Spring Potential Energy: Difference between revisions
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s= 1.5 m | s= 1.5 m | ||
'''U<sub>s'''=(.5)k<sub>ss<sup>2 | '''U<sub>s'''=(0.5)k<sub>ss<sup>2 | ||
'''U<sub>''' | |||
'''U<sub>s'''= (0.5)(200 N/m)(1.5 m)<sup>2 | |||
'''U<sub>s'''= 225 J | '''U<sub>s'''= 225 J | ||
===Middling=== | ===Middling=== | ||
A horizontal spring with stiffness 0.6 N/m has a relaxed length of 10 cm. A mass of 25 g is attached and you stretch the spring to a length of 20 cm. The mass is released and moves with little friction. What is the speed of the mass at the moment when the spring returns to its relaxed length of 10cm? | |||
k<sub>s= 0.6 N/m | |||
s= 0.1 m | |||
'''U<sub>s'''=(.5)k<sub>ss<sup>2 | |||
'''U<sub>s'''= (.5)(0.6 N/m)(0.1 m)<sup>2 | |||
'''U<sub>s'''= 0.003 J | |||
Potential Energy is Converted into Kinetic Energy (K): | |||
'''U<sub>s'''= K | |||
'''K'''=(0.5)mv<sup>2 | |||
'''U<sub>s'''=(0.5)mv<sup>2 | |||
0.003 J=(0.5)(0.025 kg)v<sup>2 | |||
'''v<sup>2'''=<sup>(0.003 J)</sup>⁄<sub>((0.5)(0.025 kg)</sub> | |||
'''v<sup>2'''=0.24 J/kg*s | |||
'''v'''=0.49 m/s | |||
===Difficult=== | ===Difficult=== | ||
Revision as of 20:40, 5 December 2015
Work in progress by scarswell3 This topic covers Spring Potential Energy.
The Main Idea
Elastic Potential Energy is the energy stored in elastic materials due to their deformation. Often this refers to the stretching or compressing of a spring.
A Mathematical Model
The formula for Ideal Spring Energy is: Us=1⁄2kss2 where: ks= spring constant s2= stretch measured from the equilibrium point;
A Computational Model
An oscillating spring can be modeled by the following:
from __future__ import division from visual import * from visual.graph import * scene.width=600 scene.height = 760 g = 9.8 mball = .2 Lo = 0.3 ks = 12 deltat = 1e-3 t = 0 ceiling = box(pos=(0,0,0), size = (0.5, 0.01, 0.2)) ball = sphere(pos=(0,-0.3,0), radius=0.025, color=color.yellow) spring = helix(pos=ceiling.pos, color=color.green, thickness=.005, coils=10, radius=0.01) spring.axis = ball.pos - ceiling.pos vball = vector(0.02,0,0) ball.p = mball*vball scene.autoscale = 0 scene.center = vector(0,-Lo,0) while t < 10: rate(1000) L_vector = (mag(ball.pos) - Lo)* ball.pos.norm() Fspring = -ks * L_vector Fgrav = vector(0,-mball * g,0) Fnet = Fspring + Fgrav ball.p = ball.p + Fnet * deltat ball.pos = ball.pos + (ball.p/mball) * deltat spring.axis = ball.pos-ceiling.pos t = t + deltat
Examples
Be sure to show all steps in your solution and include diagrams whenever possible
Simple
If a spring's spring constant is 200 N/m and it is stretched 1.5 meters from rest, what is the potential spring energy?
ks= 200 N/m s= 1.5 m
Us=(0.5)kss2
Us= (0.5)(200 N/m)(1.5 m)2
Us= 225 J
Middling
A horizontal spring with stiffness 0.6 N/m has a relaxed length of 10 cm. A mass of 25 g is attached and you stretch the spring to a length of 20 cm. The mass is released and moves with little friction. What is the speed of the mass at the moment when the spring returns to its relaxed length of 10cm?
ks= 0.6 N/m s= 0.1 m
Us=(.5)kss2
Us= (.5)(0.6 N/m)(0.1 m)2
Us= 0.003 J
Potential Energy is Converted into Kinetic Energy (K):
Us= K
K=(0.5)mv2
Us=(0.5)mv2
0.003 J=(0.5)(0.025 kg)v2
v2=(0.003 J)⁄((0.5)(0.025 kg)
v2=0.24 J/kg*s
v=0.49 m/s
Difficult
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