Abstract
Non-metallic inclusions in spheroidal cast iron (SGI) reduce fatigue strength and yield strength. This type of inclusion usually accumulates at grain boundaries. Papers addressing this topic show the overall impact of both the fraction of so-called white (carbides) and black (non-metallic) inclusions on mechanical properties. In the present work we focus on the origin and the formation conditions of black Mg-bearing inclusions, further distinguishing between Si-bearing and non-Si-bearing Mg inclusions. The formation was simulated applying thermodynamic approaches. Moreover, appropriate experiments have been carried out and a large number of particles have been studied applying innovative feature analysis with regard to shape, size, and composition. Magnesium silicates are predicted at elevated oxygen concentrations, whereas at low levels of oxygen sulphides and carbides appear at a late stage of solidification. Experiments with three consecutive flow obstacles show that the amount of magnesium silicates decrease after each of the three obstacles, whereas the fraction of non-Si-bearing inclusions remains approximately constant. The size of inclusions divides in halves over the flow path and the number of particles increases accordingly. We point out that based on feature analysis Mg-O-C bearing inclusion show disadvantageous form factors for which reason this kind of inclusions may be extremely harmful in terms of crack initiation. All results obtained indicate that magnesium silicates are entrapped on mould filling, whereas Mg-(O, C, S, P, N) bearing particles are precipitates at late stages of solidification. Consequently, the only avoidance strategy is setting up optimum retained magnesium content.
Highlights
Non-metallic inclusions decrease fatigue strength and yield strength of spheroidal graphite iron (SGI), since they accumulate near grain boundaries
In the present work we focus on the origin and the formation conditions of black Mg-bearing inclusions, further distinguishing between Si-bearing and non-Si-bearing Mg inclusions
It was found that the non-Si-bearing particles decrease in size more noticeably, whereas the form factor improvement is more pronounced in the Si-bearing particles
Summary
Non-metallic inclusions decrease fatigue strength and yield strength of SGI, since they accumulate near grain boundaries This weakening notch effect in the matrix structure is severe if caused by a jagged or worm-like morphology of these inclusions. Sofue et al created rules for the production of high quality SGI with improved fatigue strength on the basis of their results They divided non-metallic inclusions into white (Ti, Cr carbides) and black Mg-bearing inclusions. The continued segregation of the alloying elements on the basis of thermodynamic and mobility data and the formation of related precipitates is numerically calculated In this model simulation of the solidification and diffusion occurs along an axis that reflects a characteristic length, depending on the assumed morphology.
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a callMore From: IOP Conference Series: Materials Science and Engineering
Disclaimer: All third-party content on this website/platform is and will remain the property of their respective owners and is provided on "as is" basis without any warranties, express or implied. Use of third-party content does not indicate any affiliation, sponsorship with or endorsement by them. Any references to third-party content is to identify the corresponding services and shall be considered fair use under The CopyrightLaw.
