Answer:
volume fraction of fibers is 0.4
Explanation:
Given that for the aligned carbon fiber-epoxy matrix composite:
Diameter (D) = 0.029 mm
Length (L) = 2.3 mm
Tensile strength ([tex]\sigma_{cd}[/tex]) = 610 MPa
fracture strength ([tex]\sigma_f[/tex]) = 5300 MPa
matrix stress ([tex]\sigma_m[/tex]) = 17.3 MPa
fiber-matrix bond strength ([tex]\tau_c[/tex]) = 19 MPa
The critical length is given as:
[tex]L_C=\sigma_f(\frac{D}{2\tau_c} )=5300*10^6(\frac{0.029*10^{-3}}{19*10^6} )=8.1*10^{-3}=8.1mm[/tex]
Since the critical length is greater than the length, the aligned carbon fiber-epoxy matrix composite can be produced.
The longitudinal strength is given by:
[tex]\sigma_{cd}=\frac{L*\tau_c}{D} .V_f+\sigma_m(1-V_f)[/tex]
making Vf the subject of the formula:
[tex]V_f=\frac{\sigma_{cd}-\sigma_m}{\frac{L*\tau_c}{D} -\sigma_m}[/tex]
Vf is the volume fraction of fibers.
Therefore:
[tex]V_f=\frac{\sigma_{cd}-\sigma_m}{\frac{L*\tau_c}{D} -\sigma_m}=\frac{610*10^6-17.3*10^6}{\frac{2.3*10^{-3}*19*10^6}{0.029*10^{-3}}-17.3*10^6} } =0.4[/tex]
volume fraction of fibers is 0.4
