Assume that the coupling between the motor and the inertial load of Problem 14.33 is flexible...

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Assume that the coupling between the motor and the inertial load of Problem 14.33 is flexible (e.g., a long shaft). This can be modeled by adding a torsional spring between the motor inertia and the load inertia. Now we can no longer lump together the two inertias and damping coefficients as if they were one; we need to write separate equations for the two inertias. In total, there will be three equations in this system the motor electrical equation, the motor mechanical equation (Jim and Bm), and the load mechanical equation (J and B). a. Sketch a diagram of the system. b. Use free-body diagrams to write each of the two mechanical equations. Set up the equations in matrix form. c. Compute the transfer function from input voltage to load inertia speed, using the method of determinants. Assume that the coupling between the motor and the inertial load of Problem 14.33 is flexible (e.g., a long shaft). This can be modeled by adding a torsional spring between the motor inertia and the load inertia. Now we can no longer lump together the two inertias and damping coefficients as if they were one; we need to write separate equations for the two inertias. In total, there will be three equations in this system the motor electrical equation, the motor mechanical equation (Jim and Bm), and the load mechanical equation (J and B). a. Sketch a diagram of the system. b. Use free-body diagrams to write each of the two mechanical equations. Set up the equations in matrix form. c. Compute the transfer function from input voltage to load inertia speed, using the method of determinants.

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A mechanical system problem a Sketch a diagram of the system The system consists of a motor a flexib... View the full answer