Life assessment of SiMo 4.06 cast iron under LCF and TMF loading conditions

“…Ferritic SiMo ductile cast iron contains 3.5-5.1% silicon and 0.4-1.1% molybdenum (wt.%), which is commonly used for high-temperature applications primarily because of its good thermomechanical properties, resistance to high-temperature oxidation, and castability. [1][2][3] One version of this alloy, designated as SiMo51 ductile iron, contains near 3.1% C, 4.1% Si, 0.4% Mn, 0.8% Mo, and 0.05% Mg and is commonly used in the manufacture of exhaust manifolds. [1][2][3][4][5] In addition to being exposed to harsh high-temperature oxidizing environments, manifolds are subjected to the thermomechanical loadings during thermal cycling at mechanically constrained conditions.…”

“…[1][2][3] One version of this alloy, designated as SiMo51 ductile iron, contains near 3.1% C, 4.1% Si, 0.4% Mn, 0.8% Mo, and 0.05% Mg and is commonly used in the manufacture of exhaust manifolds. [1][2][3][4][5] In addition to being exposed to harsh high-temperature oxidizing environments, manifolds are subjected to the thermomechanical loadings during thermal cycling at mechanically constrained conditions. When these types of situations occur, there is a self-generated stress and strain condition, which is a function of both intrinsic (thermal expansion, heat conductivity and mechanical properties of material) and extrinsic (thermal load, component geometry) conditions.…”

Control of High-Temperature Static and Transient Thermomechanical Behavior of SiMo Ductile Iron by Al Alloying

“…Ferritic SiMo ductile cast iron contains 3.5-5.1% silicon and 0.4-1.1% molybdenum (wt.%), which is commonly used for high-temperature applications primarily because of its good thermomechanical properties, resistance to high-temperature oxidation, and castability. [1][2][3] One version of this alloy, designated as SiMo51 ductile iron, contains near 3.1% C, 4.1% Si, 0.4% Mn, 0.8% Mo, and 0.05% Mg and is commonly used in the manufacture of exhaust manifolds. [1][2][3][4][5] In addition to being exposed to harsh high-temperature oxidizing environments, manifolds are subjected to the thermomechanical loadings during thermal cycling at mechanically constrained conditions.…”

“…[1][2][3] One version of this alloy, designated as SiMo51 ductile iron, contains near 3.1% C, 4.1% Si, 0.4% Mn, 0.8% Mo, and 0.05% Mg and is commonly used in the manufacture of exhaust manifolds. [1][2][3][4][5] In addition to being exposed to harsh high-temperature oxidizing environments, manifolds are subjected to the thermomechanical loadings during thermal cycling at mechanically constrained conditions. When these types of situations occur, there is a self-generated stress and strain condition, which is a function of both intrinsic (thermal expansion, heat conductivity and mechanical properties of material) and extrinsic (thermal load, component geometry) conditions.…”

Control of High-Temperature Static and Transient Thermomechanical Behavior of SiMo Ductile Iron by Al Alloying

“…Low-Cycle Fatigue (LCF) may be induced if the temperature does not change significantly during loading cycles, whereas thermo-mechanical fatigue should be considered for the loading cycles with variable temperatures [6,7,8]. A quantification of the stress-strain response forms a pre-requisite for accurate lifetime predictions, which are increasingly important in order to guarantee the safety and reliability of these components [9,10].…”

Use of Prandtl operators in simulating the cyclic softening of Inconel 718 under isothermal low-cycle fatigue loading

“…Such conditions can cause considerable plastic deformation of a component due to either high mechanical loads or moderate mechanical loads combined with elevated temperatures, both of which exceed the yield stress of the material [2,[11][12][13]. If plastic deformation varies due to variable work conditions (start-up, full and partial loads, shut-down), the component is subjected to low-cycle fatigue which can eventually result in failure [2,6,14].…”

A new approach to finite element modelling of cyclic thermomechanical stress-strain responses