Experimental–Numerical Investigation for Layer-Wise-Heat-Input Management in GMA-Based Additive Manufacturing (Record no. 19086)

MARC details
000 -LEADER
fixed length control field a
003 - CONTROL NUMBER IDENTIFIER
control field OSt
005 - DATE AND TIME OF LATEST TRANSACTION
control field 20230329113122.0
008 - FIXED-LENGTH DATA ELEMENTS--GENERAL INFORMATION
fixed length control field 230329b xxu||||| |||| 00| 0 eng d
040 ## - CATALOGING SOURCE
Original cataloging agency AIKTC-KRRC
Transcribing agency AIKTC-KRRC
100 ## - MAIN ENTRY--PERSONAL NAME
9 (RLIN) 20341
Author Srivastava, S
245 ## - TITLE STATEMENT
Title Experimental–Numerical Investigation for Layer-Wise-Heat-Input Management in GMA-Based Additive Manufacturing
250 ## - EDITION STATEMENT
Volume, Issue number Vol,103(5), October
260 ## - PUBLICATION, DISTRIBUTION, ETC.
Place of publication, distribution, etc. USA
Name of publisher, distributor, etc. Springer
Year 2022
300 ## - PHYSICAL DESCRIPTION
Pagination 1059–1070p
520 ## - SUMMARY, ETC.
Summary, etc. Heat accumulation and consequential thermal residual stresses are the most challenging obstacles in the metal additive manufacturing (AM) processes. Accordingly, an understanding of the relation between various process parameters and residual stress evolution needs to be addressed in metal AM. Therefore, this article investigates adaptive layer-wise heat-input in gas metal arc-based additive manufacturing (GMA-WAAM) through the finite element method. A 3D finite element model has been developed using Mechanical Advanced Parametric Design Language of Ansys® software. A reduced current heat-input strategy has been adopted, i.e. the current is reduced for every next layer until the fourth layer. It is repeated for the next set of four layers. The effect of the proposed framework has been studied on the single-track eight-layered thin wall geometry. Further, experiments have been performed to validate the developed model. A good agreement has been found between predicted and experimental results. Moreover, the developed framework has been found as an effective strategy to control the evolution of accumulated heat and distortion in the substrate. A significant decrease in the maximum temperature was attained during the layer-wise deposition, i.e. 11.29% and 15.09% for the first and second sets of four layers.
650 #0 - SUBJECT ADDED ENTRY--TOPICAL TERM
9 (RLIN) 4626
Topical term or geographic name entry element Mechanical Engineering
700 ## - ADDED ENTRY--PERSONAL NAME
9 (RLIN) 20342
Co-Author Garg, R. K.
773 0# - HOST ITEM ENTRY
Place, publisher, and date of publication Kolkata Institution of Engineers (India)
International Standard Serial Number 2250-0545
Title Journal of the institution of engineers (India): Series C
856 ## - ELECTRONIC LOCATION AND ACCESS
URL https://link.springer.com/article/10.1007/s40032-022-00868-y
Link text Click here
942 ## - ADDED ENTRY ELEMENTS (KOHA)
Source of classification or shelving scheme Dewey Decimal Classification
Koha item type Articles Abstract Database
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Withdrawn status Lost status Source of classification or shelving scheme Damaged status Not for loan Home library Current library Shelving location Date acquired Total Checkouts Barcode Date last seen Price effective from Koha item type
    Dewey Decimal Classification     School of Engineering & Technology School of Engineering & Technology Archieval Section 29/03/2023   2023-0556 29/03/2023 29/03/2023 Articles Abstract Database
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