Mechanical Response and Failure Evolution of 304L Stainless Steel under the Combined Action of Mechanical Loading and Laser Heating

Mohsan Jelani,Zhonghua Shen,Najam Hassan,Zewen Li,Maryam Sardar

doi:10.3390/met8080620

Mohsan Jelani, Zhonghua Shen + Show 3 more

Open Access

https://doi.org/10.3390/met8080620

Copy DOI

Journal: Metals	Publication Date: Aug 7, 2018
Citations: 6	License type: CC BY 4.0

Affiliation: Nanjing University of Science and Technology

Abstract

Deformation and fracture properties of structural materials are greatly influenced by the factors like applied load, state of stress, and temperature. A precise prediction of the material properties of stainless steel at elevated temperature is necessary for determining the load-carrying capacity of structures under severe conditions. The present work reports the deformation and failure characteristics of 304L stainless steel subjected to combined laser heating and mechanical loading. The effect of main parameters on stress-strain, fracture characteristics, failure time, and temperature profile of specimens have been explored. Specimens were subjected to prescribed loading states, and then irradiated by a continuous wave fiber (1.08 µm) laser. The stress-strain curves indicated that the specimens experienced slight strain hardening in a specific temperature range prior to fracture. The specimen’s ultimate failure time is found to be reduced by increasing either laser power density or preload level. Fracture on a microscopic scale was predominantly ductile, comprising dimples as well as micro-void nucleation, growth, and coalescence. With the increase of laser power density, dimples rupture is the primary fracture mode, while with the increase of preload value, relatively more in-depth and severe deformation effects were observed. The description and characterization of 304L stainless steel failure under the simultaneous action of laser heating and tensile stress have been explored in detail.

Highlights

It is well known that the deformation and fracture properties of structural steels are significantly influenced by the factors like type of load, loading rate, and temperature [1,2]
304L stainless steel is extensively used in a wide range of load-bearing applications due to its superior corrosion resistance, formability, and mechanical properties [1,3,4,5]
Different components may experience the severe thermal loading situations that might be induced by local intense fire, laser irradiation, or by aerodynamic heating [6]

Summary

Introduction

It is well known that the deformation and fracture properties of structural steels are significantly influenced by the factors like type of load, loading rate, and temperature [1,2]. Different components may experience the severe thermal loading situations that might be induced by local intense fire, laser irradiation, or by aerodynamic heating [6]. The development of thermal stresses, along with a distinct degradation of mechanical properties at high temperatures, may considerably increase the possibility of fracture in structural components exposed to high operational loads [7,8]. It is worthwhile to investigate the predictions of the mechanical responses of steel structures exposed to loaded conditions. An understanding of the plastic response of the 304L stainless steel under severe environment is crucial to develop a complete characterization of the material

Methods

Results

Conclusion