Question 2.A smooth uniform sphere of mass m and radius r is squeezed between two massless levers, each oflength 1, which are inclined at an angle with the vertical. A mechanism at pivot point O ensuresthat the angles & remain the same at all times so that the sphere moves straight upward. Thisproblem is based on Problem 3-1 in the text.PPrFigure 2a) Draw appropriate freebody diagrams of the system assuming that there is no friction.b) Draw appropriate freebody diagrams of the system assuming that there is a coefficient offriction between the sphere and the right lever of μ.c) If a force P is applied between the ends of the levers (shown in the diagram), and there is nofriction, what is the acceleration of the sphere when = 30°

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Answered: Question 2. A smooth uniform sphere of…

Elements Of Electromagnetics

7th Edition

ISBN:9780190698614

Author:Sadiku, Matthew N. O.

Publisher:Sadiku, Matthew N. O.

ChapterMA: Math Assessment

Section: Chapter Questions

Problem 1.1MA

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For this problem, take a look at Figure 2 below. A disk with uniformly distributed mass m, radius R, and center of mass at point O is connected to a combination of springs at point P, which are then connected to a fixed wall. The disk rolls without slipping at point Q along an inclined plane that is at an angle a from the horizontal. Gravity acts in the vertical direction (towards the bottom of the page). ₁ is the linear coordinate of the point O along the inclined plane. The positive direction of ₁ is as shown. When the springs are undeflected, *₁ = 0. An angle , about the instant center of rotation, is shown. You may assume that the motion (and therefore angle ) is small. puny m Massless structure between springs R Figure 2: System schematic. Your tasks: A Draw the FBD for the disk. Don't forget the forces at point Q B Derive the equation of motion with as the dynamic variable. Be sure to put it in input-output standard form (inputs and constant forces on the right, things related to…
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A weight W= 120 kN is being supported by steel sections with force T, force F, andforce C. The coordinates of A, B, C, and D are given. Assume that E is the origin(0,0,0). Determine Forces T, F, and C. (Hint: Produce three equations fromequilibrium of force system)Note: The Forces T, F, and C must be computed accurately to design the proper sizes ofsteel sections in the subject “Steel Design.”

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