Materials

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Lucie

Cards (15)

Forces that produce extension are known as tensile forces
Forces that compress an object are known as compressive forces
Force (f) = spring constant (k) x extension (x)
Hookes law states that the extention is proportional to the force applied provided the limit of proportionality is not exceeded
springs in parallel - Kt = K1 + K2 ..
springs in series - 1/Kt = 1/K1 + 1/K2 ..
Elastic deformation is a reversible change in the shape of an object due to tensile/compressive forces eg a spring
Plastic deformation is an irreversible change in the shape of an object due to tensile/compressive forces eg a plastic bag
Rules of Hookes law
the extension is directly proportional to the force applied
when theres no force applied the extension is zero
Force constant depends on the material, size and shape of an object but can also be the stress and strain of an object
Stress is the force per unit cross sectional area of a material
Strain is the fractional change in length of an object
Young modulus is the stress per unit of strain measured in pascals (Pa)
$sigma (\sigma )=$ $force(F)/ area(A )$
$strain(\epsilon) =$ $extension(x) / length(L)$
$energy(E) =$ $stress(\sigma)/ strain(\epsilon)$
Elastic potential (E) = 0.5 x force (f) x extension (X)
Elastic potential (E) = 0.5 x force constant (K) x extension squared (X^2)
Stress strain graphs
limit of proportionality is the point where the stress is no longer linear to strain
Elastic limit is the point where it goes from elastic deformation to plastic deformation
Yield points are where there is a sudden extention with little increase in force
Breaking point is the point where the material breaks
Young modulus is the gradient of the linear part of the graph