Here is another option using a set of building blocks and string.įirst, create a pendulum to simulate a wrecking ball. What happened as the wrecking ball was pulled back more and more? How many blocks fell over? How far did they travel when knocked over? Now hold the ball farther back. Here are instructions using household materials.
We used a wooden building set, as pictured below. This wrecking ball physics can be tested quite simply using children’s blocks or Legos and some household materials. If the theory above is true, the crane operator controlling the wrecking ball should be able to control the force of the wrecking ball by changing the height from where the ball is “released” or from the top of the arc of the swing. This means the destructive power of the wrecking ball should then be more when the weight is released from a higher point. Therefore, the force of the weight hitting a structure increases. If the peak velocity is more when the weight is released from a higher point, then the momentum of that weight increases, as well. This means the weight needs to be released from a higher point. If the weight gains velocity as it falls, then to increase the velocity, the distance the weight falls must increase. In our pendulum discussion, we learned that the released weight increases in velocity as it nears the bottom of the pendulum arc. Since the mass of the weight of the wrecking ball is constant, the velocity of the weight as it swings must be increased if momentum is going to be increased. Momentum is a function of mass and velocity and can be calculated as: To create the amount of force necessary, the crane operator needs to create a lot of momentum. To do this, the wrecking ball must apply force to the structure it is trying to destroy. The entire point of a wrecking ball is to knock things over. The crane operator swings the wrecking ball up to a point where the ball stops and then falls and swings through an arc just like a pendulum.
The wrecking ball is the weight held by a heavy cable to a pivot point held up by a crane. Wrecking Ball Physics – Wrecking Balls And MomentumĪs stated before, wrecking balls are giant pendulums. The weight only stops for an instant until gravity pulls the weight back down and the process starts again. After the weight passes the bottom of the arc, these both decrease until the weight stops at the top of the arc at the opposite point of the release.Īt this point, the kinetic energy is back to zero and the weight now contains gravitational potential energy again. This is the point of highest kinetic energy and velocity. When the weight is released, that potential energy is converted into kinetic energy or energy of motion.Īs gravity pulls the weight down toward the earth, both the kinetic energy and velocity or speed, of the weight increase until the weight reaches the bottom point of the pendulum arc. This is the energy stored by the weight because of its position above the ground. Pendulums work because of the energy involved in their systems. When the pendulum weight is raised, it contains gravitational potential energy. A pendulum is a weight hung from a pivot point and allowed to swing freely until the friction between the weight and the air slows and stops the swinging of the pendulum and it eventually comes to a stop. If we look at a wrecking ball, it is basically a pendulum. Wrecking Ball Physics and How a Pendulum Works I’ll show you how we did it, but first a little wrecking ball physics lesson. The kids and I took our fascination with wrecking balls and turned it into a physics experiment. We love to watch demolition videos where they lay charges in just the right areas of one building making it fall straight down without touching the surrounding buildings.Įven though wrecking balls function with less precision than other demolition methods, the effectiveness of wrecking balls is still determined by physics. Our family has always had a little fascination with demolition and wrecking ball physics.
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