PARTS C & D ONLY *** Solve carefully and label both parts (circle final answer(s) (Use image Below) The following figure shows a mass-spring-damper system that will be used in the following problems. The springs have an initial deflection of 0.05 m, and the mass has an initial velocity of 10. There is no friction. m S eecee eelee Part C- Write out the equations of motion for this torsional system, but with the equivalent variables for a torsional system (use kT,1 instead of k1, torque t instead of F, etc.). Part D - Set k1= k2 = 0. Rewrite the equations such that everything is in terms of velocity v and v, and remove the deflection's equation if you have one. Solve this equation to determine v over time, with the following parameters: m = 4, c = 5 and F = 20t + 1. %3D %3D %3D

2 Parts ( C & D) in image below read & and solve carefully.

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PARTS C & D ONLY *** Solve carefully and label both parts (circle final answer(s) (Use image Below) The following figure shows a mass-spring-damper system that will be used in the following problems. The springs have an initial deflection of 0.05 m, and the mass has an initial velocity of 10. There is no friction. ki eelee Kz eelee Part C- Write out the equations of motion for this torsional system, but with the equivalent variables for a torsional system (use kT,1 instead of k1, torque t instead of F, etc.). Part D - Set k1= k2 = 0. Rewrite the equations such that everything is in terms of velocity v and v, and remove the deflection's equation if you have one. Solve this equation to determine v over time, with the following parameters: m = 4, c = 5 and F = 20t + 1.