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1.To understand that once the elastic limit has been exceeded, the force-extension graphs for loading and unloading are unequal 2.To know that such curves.

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Presentation on theme: "1.To understand that once the elastic limit has been exceeded, the force-extension graphs for loading and unloading are unequal 2.To know that such curves."— Presentation transcript:

1 1.To understand that once the elastic limit has been exceeded, the force-extension graphs for loading and unloading are unequal 2.To know that such curves are called hysterisis curves. 3.To be able to describe such graphs for different materials 4.To describe the energy changes during loading/unloading Book Reference : Pages 170-171

2 Ductile materials have a very large plastic region. Just before it fails the material necks Cross sectional reduces, and as stress = F/A the neck sees an increase in tensile stress. Brittle materials show little plastic deformation. Failure is sudden and ‘catastrophic’. Better under compression

3 We have seen that providing the elastic limit of the material is not exceeded then Hooke’s law is obeyed and the graph obtained during loading and unloading will be identical However, once the limit of elasticity has been exceeded this is no longer true

4 For a material such as a metal wire, the curve obtained during unloading, (red) follows parallel to the original loading curve (blue) There has been a permanent extension Such curves are called Hysteresis curves

5 In contrast a very elastic material such as rubber, loads and unloads in a very different way Very low limit of proportionality Curled when unstretched Curled when unstretched Uncurled when stretched Uncurled when stretched Curling / uncurling is different Curling / uncurling is different

6 Plastic deformation. Permanent extension Tangled when unstretched, weak intermolecular cross links exist between the molecules. These break during stretching but new bonds reform when the tension is removed.

7 Earlier we saw that the area under a force- extension graph shows the work done to stretch the material. This is more correctly called the strain energy When the graph is linear the work done during stretching is recovered when it is unloaded

8 Rubber...

9 In a material such as polythene, much of the work done during loading is used to deform the material permanently

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