Change of Oxidation Mechanisms by Laser Chemical Machined Rim Zone Modifications of 42CrMo4 Steel.

Alexander Schupp,Daniela Zander,René Daniel Pütz,Tim Radel,Oliver Beyss,Lucas-Hermann Beste

doi:10.3390/ma14143910

Alexander Schupp, Daniela Zander + Show 4 more

Open Access

https://doi.org/10.3390/ma14143910

Copy DOI

Abstract

The oxidation mechanism of metals depends, among other factors, on the surface integrity. The surface and rim zone properties are often determined by the manufacturing process that was used to machine the material. Laser chemical machining (LCM) is a manufacturing process that uses laser radiation as a localized and selective heat source to activate a chemical reaction between an electrolyte and a metallic surface. The objective of this work is first to investigate how different LCM processes affect the rim zone properties of 42CrMo4. For this purpose, the surface chemistry is analyzed by EDS and XPS, phases and residual stresses are determined by XRD, and the morphology is investigated by SEM. Second, the influence of these modified rim zones on the oxidation properties of the steel at 500 °C in air is to be demonstrated in oxidation tests by in situ XRD and subsequent SEM/EDS investigations. A decisive influence of the oxides formed on the surface of 42CrMo4 during LCM in different electrolytes (NaNO3 solution and H3PO4) at two different laser powers on the high-temperature oxidation properties was demonstrated. These oxides were supposed to act as nucleation sites for oxide layer formation at 500 °C and led to an overall increase in oxide layer thickness after high-temperature oxidation compared to non-LCM-processed surfaces.

Highlights

The use of materials for engine components, such as cylinders, requires both excellent mechanical properties and sufficient high-temperature corrosion resistance
The surface and rim zone analysis of 42CrMo4 steel for the Laser chemical machining (LCM) machined surfaces and the ground surface was performed by SEM and X-ray photoelectron spectroscope (XPS) before oxidation
The rim zone properties generated by LCM have a significant effect on the oxidation behavior of 42CrMo4 steel below the wüstite temperature at 500 ◦C

Summary

Introduction

The use of materials for engine components, such as cylinders, requires both excellent mechanical properties and sufficient high-temperature corrosion resistance. It has been reported that the high-temperature oxidation behavior of 42CrMo4 steel, which is used for crankshafts, for example, depends on rim zone properties such as residual stresses, roughness and chemical composition [1]. These rim zone properties are determined by the mechanical, thermal, thermo-chemical or chemical loads of the applied manufacturing process. The relationships between LCM-manufactured rim zone properties and oxidation mechanisms of 42CrMo4 steel at high temperatures are not fully understood yet

Objectives

Methods

Results

Discussion

Conclusion