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Composition Setup

Excerpt
hiddentrue

Energy and springs.

A certain spring-loaded gun is cocked by compressing its spring by 5.0 cm. The gun fires a 4.0 g projectile with a speed of 8.0 m/s. What spring constant is required for the spring?

Solution

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idsys
System:
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idsys

Projectile as plus the gun as a rigid body of infinite mass.

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idint
Interactions:
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The conservative spring interaction between the gun and the projectile will give rise to elastic potential energy.

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idmod
Model:
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.

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idapp
Approach:

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iddiag
Diagrammatic Representation

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iddiag

We will ignore friction and other non-conservative interactions, which means that the mechanical energy of the system will be constant. We will further make the usual assumption that the projectile stops interacting with the spring when the spring returns to its equilibrium position (the projectile has essentially been "fired" at that point). Thus, appropriate initial-state final-state diagram and energy bar graphs are:

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Image Added

Initial

Final

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diag

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idmath
Mathematical Representation

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idmath

We can now express the fact that the mechanical energy is constant through the Law of Change:

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{excerpt:hidden=true}Energy and springs.{excerpt}


A certain spring-loaded gun is cocked by compressing its spring by 5.0 cm.  The gun fires a 4.0 g projectile with a speed of 8.0 m/s.  What spring constant is required for the spring?

h4. Solution

{toggle-cloak:id=sys} *System:*  {cloak:id=sys}Projectile as [point particle] plus the gun as a rigid body of infinite mass.{cloak}

{toggle-cloak:id=int} *Interactions:*  {cloak:id=int}The [conservative|conservative force] spring interaction between the gun and the projectile will give rise to [elastic potential energy|Hooke's Law for elastic interactions#epe].{cloak}

{toggle-cloak:id=mod} *Model:* {cloak:id=mod}[Mechanical Energy and Non-Conservative Work].{cloak}

{toggle-cloak:id=app} *Approach:*  

{cloak:id=app}

{toggle-cloak:id=diag} {color:red} *Diagrammatic Representation* {color}

{cloak:id=diag}

We will ignore friction and other [non-conservative] interactions, which means that the [mechanical energy] of the system will be constant.  We will further make the usual assumption that the projectile stops interacting with the spring when the spring returns to its equilibrium position (the projectile has essentially been "fired" at that point).  Thus, appropriate [initial-state final-state diagram] and [energy bar graphs|energy bar graph] are:

|!springgun1.jpg!|!springgun2.jpg!|
||Initial||Final||

{cloak:diag}

{toggle-cloak:id=math} {color:red} *Mathematical Representation* {color}

{cloak:id=math}

We can now express the fact that the mechanical energy is constant through the Law of Change:

{latex}\begin{large}\[ E_{i} = U_{i} = \frac{1}{2}kx_{i}^{2} = E_{f} = K_{f} = \frac{1}{2}mv_{f}^{2}\]\end{large}{latex}

Solving

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for

...

k

...

gives:

{
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}\begin{large}\[ k = \frac{mv_{f}^{2}}{x_{i}^{2}} = \mbox{102 N/m}\]\end{large}{latex}

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