Answer:
The total elongation for the tension member is of 0.25mm
Explanation:
Assuming that material is under a linear deformation then the relation between the stress and the specific elongation is given as:
[tex]\sigma=E*\epsilon[/tex] (1)
Where E is the modulus of elasticity, σ the stress and ε the specific deformation. Also, the total longitudinal elongation can be expressed as:
[tex]\delta L=L*\epsilon[/tex] (2)
Here L is the member extension and δL the change total longitudinal elongation.
Now if the stress is found then the deformation can be calculated by solving the stress-deformation equation (1). The stress applied sigama is computed dividing the axial load P by the cross-sectional area A:
[tex]\sigma=P/A[/tex]
[tex]\sigma=22.44N / 1290 mm^2[/tex]
[tex]\sigma=0.0174 N/mm^2[/tex]
Solving for epsilon and replacing the calculated value for the stress and the value for the modulus of elasticity:
[tex]=\sigma=E*\epsilon[/tex]
[tex]\epsilon=\sigma/E[/tex]
[tex]\epsilon=0.0174 \frac{N}{mm^2}/\ 204 \frac{N}{mm^2} [/tex]
[tex]\epsilon=8.53*10^-{5}[/tex]
Finally introducing the specific deformation and the longitudinal extension in the equation of total elongation (2):
[tex]\delta L=3048 mm * 8.53*10^{-5} [/tex]
[tex]\delta L= 0.25 mm [/tex]
