear reaction derived torque measurement

What is claimed is: 1 . A rotorcraft propulsion system comprising: a mast coupled to a rotor assembly; a gear coupled to the mast, the gear during use producing an axial reaction force; a flexure shaft extending from the gear, wherein the flexure shaft does not rotate with the gear and the flexure shaft flexes in response to radial loads from the gear; and a load cell on the flexure shaft to measure the axial reaction force. 2 . The rotorcraft propulsion system of claim 1 , wherein the load cell is in communication with a processor to determine a torque of the gear based on the axial reaction force. 3 . The rotorcraft propulsion system of claim 1 , wherein the flexure shaft is coaxial with the gear and the flexure shaft is not coaxial with the mast. 4 . The rotorcraft propulsion system of claim 1 , wherein the flexure shaft is coaxial with the mast. 5 . The rotorcraft propulsion system of claim 1 , wherein the flexure shaft is a standpipe that extends through the mast to the rotor assembly. 6 . The rotorcraft propulsion system of claim 1 , wherein: the load cell is in communication with a processor to determine a torque of the gear based on the axial reaction force; and the flexure shaft is coaxial with the gear and the flexure shaft is not coaxial with the mast. 7 . The rotorcraft propulsion system of claim 1 , wherein: the load cell is in communication with a processor to determine a torque of the gear based on the axial reaction force; and the flexure shaft is coaxial with the mast. 8 . The rotorcraft propulsion system of claim 1 , wherein: the load cell is in communication with a processor to determine a torque of the gear based on the axial reaction force; and the flexure shaft is a standpipe that extends through the mast to the rotor assembly. 9 . The rotorcraft propulsion system of claim 1 , wherein the gear comprises a first roller bearing and a second roller bearing configured to absorb the radial loads from the gear; and a ball bearing interposed between the gear and the flexure shaft, the ball bearing configured to transfer the axial reaction force and the radial loads from the gear to the flexure shaft. 10 . The rotorcraft propulsion system of claim 1 , further comprising a ball bearing including inner and outer races interposed between the gear and the flexure shaft, the ball bearing configured to transfer the axial reaction force from the gear to the flexure shaft. 11 . The rotorcraft propulsion system of claim 10 , wherein the ball bearing transfers the radial loads from the gear to the flexure shaft. 12 . The rotorcraft propulsion system of claim 10 , wherein the gear further comprises a first collar and a second collar, wherein the ball bearing is interposed between the flexure shaft and the first collar. 13 . The rotorcraft propulsion system of claim 12 , further comprising a first roller bearing coupled to the first collar and a second roller bearing coupled to the second collar, the first roller bearing and the second roller bearing configured to absorb the radial loads from the gear and the ball bearing configured to transfer the radial loads to the flexure shaft. 14 . A rotorcraft comprising: a propulsion assembly coupled to a fuselage, the propulsion assembly comprising: a mast coupled to a rotor assembly; a gear coupled to the mast, the gear during use producing an axial reaction force; a flexure shaft extending from the gear, wherein the flexure shaft flexes in response to radial loads from the gear; a ball bearing rotationally coupling the gear to the flexure shaft, wherein the ball bearing is configured to transfer the axial reaction force and radial loads from the gear to the flexure shaft; and a load cell on the flexure shaft to measure the axial reaction force. 15 . The rotorcraft of claim 14 , wherein the flexure shaft is coaxial with the gear and the flexure shaft is not coaxial with the mast. 16 . The rotorcraft of claim 14 , wherein the flexure shaft is coaxial with the mast. 17 . The rotorcraft of claim 14 , wherein the flexure shaft is a standpipe that extends through the mast to the rotor assembly. 18 . A method comprising: operating a propulsion system to maintain a rotorcraft in flight, the propulsion system including a mast coupled to a rotor assembly, a gear coupled to the mast and producing an axial reaction force, a flexure shaft extending from the gear, a ball bearing rotationally coupling the gear to the flexure shaft and transferring the axial reaction force and radial loads from the gear to the flexure shaft, wherein the flexure shaft flexes in response to the radial loads; measuring the axial reaction force on the flexure shaft and during the flight; and determining a torque of the gear using the axial reaction force. 19 . The method of claim 18 , wherein the flexure shaft is coaxial with the gear and the flexure shaft is not coaxial with the mast. 20 . The method of claim 18 , wherein the flexure shaft is a standpipe that extends through the mast to the rotor assembly.