Massachusetts Institute of Technology Department of Ocean Engineering Department of Civil and Environmental Engineering 13.013J/1.053J Dynamics and Vibration Fall 2002 Quiz I • “Closed book and notes”, one sheet of formulas allowed. • Individual effort. • Read all problems first. • This quiz contains 6 printed pages.Figure for Problem 1: M L m v g O d 2Problem 1: (50 Points) A pendulum of mass M with a massless rigid rod of length L hanging from a fixed frictionless pin O is initially at rest in a field with acceleration due to gravity g. The mass M can be considered as a point mass (particle with negligible dimensions). A particle of mass m and horizontal velocity v flying at a vertical distance d from the pin collides with the pendulum rod and sticks to it. a) a i. Explain why kinetic energy and linear momentum are not in general conserved during the collision. a ii. Determine the angular velocity and kinetic energy of the system immediately after the collision, and the kinetic energy loss during the collision, as a fraction of the initial kinetic energy of the mass m. a iii. Determine the impulse from the pin O on the rod during the time of the collision. C 0+ Hint: Impulse is the integral of the force F (t) over the time of collision J = — F (t) dt , 0− assuming the time interval of collision is very small. (2 + 10 + 5 = 17 Points) b) Determine the second order (nonlinear) ordinary differential equation of motion of the system after the collision. The motion can be described in terms of the angle θ(t) the rod makes with the vertical line through O. (10 Points) c) c i. Determine the maximum angle θmax the pendulum will make with the vertical after the collision. c ii. Determine under what condition for the initial speed v will the maximum angle of the pendulum after collision be equal to πradians. (5 + 3 = 8 Points) d) Determine an expression for the force from the rod on the pin after the collision as a function of θ(t). #Hint: Eliminate any dependence on θ(t) and leave only the dependence on θ(t) using an appropriate conservation law valid after the collision. (10 Points) e) Determine an integral expression for the time that will elapse between the collision and the maximum angle θmax of question (c i). Hint: Using an appropriate conservation law valid after the collision (just as in question d), express dθ= f (θ) , where f(θ) is a function of θ. dt (5 Points) 3Figure for Problem 2: P Y Z X O y z x G Rh Ω θ(t) L Head Seas z1 x1 Figure for Problem 2c, 2d: x z y G R T P Mussel x1 z1 y1 φ(t) 4Problem 2: (50 Points) A ship is traveling at a constant velocity Vmean with respect to the earth, along the axis OX, where OXYZ C C C is an inertial system (with unit vectors I , J , K ) attached to the earth. A moving system Gxyz (with unit C CC vectors i , j, k ) is attached to the ship at its center of gravity G, so that the axis Gx makes an angle θ(t) to the horizontal axis OX. Due to head seas (a storm with waves whose crests are parallel to OY axis and propagating along OX axis) the ship oscillates in the vertical plane heaving and surging, and rotates about an axis orthogonal to its center plane (ie. pitching). The velocity of G with respect to the inertial frame is C VG = Vmean I + u(t)i + w(t)k where u(t) and w(t) are the surge and heave velocities of the ship. The angular velocity of the ship with C • respect to OXYZ is ω=ω2(t)J , where ω2(t) =θ(t) , also known as pitch angular velocity. At the same time the ship’s propeller of radius R is rotating with its shaft at a constant angular velocity Ω with respect to the ship, ie. Cωpropeller, ship = Ωi a) Determine the inertial velocity vp and acceleration ap of the center of the propeller, P using the ship C fixed system Gxyz for your calculations. For simplicity of algebra express vp = VmeanI +αi +βk and C ap =γi +δk , and determine α, β, γand δ. (15 Points) b) Determine the angular velocity of the propeller with respect to OXYZ and its time rate of change with respect to OXYZ. (5 Points) c) The line PT makes an angle φ(t) with the Y direction (same as direction y1) and assume, for simplicity #that the line PT is on a plane Py1z1 parallel to the plane Gyz. Note that φ(t) =Ω. Find the inertial velocity vT and the acceleration aT of the tip T for an arbitary φ(t) and in particular when φ= 3π , ie. when the tip 2 T is at the lowest point. Hint: Use a system Px1y1z1 fixed to the ship with origin at the propeller center P and with the axes parallel to Gxyz, respectively. (20 Points) d) Imagine that a mussel of mass m happens to be attached to the tip T, of the propeller. For the 3π condition of question (c) and φ= find the contact force from the blade on the mussel assuming the 2 (static and dynamic) fluid force on the mussel is known and equal to Ff (t) . Note that the acceleration of gravity is g. Assume that the propeller does not emerge from the ocean surface during the oscillations of the ship. (10 Points)