Abstract
The aim of this work is to compare the technological and material properties of CMnCr steels without bismuth, with 0.08 wt. % Bi and 0.12 wt. % Bi. Experimental heats showed that the most advantageous alloying of Bi into the heat was in the ladle, with an efficiency of about 20%. The optimal temperature range for forming steel was found to be 1160–1050 °C. With increasing Bi content, the formability of steels and plastic properties decreased, while the yield stress and tensile strength increased. Manganese sulfides, aluminum oxides, or oxysulfides, which were segregated both individually and in clusters, were found in the matrix of all tested steels. In steels with Bi, the Bi particles segregate the separately in the form of globules, either as envelopes of elongated MnS or Al2O3 particles segregated in rows. Sulfur dot-shaped segregations in the steel with 0.12 wt. % of Bi and the steel without Bi were essentially uniform over the whole area. For the steel with 0.08 wt. % of Bi, both dot-like and ray-ordered sulfur segregations were observed. The microstructure of all tested steels was ferritic–pearlitic with islands of bainite. Towards the center of the forged bars, variable shape and size of bainite blocks were observed. Machinability tests evaluated by the extend of tool wear showed that the most advantageous was CMnCr steel alloyed with 0.08 wt. % Bi.
Highlights
IntroductionThe properties of free cutting steels are designed for the easy machining of products, which is one of the key technological requirements, especially in the automotive industry
Free cutting steels belong to the group of special steels
Experiments were realized in three trial heats of low-alloy CMnCr steels, which were alloyed with bismuth in the form of a filled profile with a composition of 93 wt. % Bi and
Summary
The properties of free cutting steels are designed for the easy machining of products, which is one of the key technological requirements, especially in the automotive industry. Machining costs represent approximately 50% of the value of the machined part. Other properties, such as response to heat treatment, mechanical resistance, fatigue characteristics, corrosion resistance, brittle fracture properties, etc., are secondary aspects of these steels, in many cases they can be a determining parameter for the selection of steel grade [1]. Alloying with sulfur and lead is used in the development and optimization of the properties of free cutting steels, and the addition of other elements like phosphorus, lead, selenium, tellurium, antimony, calcium, bismuth, or tin [2]
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