Ask Question
1 April, 03:52

Suppose that a wing component on an aircraft is fabricated from an aluminum alloy that has a plane-strain fracture toughness of 26.0 MPa (23.7 ksi). It has been determined that fracture results at a stress of 112 MPa (16,240 psi) when the maximum internal crack length is 8.6 mm (0.34 in.). For this same component and alloy, compute the stress level at which fracture will occur for a critical internal crack length of 6.0 mm

+5
Answers (1)
  1. 1 April, 04:59
    0
    Answer: 133.88 MPa approximately 134 MPa

    Explanation:

    Given

    Plane strains fracture toughness, k = 26 MPa

    Stress at which fracture occurs, σ = 112 MPa

    Maximum internal crack length, l = 8.6 mm = 8.6*10^-3 m

    Critical internal crack length, l' = 6 mm = 6*10^-3 m

    We know that

    σ = K / (Y.√πa), where

    112 MPa = 26 MPa / Y.√[3.142 * 8.6*10^-3) / 2]

    112 MPa = 26 MPa / Y.√ (3.142 * 0.043)

    112 = 26 / Y.√1.35*10^-2

    112 = 26 / Y * 0.116

    Y = 26 / 112 * 0.116

    Y = 26 / 13

    Y = 2

    σ = K / (Y.√πa), using l'instead of l and, using Y as 2

    σ = 26 / 2 * [√3.142 * (6*10^-3/2) ]

    σ = 26 / 2 * √ (3.142 * 3*10^-3)

    σ = 26 / 2 * √0.009426

    σ = 26 / 2 * 0.0971

    σ = 26 / 0.1942

    σ = 133.88 MPa
Know the Answer?
Not Sure About the Answer?
Get an answer to your question ✅ “Suppose that a wing component on an aircraft is fabricated from an aluminum alloy that has a plane-strain fracture toughness of 26.0 MPa ...” in 📙 Engineering if there is no answer or all answers are wrong, use a search bar and try to find the answer among similar questions.
Search for Other Answers