This theory of elasticity says the extension of a spring is proportional to the load applied to it. Many materials obey this law as long as the load does not exceed the material's elastic limit. Materials for which Hooke's law is useful are known as linear-elastic or "Hookean" materials.
The spring equation [change]
The length of a spring always changes by the same amount when it is pushed or pulled. The equation for that is:
- F is how much push or pull is on the spring (e.g. 10 Newtons)
- k is the spring constant, or how strong the spring is. Different springs have different strengths or k.
- x is how far the spring was pushed or pulled
When x = 0, the spring is at the equilibrium position. This equation only works on a linear spring. A linear spring is a spring that is only being pushed or pulled in one direction, such as left or right or up or down.
Elastic potential energy [change]
Elastic potential energy is the energy saved in an object that is stretched, compressed (compression is pressing objects together), twisted or bent. For example, an arrow gets the elastic potential energy from the bow. When it leaves the bow, the potential energy turns into kinetic energy. The equation of the elastic potential energy is:
- U is the elastic potential energy.
- k is the spring constant.
- x is the distance pushed or pulled.