When the elastic of a catapult is pulled back, it stores potential energy in the form of elastic potential energy. This potential energy is converted into kinetic energy when the catapult is released, launching the projectile forward.
A catapult has elastic potential energy when the elastic has been pulled back. This potential energy is stored in the stretched elastic material. When the catapult is released, this potential energy is converted into kinetic energy as the projectile is launched forward.
A catapult has potential energy stored in the elastic material when it is pulled back. This potential energy is released when the catapult is triggered, converting into kinetic energy as the projectile is launched.
Yes, a catapult has potential energy when its arm is pulled back and loaded with a projectile. The potential energy is stored in the arm's position and is released when the arm is released, launching the projectile.
An Xpult catapult works by storing potential energy in its elastic material (such as a rubber band) when it is pulled back or wound up. When released, this potential energy is rapidly converted into kinetic energy, causing the arm to swing forward and launch the projectile. The design of the Xpult allows for adjusting the launch angle and distance by changing the amount of tension on the elastic material.
kenetic energy
A catapult has elastic potential energy when the elastic has been pulled back. This potential energy is stored in the stretched elastic material. When the catapult is released, this potential energy is converted into kinetic energy as the projectile is launched forward.
A catapult has potential energy stored in the elastic material when it is pulled back. This potential energy is released when the catapult is triggered, converting into kinetic energy as the projectile is launched.
Yes, a catapult has potential energy when its arm is pulled back and loaded with a projectile. The potential energy is stored in the arm's position and is released when the arm is released, launching the projectile.
a catapult has a elastic so it can be pulled back and when u let go it the item in it will go far.the catapult uses tension to give it its power .when the tension on elastics it created by pulling back the lever. it is released by letting go and the object will fly
An Xpult catapult works by storing potential energy in its elastic material (such as a rubber band) when it is pulled back or wound up. When released, this potential energy is rapidly converted into kinetic energy, causing the arm to swing forward and launch the projectile. The design of the Xpult allows for adjusting the launch angle and distance by changing the amount of tension on the elastic material.
kenetic energy
Well, elastic potential energy is energy that is released from an object by stretching or pulling. The formula for EPE is : EPE= 1/2 spring constant x extensions (squared) The rubber band is related to EPE because when you bend it back and release it, you are releasing elastic potential energy. (Note: EPE refers to "elastic potential energy".
In a catapult, potential energy is converted into kinetic energy as the arm is pulled back. When the trigger is released, the stored energy is rapidly released, propelling the projectile forward. This results in a transformation of potential energy into kinetic energy of the projectile.
In the elasticity of it being held down. It depends on which catapult mechanism, all catapults are powered by potential energy; for example the simple catapult is an elasctic band that is pulled back converting the energy used to pull it back (usually muscle power) into the potential energy in the stretched elastic band.
The catapult is a simple machine. The work input is the restraining of the payload and pressure put on the spring or lever. The work output is the delivery of the payload with the energy of the work transferred to it.
A catapult uses the force of tension, which is created when the catapult's arm is pulled back and potential energy is stored in the tension of the rope or spring. When the arm is released, this potential energy is converted into kinetic energy, propelling the projectile forward. The release mechanism of the catapult, such as a trigger or lever, allows the tension force to be quickly and efficiently transferred to the projectile.
When you pull the slingshot back on a catapult, you are using muscular force from your arms and hands to stretch the elastic material of the slingshot. This builds up potential energy in the slingshot, which is then released when the projectile is launched.