Answer:
Yes, fracture will occur since toughness (42.4 MPa) is greater than the toughness of the material, 40MPa
Explanation:
Given
Toughness, k = 40Mpa
Stress, σ = 300Mpa
Length, l = 4mm = 4 * 10^-3m
Under which fracture occurred (i.e., σ= 300 MPa and 2a= 4.0 mm), first we solve for parameter Y (The dimensionless parameter)
Y = k/(σπ√a)
Where a = ½ of the length in metres
Y = 40/(300 * π * √(4/2 * 10^-3))
Y = 1.68 ---- Approximated
To check if fracture will occur of not; we apply the same formula.
Y = k/(σπ√a)
Then we solve for k, where
σ = 260Mpa and a = ½ * 6 * 10^-3
So,.we have
1.68 = k/(260 * π * √(6*10^-3)/2)
k = 1.68 * (260 * π * (6*10^-3)/2)
k = 42.4 MPa --- Approximately
Therefore, fracture will occur since toughness (42.4 MPa) is greater than the toughness of the material, 40 MPa
Answer:
The fracture toughness at 6 mm is greater than the fracture toughness of the material (42.46 MPa(m)^1/2 > 40 MPa(m)^1/2), thus, the material will fracture.
Explanation:
The half length of the internal crack is:
[tex]a=\frac{L_{surface} }{2} =\frac{4}{2}=2 mm= 2x10^{-3}m[/tex]
The dimensionless parameter Y is:
[tex]Y=\frac{K}{o\sqrt{\pi a} }[/tex]
Where K is the plane strain fracture toughness=40 MPa(m)^1/2.
o is the initiating crack propagation=300 MPa. Replacing values:
[tex]Y=\frac{40}{300\sqrt{\pi 2x10^{-3} } }=1.68[/tex]
The half length of the internal crack when the length is 6 mm is:
a=6/2=3 mm=3x10^-3 m
The strain fracture toughness at the critical stress is:
[tex]K=oY\sqrt{\pi a}=260*1.68*\sqrt{\pi *3x10^{-3} }=42.46 MPa\sqrt{m}[/tex]
