A tie rod made of quenched and tempered 4340 steel is used as a critical linkage in an industrial apparatus. The rod is subjected to an alternating cyclic tensile/compressive stress from 550 MPa to -550 MPa. An inspection of the rod revealed a 3.5 mm deep edge crack on the surface of the rod. Please answer the following question for the rod given the properties in the table and curve below and fracture toughness of 55 MPa√m. (NOTE: Y=1.12 for edge crack and use “a” not “2a” for the length of the crack) 

1. At the given crack size and tensile loading would the rod undergo instantaneous fast fracture, assuming plane strain conditions? Show calculations to back up your conclusions.

 

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The left side of the image displays a table containing mechanical properties of a material: - **Modulus, E**: 200 - **Yield strength, σ_y (MPa)**: 900 - **Tensile strength, TS (MPa)**: 1300 - **Elongation (%)**: 20 - **Fracture toughness, K_Ic (MPa√m)**: 55 The right side of the image presents a graph depicting fatigue behavior of different materials. This is a log-log graph with the x-axis labeled "Cycles to failure, N" ranging from 10³ to 10⁹, and the y-axis labeled "Maximum stress, S (MPa)" ranging from 0 to 700. ### Graph Explanation The graph illustrates the relationship between the maximum stress (S) that materials can withstand and the number of cycles to failure (N), which is a common measure in fatigue analysis. Several materials are represented through distinct curves: - **Ti-6Al-2.5Sn titanium alloy**: This curve is at the highest stress levels for a given number of cycles. - **4340 steel**: Appears below the titanium alloy curve, indicating lower stress endurance. - **1045 steel**: Positioned below the 4340 steel curve. - **Ductile cast iron**: Displays a specific curve lower than both steels. - **70Cu-30Zn brass**: Represented by a curve indicating lower maximum stress. - **2014-T6 Al alloy**: Shows a curve similar to the brass but slightly improved in performance. - **EQ21A-T6 Mg alloy**: Has the lowest curve in terms of maximum stress capacity. This graph helps in understanding the fatigue performance of different materials, showing how long a material can withstand cyclic loading at varying stress levels before failure.