11th Edition

ISBN: 9780135189405

Author: Michael Sullivan

Publisher: PEARSON

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Chapter 3.5, Problem 38AYU

Runaway Car Using Hooke's Law, we can show that the work done in compressing a spring a distance of $x$ feet from its at-rest position is $W = \frac{1}{2} k x^{2}$ , where $k$ is a stiffness constant depending on the spring. It can also be shown that the work done by a body in motion before it comes to rest is given by $\tilde{W} = \frac{w}{2 g} v^{2}$ , Where $w =$ weight of the object (in Ibs), $g =$ acceleration due to gravity( $32.2 f t / \sec^{2}$ ), and $v =$ objectâ€™s velocity (in ft/sec). A parking garage has a spring shock absorber at the end of a ramp to stop runaway cars. The spring has a stiffness constant $k = 9450 l b / f t$ and must be able to stop a 4000-lb car traveling at 25 mph. What is the least compression required of the spring? Express your answer using feet to the nearest tenth.

[Hint: Solve $W > \tilde{W}, x \geq 0$ ].

Source: www.scifonims.com

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Chapter 3.5, Problem 37AYU

Chapter 3.5, Problem 39AYU

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Solution Summary: The author explains that the least compression required of a spring is 4 feet, based on Hooke's Law.

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