2kg is released at point A, from rest on surface inclined at 18° with the horizontal. At the sameA spherical ball of mass m gsph =instant, a cylindrical mass meyl = 1.3kg is launched up the incline with an initial speed of V. = 2.94m/s from point B. At the initialinstant t. (when both masses start motion) the spherical mass is Ah AB = 0.6m higher than the cylinder. The masses can pass eachother without collision. Analyze the rolling motion (without slipping) and then answer the following questions:Calculate the initial distance between both masses:The speed of the spherical mass willincreases +at a rate ofm/s each second on during motion andand itdecreases +for the cylindrical mass at a rate of 2.0209711432122 m/s each second on during motion for the cylindricalmass.m/s each second.It will takesec from the initial instant to for both masses to pass each other.At the instant they pass each other, the cylindrical mass has a speed ofm/s andthe spherical mass rolls atm/8And the total distance covered by the spherical mass from its original position ism when they pass each other.Calculate the maximum elevation of the cylindrical mass from its initial position Ah BEm The solid winding drum in the figure has bearings and loads as shown.Analyse the dynamics of the system with respect to parts in translation and rotation and then calculateThe linear accelerations of masses m1 = 190 kg and m2 = 50 kg as well as the angular acceleration of the drumas well asThe tension in each light rigid rope during acceleration given:ri = 150 mm (the radius at the tangential point between the rope supporting mi ), r2 = 240 mm , k = 200 mm(the radius of inertia of the drum ) and the mass of the drum is 63 kg. A frictional torque of 200 Nm is opposing themotion.• The angular acceleration of the drum is :rad/s?• The linear acceleration of the 190 kg mass ism/s?, and• The linear acceleration of the 50 kg mass ism/s?.• The tension hanging the 190 kg mass isN, andN supports the 50 kg .

As per the bartleyby policy, please find the solution of first question below: Given: The mass of…

A spherical ball of mass m gsph = instant, a cylindrical mass m eyi = 1.3kg is launched up the incline with an initial speed of V. = 2.94m/s from point B. At the initial instant to (when both masses start motion) the spherical mass is Ah AB = 0.6m higher than the cylinder. The masses can pass each 2kg is released at point A, from rest on surface inclined at 18° with the horizontal. At the same other without collision. Analyze the rolling motion (without slipping) and then answer the following questions: Calculate the initial distance between both masses : m The speed of the spherical mass will increases + at a rate of m/s each second on during motion and and it decreases + for the cylindrical mass at a rate of 2.0209711432122 m/s each second on during motion for the cylindrical mass, m/s each second.

A spherical ball of mass m gsph = instant, a cylindrical mass m eyi = 1.3kg is launched up the incline with an initial speed of V. = 2.94m/s from point B. At the initial instant to (when both masses start motion) the spherical mass is Ah AB = 0.6m higher than the cylinder. The masses can pass each 2kg is released at point A, from rest on surface inclined at 18° with the horizontal. At the same other without collision. Analyze the rolling motion (without slipping) and then answer the following questions: Calculate the initial distance between both masses : m The speed of the spherical mass will increases + at a rate of m/s each second on during motion and and it decreases + for the cylindrical mass at a rate of 2.0209711432122 m/s each second on during motion for the cylindrical mass, m/s each second.

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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