Forces and Elasticity
Forces and Elasticity
Videos and Notes which teach you everything you need to know
Flash Mode: Quick Videos for cramming
Revision Mode: Self Paced Videos with Full Notes
There are TWO types of deformation:
1. ELASTIC deformation
This is when the object RETURNS TO ITS ORIGINAL SHAPE AND LENGTH after the forces have been removed.
2. INELASTIC deformation
This is when the object DOESN’T return to its original shape and length after the forces have been removed.
Consider adding a force of 1000N on a spring causing it to be stretched.
The EXTENSION is the DIFFERENCE between the length of STRETCHED SPRING and the ORIGINAL LENGTH of the unstretched spring:
If ANOTHER 1000N was added, the EXTENSION would DOUBLE.
This can be explained by Hooke’s Law which states that:
The extension of an elastic object like a spring is DIRECTLY PROPORTIONAL to the force applied, given the LIMIT OF PROPORTIONALITY is not exceeded.
Hookes Law can be represented with the following equation:
Where:
The relationship between the force applied and extension can be shown on a FORCE-EXTENSION graph:
This graph shows a LINEAR relationship until an extension of around 0.7m. This shows force and extension is DIRECTLY PROPORTIONAL until the object is stretched to 0.7m.
The point at which the graph becomes NON-LINEAR (0.7m) is known as the LIMIT OF PROPORTIONALITY, and if the object is stretched to more than this extension, the force is NO LONGER proportional to the extension.
Eventually, if you add enough force to a spring, it will deform INELASTICALLY and will NOT return to its original shape and length. The point at which this happens is known as the ELASTIC LIMIT.
You can work out the SPRING CONSTANT using the graph, by finding the GRADIENT of the LINEAR section:
The WORK DONE in stretching (or compressing) an elastic object is stored as ELASTIC POTENTIAL ENERGY within the object.
During ELASTIC DEFORMATION: The WORK DONE is EQUAL to the ELASTIC POTENTIAL ENERGY stored in the object
During INELASTIC DEFORMATION: Some of the WORK DONE is DISSIPATED as heat, meaning the object does NOT return to its original shape and size.
There are TWO types of deformation:
1. ELASTIC deformation
This is when the object RETURNS TO ITS ORIGINAL SHAPE AND LENGTH after the forces have been removed.
2. INELASTIC deformation
This is when the object DOESN’T return to its original shape and length after the forces have been removed.
Consider adding a force of 1000N on a spring causing it to be stretched.
The EXTENSION is the DIFFERENCE between the length of STRETCHED SPRING and the ORIGINAL LENGTH of the unstretched spring:
If ANOTHER 1000N was added, the EXTENSION would DOUBLE.
This can be explained by Hooke’s Law which states that:
The extension of an elastic object like a spring is DIRECTLY PROPORTIONAL to the force applied, given the LIMIT OF PROPORTIONALITY is not exceeded.
Hookes Law can be represented with the following equation:
Where:
The relationship between the force applied and extension can be shown on a FORCE-EXTENSION graph:
This graph shows a LINEAR relationship until an extension of around 0.7m. This shows force and extension is DIRECTLY PROPORTIONAL until the object is stretched to 0.7m.
The point at which the graph becomes NON-LINEAR (0.7m) is known as the LIMIT OF PROPORTIONALITY, and if the object is stretched to more than this extension, the force is NO LONGER proportional to the extension.
Eventually, if you add enough force to a spring, it will deform INELASTICALLY and will NOT return to its original shape and length. The point at which this happens is known as the ELASTIC LIMIT.
You can work out the SPRING CONSTANT using the graph, by finding the GRADIENT of the LINEAR section:
The WORK DONE in stretching (or compressing) an elastic object is stored as ELASTIC POTENTIAL ENERGY within the object.
During ELASTIC DEFORMATION: The WORK DONE is EQUAL to the ELASTIC POTENTIAL ENERGY stored in the object
During INELASTIC DEFORMATION: Some of the WORK DONE is DISSIPATED as heat, meaning the object does NOT return to its original shape and size.
