The 13.3-in. spring is compressed to a 6.9-in. length, where it is released from rest and accelerates the sliding block A. The accelerationhas an initial value of 280 ft/sec² and then decreases linearly with the x-movement of the block, reaching zero when the spring regainsits original 13.3-in. length. Calculate the time t for the block to go (a) 3.2 in. and (b) 6.4 in.-6.9"-13.3"Answers:To go 3.2 in., t=To go 6.4 in., t =isecsec

Answered: Image /qna-images/answer/e6c8bb5c-c876-46dc-ad0c-7df5d330ea97.jpg

Answered: The 13.3-in. spring is compressed to a…

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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The cord is pulled with a force at point A to lift the anvil. The pulley starts from rest. The cord at point A is pulled down 6 ft. Neglect the mass of the pulleys and cords. Hint: 1. The acceleration you find for point A is constant. F₁ A www C W B Values for the figure are given in the following table. Note the figure may not be to scale. Value 15 lb 21 lb Using equations of motion in rectangular coordinates, Variable F₁ W a. Determine the magnitude of acceleration of point B, ap. b. Determine the magnitude of acceleration of point A, aд. c. Determine the time it takes to pull point A down s = 6 ft. Round your final answers to 3 significant digits/figures. Round coefficients in equation/function to 3 significant digits. aB= 66.857 aд 267.428 t = 0.211 X Submit Question X X S Question Help: Video 1% 1%
The x- and y-motions of guides A and B with right-angle slots control the curvilinear motion of the connecting pin P, which slides in both slots. For a short interval, the motions are governed by x = 12 +0.55t² and y= 16-0.57t3, where x and y are in millimeters and t is in seconds. Calculate the magnitudes of the velocity v and acceleration a of the pin for t = 2.5 s. Sketch the direction of the path and indicate its curvature for this instant. B P A| x
ATWOOD'S MACHINE Draw a free body diagram of m1 and another free body diagram of m2. Using these diagrams, apply Newton’s second law to each mass. Assume that the tension is the same on each mass and that they have the same acceleration. From these two equations, find an expression for the acceleration of m1 in terms of m1, m2, and g. Compare the expression to your result in Step 5 of Analysis.

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