Estimation of laser shock peening induced plastic deformation in Hastelloy-X superalloys

S. Nath; P. Shukla; X. Shen; A. Behera; J. Lawrence

Estimation of laser shock peening induced plastic deformation in Hastelloy-X superalloys

S. Nath, P. Shukla, X. Shen, A. Behera, J. Lawrence

Research output: Contribution to journal › Article › peer-review

Abstract

The goals of the present study are to strengthen a new, Hastelloy-X superalloys by prestressing the surface with laser-plasma driven shock waves and also to quantify the effect of Laser Shock Peening (LSP) on the evolution of phase, residual stress (both through thickness and on the surface), dislocation density, and hardness of Hastelloy-X superalloys. Dislocation densities in the peened and unpeened samples were measured by Wiliamson and Smallman approach to analyze the severity of plastic deformation following LSP surface treatment. The maximum compressive residual stress measured on the peened surface of Hastelloy-X samples using incremental hole drilling technique was 850 MPa. In addition, it was found that the LSP parameters have a dominant effect in tailoring the surface hardening behavior and residual stress in Hastelloy-X superalloys.

Original language	English
Pages (from-to)	233-257
Number of pages	25
Journal	International Journal of Peening Science & Technology
Volume	1
Issue number	3
Publication status	Published - 1 Sept 2019
Externally published	Yes

Keywords

laser shock peening
residual stress
incremental hole drilling
dislocation density
strain hardening

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title = "Estimation of laser shock peening induced plastic deformation in Hastelloy-X superalloys",

abstract = "The goals of the present study are to strengthen a new, Hastelloy-X superalloys by prestressing the surface with laser-plasma driven shock waves and also to quantify the effect of Laser Shock Peening (LSP) on the evolution of phase, residual stress (both through thickness and on the surface), dislocation density, and hardness of Hastelloy-X superalloys. Dislocation densities in the peened and unpeened samples were measured by Wiliamson and Smallman approach to analyze the severity of plastic deformation following LSP surface treatment. The maximum compressive residual stress measured on the peened surface of Hastelloy-X samples using incremental hole drilling technique was 850 MPa. In addition, it was found that the LSP parameters have a dominant effect in tailoring the surface hardening behavior and residual stress in Hastelloy-X superalloys.",

keywords = "laser shock peening, residual stress, incremental hole drilling, dislocation density, strain hardening",

author = "S. Nath and P. Shukla and X. Shen and A. Behera and J. Lawrence",

year = "2019",

month = sep,

day = "1",

language = "English",

volume = "1",

pages = "233--257",

journal = "International Journal of Peening Science & Technology",

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TY - JOUR

T1 - Estimation of laser shock peening induced plastic deformation in Hastelloy-X superalloys

AU - Nath, S.

AU - Shukla, P.

AU - Shen, X.

AU - Behera, A.

AU - Lawrence, J.

PY - 2019/9/1

Y1 - 2019/9/1

N2 - The goals of the present study are to strengthen a new, Hastelloy-X superalloys by prestressing the surface with laser-plasma driven shock waves and also to quantify the effect of Laser Shock Peening (LSP) on the evolution of phase, residual stress (both through thickness and on the surface), dislocation density, and hardness of Hastelloy-X superalloys. Dislocation densities in the peened and unpeened samples were measured by Wiliamson and Smallman approach to analyze the severity of plastic deformation following LSP surface treatment. The maximum compressive residual stress measured on the peened surface of Hastelloy-X samples using incremental hole drilling technique was 850 MPa. In addition, it was found that the LSP parameters have a dominant effect in tailoring the surface hardening behavior and residual stress in Hastelloy-X superalloys.

AB - The goals of the present study are to strengthen a new, Hastelloy-X superalloys by prestressing the surface with laser-plasma driven shock waves and also to quantify the effect of Laser Shock Peening (LSP) on the evolution of phase, residual stress (both through thickness and on the surface), dislocation density, and hardness of Hastelloy-X superalloys. Dislocation densities in the peened and unpeened samples were measured by Wiliamson and Smallman approach to analyze the severity of plastic deformation following LSP surface treatment. The maximum compressive residual stress measured on the peened surface of Hastelloy-X samples using incremental hole drilling technique was 850 MPa. In addition, it was found that the LSP parameters have a dominant effect in tailoring the surface hardening behavior and residual stress in Hastelloy-X superalloys.

KW - laser shock peening

KW - residual stress

KW - incremental hole drilling

KW - dislocation density

KW - strain hardening

M3 - Article

SN - 2473-506X

VL - 1

SP - 233

EP - 257

JO - International Journal of Peening Science & Technology

JF - International Journal of Peening Science & Technology

IS - 3

ER -

Estimation of laser shock peening induced plastic deformation in Hastelloy-X superalloys

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Keywords

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