Projectile Launcher

Springs and Energy

The spring in your launcher is like a tiny battery. When you stretch it, you're storing energy. When you release it, that energy launches your projectile!

Key Variables

Force

Newtons

Push/pull strength

Spring Constant

N/m

Stiffness rating

Displacement

meters

Stretch distance

Potential Energy

Joules

Stored energy

1. The "Stiffness" Factor: Hooke's Law

First, grab the spring from your kit. Stretch it. It fights back, right?

The harder you stretch it, the harder it pulls back. This rule is called Hooke's Law, named after a scientist named Robert Hooke who figured this out over 300 years ago.

F = −kx

F (Force): This is how hard the spring pulls back.
x (Displacement): This is how far you have stretched the spring from its relaxed shape.
k (Spring Constant): This is the "Stiffness Rating." A high k means a really stiff, tough spring (like on a car). A low k means a loose, slinky spring (like in a ballpoint pen).
The Negative Sign (−): This just means the spring pulls in the opposite direction of where you stretch it. If you pull it out, the spring pulls back.

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Teacher Tip

If you want your projectile to go farther, you either need a stiffer spring (higher k) or you need to stretch it more (higher x).

2. The Energy Tank: Elastic Potential Energy

When you lock your launcher in the "ready" position, you aren't just holding a spring; you are storing energy. This is called Elastic Potential Energy.

PE = ½kx²

PE: The energy stored in Joules.
k: That same stiffness rating from before.
x: The distance you stretched the spring.

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Key Takeaway

Look at the x² (x-squared). This is the secret to a powerful launch. Because the distance is squared, if you pull the spring back 2 times as far, you don't get 2 times the energy... you get 4 times the energy (2² = 4).

Try It: Interactive Visualizer

Drag the slider to stretch the spring and watch how force and energy change. Notice that energy grows much faster than force!

Spring Energy Visualizer

Stretch: 50%

RelaxedMax Stretch

Force vs Distance (Linear)

F = kx (straight line)

Energy vs Distance (Quadratic)

PE = ½kx² (curved parabola)

Notice: The Force graph is a straight line, but Energy is a curve. Double the stretch = 4x the energy!

3. The Launch: Energy Transformation

This is the moment of truth. When you pull the trigger, the spring is released.

All that Potential Energy (PE) you stored doesn't disappear; it instantly transforms into Kinetic Energy (KE), which is the energy of motion.

Potential Energy → Kinetic Energy

The massive amount of energy stored in the stretched spring launches the projectile, making it fly!

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Try It!

Stretch the spring to different lengths and launch. Does stretching it twice as far really make the ball go further?

Real World Connections

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Pogo Sticks

Springs store energy when you push down, then release it to bounce you up!

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Car Suspension

Springs absorb energy from bumps to give you a smooth ride.

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Mechanical Watches

A mainspring stores energy to power the watch for days!