Answer Step-wise with detailed explantions Please Answer the following question step-wise with detailed explanations. Thanks in advance A bar of mass m = 25 kg and length L = 3 m is bound to a wall by a pin; the other end B of the bar is supported by a rope to the point C of the wall by means of a rope which forms an angle q = 35° with the horizontal direction. A mass M = 35 kg is placed on the distance x from the wall. Calculate: a) the wire tension as a function of x; b) the binding reaction of the pin; c) assuming that Tmax = 650 N, determine the maximum distance xmax from the wall that the system can tolerate [Xmax = 2.20 m]

Answer Step-wise with detailed explantions Please Answer the following question step-wise with detailed explanations. Thanks in advance A bar of mass m = 25 kg and length L = 3 m is bound to a wall by a pin; the other end B of the bar is supported by a rope to the point C of the wall by means of a rope which forms an angle q = 35° with the horizontal direction. A mass M = 35 kg is placed on the distance x from the wall. Calculate: a) the wire tension as a function of x; b) the binding reaction of the pin; c) assuming that Tmax = 650 N, determine the maximum distance xmax from the wall that the system can tolerate [Xmax = 2.20 m]

Mechanics of Materials (MindTap Course List)

9th Edition

ISBN:9781337093347

Author:Barry J. Goodno, James M. Gere

Publisher:Barry J. Goodno, James M. Gere

Chapter2: Axially Loaded Members

Section: Chapter Questions

Problem 2.2.16P: A uniform bar AB of weight W = 25 N is supported by two springs, as shown in the figure. The spring...

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