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m = 2.7 kg k = 398 N/m δ = 38 mm θ = 25∘ Find the amount which the spring is compressed after the mass comes to rest. Assume a kinetic coefficient of friction of 0.13 and an initial velocity along the surface of v = 2 m/s. Answer:

m = 2.7 kg k = 398 N/m δ = 38 mm θ = 25∘ Find the amount which the spring is compressed after the mass comes to rest. Assume a kinetic coefficient of friction of 0.13 and an initial velocity along the surface of v = 2 m/s. Answer:

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m = 2.7 k g k = 398 N / m δ = 38 m m θ = 25 Find the amount which the spring is compressed after the mass comes to rest. Assume a kinetic coefficient of friction of 0.13 and an initial velocity along the surface of v = 2 m / s .
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