Elastic Potential Energy Formula

Elastic Potential Energy Formula

Potential energy is the energy that a body possesses as a function of its position with respect to a reference point. An item can store energy based on its location. When the heavy ball of a demolition machine is kept high, it saves energy. This stored positional energy is referred to as “potential energy.” A drawn bow, similarly, can store energy based on its attitude.

There is no energy stored in the bow while it is in its normal posture (i.e., not pulled). When the bow’s position is modified from its typical equilibrium condition, it can store energy. This stored positional energy is referred to as “potential energy.” Potential energy is the stored energy of an object’s position.

Potential energy is the stored energy in an item as a result of its location. When we think about potential energy, the first image that comes to mind is an item high in the air, about to fall. Because of its height, it has potential energy stored in it. As it falls, this energy is converted into kinetic energy. However, an object can have potential energy in some other situations. An elastic material is one such example.

Elastic Potential Energy Formula

The Elastic Potential Energy Formula is the potential energy held when an elastic item is stretched or compressed by an external force, such as a spring stretching. It is the work done to extend the spring, which is proportional to the spring constant k and the distance stretched.

What is elastic potential energy?

This is the energy stored in an item as a result of its shape distortion. Any item with elastic potential energy can be distorted and then returned to its original shape. Rubber bands, sponges, bungee ropes, and other similar items are examples.

When we distort these things, they automatically return to their previous shape. Only accumulated potential energy, which is elastic potential energy, makes it feasible. As a result, elastic potential energy is the energy contained in a compressible or stretchy item.

Elastic potential energy can be calculated using the following fundamental formula:

The Elastic Potential Energy Formula = force × displacement.

The Elastic Potential Energy Formula is calculated as the effort done to stretch the spring, which is dependent on the spring constant k and the stretched displacement.

Hooke’s law states that the force used to extend the spring is directly equal to the amount of stretch. To put it another way,

Elastic Potential Energy Formula

This is the energy held by the object’s distortion of shape. Elastic potential energy can be found in any item that can be distorted and then returned to its original shape. Such things include rubber bands, sponges, and bungee cords. When we modify these things, they will naturally return to their previous forms. This is only possible because the collected potential energy is elastic potential energy.Elastic potential energy is, therefore, the energy contained in a compressible or stretchy item.

Solved Examples

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