kindly solve asap A thin semi-circular pipe has been bent in the shape of a semicircle of radius R and is held fixed. Anideal spring is inserted inside the pipe as shown in figure. Two balls, each of mass m, are released attwo ends of the pipe and the system is allowed to settle in equilibrium (see second figure). Inequilibrium, compression in the spring is found to be x. Find force constant (k) of the spring.verticaldown(A) k=-mg(B) k =-mgcoscos2.x2RR(C) k =mg(D) k=mgcoscos2x2R2R

Draw the free body diagram of the of the given arrangement: Note from the figure: θ=x2R=x2R

A thin semi-circular pipe has been bent in the shape of a semicircle of radius R and is held fixed. A ideal spring is inserted inside the pipe as shown in figure. Two balls, each of mass m, are released two ends of the pipe and the system is allowed to settle in equilibrium (see second figure). equilibrium, compression in the spring is found to be x. Find force constant (k) of the spring. vertical down mg cos R mg (A) k =- cos (B) k= 2x 2R (C) k = mg (D) k=- mg cos cos 2x 2R 2R

A thin semi-circular pipe has been bent in the shape of a semicircle of radius R and is held fixed. A ideal spring is inserted inside the pipe as shown in figure. Two balls, each of mass m, are released two ends of the pipe and the system is allowed to settle in equilibrium (see second figure). equilibrium, compression in the spring is found to be x. Find force constant (k) of the spring. vertical down mg cos R mg (A) k =- cos (B) k= 2x 2R (C) k = mg (D) k=- mg cos cos 2x 2R 2R

International Edition---engineering Mechanics: Statics, 4th Edition

4th Edition

ISBN:9781305501607

Author:Andrew Pytel And Jaan Kiusalaas

Publisher:Andrew Pytel And Jaan Kiusalaas

Chapter4: Coplanar Equilibrium Analysis

Section: Chapter Questions

Problem 4.125P: The figure shows a three-pin arch. Determine the horizontal component of the pin reaction at A...

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