The Effects of Rust on the Gas Carburization of AISI 8620 Steel

Wang, Xiaolan

31 July 2008

"The effects of rust on the carburization behavior of AISI 8620 steel have been experimentally investigated. AISI 8620 steel samples were subjected to a humid environment for time of 1 day to 30 days. After the exposure, a part of the samples was cleaned by acid cleaning. Both cleaned and non-cleaned samples have been carburized, followed by quenching in mineral oil, and then tempered. To determine the effect of rust on gas carburizing, weight gained by the parts and the surface hardness were measured. Surface carbon concentration was also measured using mass spectrometry. Carbon flux and mass transfer coefficient have been calculated. The results show that acid cleaning removes the rust layer effectively. Acid cleaned samples displayed the same response to carburization as clean parts. Rusted parts had a lower carbon uptake as well as lower surface carbon concentration. The surface hardness (Rc) did not show a significant difference between the heavily rusted sample and clean sample. It has been observed that the carbon flux and mass transfer coefficient are smaller due to rust layer for the heavily rusted samples. These results are discussed in terms of the effects of carbon mass transfer on the steel surface and the resulting mass transfer coefficient."

rust formation

AISI 8620 steel

gas carburizing

Steel

Corrosion

Steel

Heat treatment

Steel alloys

Case hardening

MICROSTRUCTURE DEVELOPMENT IN MULTI-PASS LASER MELTING OF AISI 8620 STEEL

Matthew L Binkley (9182462)

29 July 2020

<p>An existing thermal model for laser melting and additive manufacturing (AM) was expanded to include phase transformation and hardness predictions for an alloy steel and coupled to experimental results. The study was performed on AISI 8620, a popular case-hardening, steel to understand microstructural and property effects for potential repair applications. The experimental samples were polished, etched with nital and picral for comparison, imaged, and Vicker’s microhardness was taken at 0.5 and 0.2 kg loads. The etched images revealed a transformation zone slightly larger than the melt zone in all cases including a gradient in transformation along the outer edges of the transformation zones. The microhardness measurements revealed that the lower energy cases provided a higher hardness in the melted region even after tempering due to multiple passes. But the overall hardness was higher than what is to be expected of a fully martensitic structure in AISI 8620. The phase transformation model qualitatively shows a similar microstructure where molten regions turn completely to martensite. The model also predicts a transformation zone larger than the melt pool size, as well as the transformation of pearlite but not ferrite near but not in melt pool. This observation is experimentally verified showing a heat affected zone where pearlite is clearly transformed but not ferrite outside the transformation zone comprised of complete martensite. The hardness model predicts a lower hardness than the experiments but is similar to what is expected based on published Jominy End Quench tests. The cases in the regime dominated by conductive heat transfer show good agreement with the predictions of melt pool shape and hardness by the thermal model. However, at higher powers and lower speeds, the fluid flow influenced the shape of the melt pool and the hat transfer in its vicinity, and the model was less accurate.</p>

Metals and Alloy Materials

Additive Manufacturing

steel

AISI 8620

Laser

additive manufacturing

Microstructure modeling