The titanium alloy TC6 was laser peened without coating (LPwC) with a pulsed Nd:YAG laser (1064 nm) at power densities of 3, 6 and 9 GW cm− 2. Microhardness data revealed that hardness does not linearly scale with power density. Residual stress analysis indicated that the profile has two distinct regions, one near surface (&lt; 100 μm) showing thermal effects due to laser beam-material interaction and a far-surface region (&gt; 100 μm) with decreasing compressive residual stresses with increasing power density. Transmission electron microscopy (TEM) showed high dislocation density with dislocation tangles and dislocation walls without dislocation cell or nanocrystals in the near surface region. Synchrotron radiation showed the increase in volume fraction of β phase with increase in power density in the far-surface region. Fatigue performance of the samples (number of cycles to failure) subjected to LPwC at a power density of 6 GW cm− 2 was found to have increased by a factor of 2–4, in the load range of 12.5–15 kN. Further, it was observed that in addition to the normally observed sub-surface crack nucleation of LPwC samples, additional formation of β phase in the far-surface region improves fatigue performance. © 2017 Elsevier Inc.

Sathya Swaroop N-R

Department of Physics

School of Advanced Sciences

Vellore Campus

Umapathi A

Vellore Institute of Technology (VIT) is a private university located in&nbsp;Tamil Nadu, India. Founded in 1984, as Vellore Engineering College, the institution offers 20 undergraduate, 34 postgraduate, four integrated and four research programs. It has campuses in Vellore, Amravati, Bhopal and Chennai.

VIT is one of the top ranked private universities in India according to NIRF, THE and QS Rankings.&nbsp;Govt. of India has recognized&nbsp;VIT, Vellore as an&nbsp;Institution of Eminence. This has allowed VIT to take independent quality initiatives and move up in world ranking.

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VIT University

Materials Characterization

The titanium alloy Ti-6Al-4V was subjected to laser peening (without coating) at power densities of 3, 6 and 9 GW cm−2. The cross sectional profiles of microhardness and residual stress indicated softening in the bulk (away from the surface) at power density of 9 GW cm−2. This behavior was analyzed using a combination of Zerilli-Armstrong phenomenological model in conjunction with the concept of adiabatic heating. The implications of this analysis was supported by structural changes in terms of α → β transition (analyzed through synchrotron radiation) and microstructural changes in terms of primary α (equiaxed) to secondary α (lamellar) transformation, which is observed for the first time here. Based on this, optimum levels of peening to improve fatigue lives are suggested through relevant experiments. © 2019 Elsevier Ltd

Optics & Laser Technology

Mechanical properties of a laser peened Ti-6Al-4V

In the present study, Ti-15V-3Al-3Cr-3Sn (Ti-15-3), a beta titanium aerospace alloy in solution treated condition (850 °C/1 h) was subjected to Laser Peening without Coating (LPwC) with a wavelength of 532 nm and power density of 8.96 GW cm−2. Surface roughness was analysed using 3D optical topography. Curiously, in the near peened surface, peening induced precipitation (i.e. 19% of α precipitation) and increased fraction of low angle boundaries (∼123%) was revealed through the Electron Back Scattered Diffraction (EBSD) analysis. Through depth nanohardness measurement was carried out along the cross-section of the peened sample right from the near peened surface. Peak hardness of 4.6 GPa is observed at a depth of 100 µm from the peened surface while the base/bulk hardness of the material is 4 GPa. In addition, X-Ray Diffraction (XRD) based analysis confirmed the presence of compressive residual stress in the near surface region of the peened sample. To understand the effect of the peening induced microstructural changes and residual stresses in fatigue behaviour, staircase method of fatigue analysis was adopted and observed that the more number of run out samples belonged to laser peened condition when compared to the unpeened condition. Despite this favourable indication, fatigue limit remains more or less unaltered even after peening. Fractography studies revealed the least influence of the surface roughness induced by laser peening over the crack initiation. Irrespective of the condition (i.e. unpeened and laser peened), crack initiation was predominantly influenced by the stress concentration co-existing at the sharp corners. © 2018 Elsevier Ltd

Influence of laser peening without coating on microstructure and fatigue limit of Ti-15V-3Al-3Cr-3Sn

Laser shock peening (LSP) is a modern and efficient thermo-mechanical approach to engineer and modify the surface and subsurface related properties of materials which has been frequently opted by contemporary researchers in the field of peening. The main objective of this review article is to emphasize LSP as a post weld treatment method which may help in the commercialization of LSP which is considered a challenge till date. Combining laser welding and laser shock peening could be an alternative and promising approach for improving weld quality over different conventional methods of post weld treatments. With this hindsight, reports incorporating welding and peening in last decades are reviewed. The notable effects of LSP on the mechanical properties and microstructure of different weldments are also discussed along with the classification and important parameters of LSP. We conclude that LSP can indeed be used as an effective post weld treatment (PWT) method in industrial manufacturing process. © 2018

Journal of Manufacturing Processes

Review: Laser shock peening as post welding treatment technique

Laser peening without protective coating (LPwC) is an advanced mechanical surface modification method being used for a wide range of metallic materials for improving their fatigue and corrosion properties. The literature review of LPwC for the last two decades is systematically presented. The mechanism and experimental parameters of LPwC are described comprehensively. The major factors that influence the fatigue or corrosion properties, for example, compressive residual stress (CRS) and surface roughness, are analyzed with great care using the available data from the literature. A list of suggestions for future work in LPwC is given at the end. © 2017 Taylor &amp; Francis.

Materials and Manufacturing Processes

Laser peening without coating—an advanced surface treatment: A review

The goal of the present study is to investigate residual stress distributions and the accompanying deformation mechanisms during the process of laser peening without coating (LPwC), carried out on a Ti-2.5Cu alloy at a fixed power density of 6.97 GW cm− 2 with overlap rates from 50 to 90% (in steps of 10%). Thermal softening near surface (confined to a depth of 50 μm) from laser beam-material interaction was observed. Work-hardening increased with increase in overlap percentage till 80%. The maximum residual stress was found to be − 889 MPa for an optimal 70% overlap. Twinning was found to increase with the increase in overlap rates, indicating the hardening of the sample. The combined effect of adiabatic heating and thermal effects at the surface due to laser beam-material interaction (propagating inside the material), results in the softening of the material. The softening was found to be only in the onset stage, without flow localization. Softening predominates hardening beyond the overlap rates of 80% and the implications for this towards multiple peening are discussed. © 2016 Elsevier B.V.

Surface and Coatings Technology

Residual stress distribution in a laser peened Ti-2.5Cu alloy

Laser peening without coating (LPwC) was performed on austenitic stainless steel AISI 321 with a power density of 5.97 GW cm-2 and pulse densities of 1600, 2500 and 3900 pulses cm-2. A large compressive residual stress resulted for 1600 pulses cm-2. Surface roughness was found to have increased to a relatively smaller extent with lesser number of valleys or peaks. Micro-hardness increased after the process with the depth of hardened layer extending up to 900 μm. LPwC induced martensitic phase transformation (about 18% in volume fraction) was observed near treated surface. Microstructures confirmed the phase transformation effect. The grains were not refined as a result of single LPwC scan. Thermal relaxation of residual stresses at 700 °C for 2 h were 41% in longitudinal and 140% in transverse (relative to LPwC scanning) directions. The influential factors on stress relaxation were discussed. No significant reduction in hardness was seen after thermal treatment. Followed by the thermal treatment, fully austenitic phase was recovered. © 2016 Elsevier B.V.

Laser peening without coating induced phase transformation and thermal relaxation of residual stresses in AISI 321 steel

The present study investigates the effect of laser peening without coating on aluminum alloy Al-6061-T6 with a 300 mJ infrared laser. The surface topography, microstructure, surface topography, surface residual stress and micro-hardness of peened and unpeened surfaces were studied. The study shows that laser peening without coating can significantly improve surface compressive stress and micro-hardness with trivial increase in surface roughness. Microstructure evaluation confirmed there was no near surface solidification after LPwC. © 2012 Elsevier Ltd.

Laser peening without coating on aluminum alloy Al-6061-T6 using low energy Nd:YAG laser

This paper discusses the results of laser peening without coating on low carbon austenitic stainless steel 316L. Unlike typical experiments on laser peening without coating (LPwC) performed with frequency doubled (green) laser and underwater irradiation, the present study reports LPwC with infrared radiation using thin layer of water as confinement medium. The dependence of laser pulse density on properties such as surface roughness, surface residual stress, microhardness, and corrosion behavior of LPwC specimen were investigated. The magnitude of surface compressive residual stress on laser peened specimen showed appreciable improvement compared to unpeened base material. Microhardness of the specimen improved by 3040% after LPwC. However, the potentiodynamic polarization study indicated that though there is an enhancement of corrosion potential (E corr), the corrosion current density (I corr) increased with increase in laser pulse density. © 2012 Elsevier Ltd.

Journal	Data powered by TypesetMaterials Characterization
Publisher	Data powered by TypesetElsevier BV
ISSN	1044-5803
Open Access	0