ArticleName |
Investigation of a cooled top ingot structure and the analysis of metal quality of the hollow forgings produced from this ingot |
ArticleAuthorData |
Volgograd State Technical University (Volgograd, Russia):
Rutskii D. V., Cand. Eng., Ass. Prof., Chair of Materials Technology Zyuban N. A., Dr. Eng., Prof., Head of Chair of Materials Technology, e-mail: tecmat@vstu.ru; tecmat49@vstu.ru Gamanyuk S. B., Cand. Eng., Ass. Prof., Chair of Materials Technology Chubukov M. Yu., Post-graduate, Chair of Materials Technology |
Abstract |
The analysis of the standard sizes of forgings, produced at machine building factories, shows that most forgings are hollow. Hollow and elongated ingots, both with and without a hot top, are used to manufacture such forgings.Ingot solidifi cation is accompanied with defect development inside the ingot. These defects can achieve considerable dimensions and fully or partially transfer to the forging after ingot deformation or mechanical treatment. These defects may result in rejecting the forging either during its production or delivery trials. Optical and electronic microscopy methods are used in the paper to investigate the quality of steel 38XH3MФA in a 1.53 ton ingot teemed into a mold with a top cooling unit. In addition, an investigation was carried out to analyze metal quality of hollow forgings fabricated from ingots with a cooled top and a heat insulated hot top unit. A metallographic study and mathematical modeling have established that if ingot top is cooled, solidifi cation occurs faster throughout practically the entire ingot mass and shifts the heat center to the ingot central axial zone. Top cooling results in a more favorable location of the shrinkage cavity which has a considerable length and a small diameter. These factors make it possible to fully remove the cavity during ingot deformation to producea hollow forging. Teeming ingots with a cooled top makes it possible to produce hollow forgings with a higher chemical heterogeneity over the ingot length and cross section; besides, ingot-to-product yield can be increased on the average by 7%. The reported study was funded by RFBR, according to the research project No. 15-08-08098 А and No. 16-08-01029 А, and № 16-38-60007 мол_а_дк». |
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