elastic potential energy :)
When you stretch a spring, the energy is stored as potential energy in the form of elastic potential energy. This potential energy is stored in the spring due to the deformation of its shape, and it is released when the spring returns to its original position.
Elastic potential energy is stored when you stretch a spring. This energy is a type of potential energy that is stored in an object when it is compressed or stretched.
When you stretch a spring, it stores potential energy in the form of elastic potential energy. The spring will exert a restoring force trying to return to its original shape. The amount of force required to stretch the spring is directly proportional to the amount of deformation.
The energy required to stretch or compress a spring is potential energy, which is stored in the spring as it is deformed from its equilibrium position. This potential energy is proportional to the amount the spring is stretched or compressed and can be calculated using the formula 1/2kx^2, where k is the spring constant and x is the displacement from equilibrium.
You can increase the elastic potential energy of a spring by stretching or compressing it further. The more you stretch or compress the spring, the greater the potential energy stored in it.
When you stretch a spring, the energy is stored as potential energy in the form of elastic potential energy. This potential energy is stored in the spring due to the deformation of its shape, and it is released when the spring returns to its original position.
Elastic energy is really potential energy that is derived from the stretching of an item such as a spring. The energy potential is based on the force used stretch the spring and the distance the spring is stretched.
Elastic potential energy is stored when you stretch a spring. This energy is a type of potential energy that is stored in an object when it is compressed or stretched.
When you stretch a spring, it stores potential energy in the form of elastic potential energy. The spring will exert a restoring force trying to return to its original shape. The amount of force required to stretch the spring is directly proportional to the amount of deformation.
It depends on spring energy or spring strength
The energy required to stretch or compress a spring is potential energy, which is stored in the spring as it is deformed from its equilibrium position. This potential energy is proportional to the amount the spring is stretched or compressed and can be calculated using the formula 1/2kx^2, where k is the spring constant and x is the displacement from equilibrium.
You can increase the elastic potential energy of a spring by stretching or compressing it further. The more you stretch or compress the spring, the greater the potential energy stored in it.
Yes, you can stretch a spring by applying a force to it. When you push or pull on a spring, you are exerting a force that causes the spring to deform and extend. This stretching force is known as tension in the spring.
You can increase the elastic potential energy of a spring by stretching or compressing it further from its equilibrium position. The more you stretch or compress the spring, the more potential energy it will store.
Springs are great for absorbing energy. The spring force is negative when the spring is stretched and positive when it is compressed or pushed.
The stored energy in a stretched-out slinky spring toy is potential energy. As the coils are pulled apart, work is done to stretch the spring, and this work is stored in the spring as potential energy. When the spring is released, this potential energy is converted back into kinetic energy as the coils snap back together.
its potential energy is 1/2kx^2 -k is its spring constant and x its displacement - the higher the stretch, the more the energy which goes as the square of the stretch, x