Abstract
The classification of grades inside a material family should be based on the properties required by design procedures. This paper proposes a reclassification of spheroidal graphite ferritic pearlitic and ausferritic (ADI) ductile cast irons grades based on yield strength (YS), strength ratio (SR) UTS/YS and elongation at fracture (EF). In fact, these parameters are fundamental for the static assessment according to the procedures FKM Guideline and BS 7910:2005. Static assessment at room temperature, involving plastic deformation and depending on the wall thickness and stress state triaxiality, is here proposed as the most significant for the material classification. All other properties (e.g., fatigue under cyclic loads, high strain rates and temperature effect, etc.) should be reported with reference to the classification mentioned above. SR and EF control the plastic deformation at the notch tip, where maximum calculated elastic stress is redistributed. Minimum YS is usually assumed as the basic parameter for static and cyclic loading design. Because of the inverse relationship that exists between strength and ductility, Brinell hardness control and material quality index should be adopted as Material Quality Control tools, preventing from a too low EF. Fracture Toughness and its ratio with YS must be considered for preventing brittle fracture due to the presence of flaws. Fracture toughness definitions and available data are not sufficiently consistent for a correct comparison between different material grades. A surrogate Charpy energy measurement is indicated for an indirect estimate of toughness.
Highlights
Spheroidal graphite cast irons (SGCIs) are a family of materials that compete favorably with steels for applicationThis paper is an invited submission to IJMC selected from presentations at the 2nd Carl Loper 2019 Cast Iron Symposium held September 30 to October 1, 2019, in Bilbao, Spain.Disclaimer: The present paper is not a direct design support
This paper proposes a reclassification of spheroidal graphite ferritic pearlitic and ausferritic (ADI) ductile cast irons grades based on yield strength (YS), strength ratio (SR) UTS/YS and elongation at fracture (EF)
Because of the inverse relationship that exists between strength and ductility, Brinell hardness control and material quality index should be adopted as Material Quality Control tools, preventing from a too low EF
Summary
Spheroidal graphite cast irons (SGCIs) are a family of materials that compete favorably with steels for application. This paper is an invited submission to IJMC selected from presentations at the 2nd Carl Loper 2019 Cast Iron Symposium held September 30 to October 1, 2019, in Bilbao, Spain.Disclaimer: The present paper is not a direct design support. Its purpose is to make the case for improving material standards for spheroidal graphite cast irons (SGCIs) to address the true needs for designing with these materials. The material family is featured by a microstructure that can be described as constituted by a ‘‘high-silicon steel matrix surrounding spheroidal carbon sinks.’’ Carbon sinks and silicon allow for solid-state heat treatment transformations that are not possible with steel. During the liquid–solid transformation, carbon and silicon allow a much lower (compared with steel) melting temperature, self-feeding properties, a carbide-free matrix and protection against surface oxidation. Graphite spheroids influence the plastic deformation of SGCIs under load after the onset of necking and/ or even prevent the onset of necking to be met
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