Answer:
a) [tex]P_{max}=89375N[/tex]
b) [tex]L_{f}=115.275mm[/tex]
Explanation:
a) The maximum load that may be applied to a specimen of bronze alloy without plastic deformation is given by the following equation :
Pmax = (σ).(A)
Where Pmax is the maximum load
σ is the value at which plastic deformation begins
Where ''A'' is the cross-sectional area of the specimen
Let's also use the fact that :
[tex]1 MPa=(10^{6})Pa=(10^{6})\frac{N}{m^{2}}[/tex]
We first must turn ''A'' from [tex](mm^{2})[/tex] to [tex](m^{2})[/tex]
[tex]325(mm^{2})=325.(mm).(mm).(\frac{1m}{1000mm}).(\frac{1m}{1000mm})\\[/tex]
[tex]325(mm^{2})=(3.25).(10^{-4})m^{2}[/tex]
Using the equation :
[tex]P_{max}=(275)(10^{6})\frac{N}{m^{2}}.(3.25).(10^{-4}).m^{2}=89375N[/tex]
The maximum load is 89375 N.
b) To calculate the maximum length we are going to use the following equation :
Lf = Li ( 1 + σ / E )
Where Lf is final length without causing plastic deformation
Li is initial length
σ is the value at which plastic deformation begins
And finally ''E'' is the modulus of elasticity from the bronze alloy
Using the equation :
[tex]L_{f}=(115mm).(1+\frac{(275).(10^{6})Pa}{(115).(10^{9})Pa})\\L_{f}=115.275mm[/tex]
