The behaviour of geometrically-reinforced thin plates under thermoacoustic loading: A comparison of additive and subtractive manufacturing

Lambros, J, Middleton, CA ORCID: 0000-0001-9488-9717, Patterson, EA ORCID: 0000-0003-4397-2160 and Weihrauch, M (2026) The behaviour of geometrically-reinforced thin plates under thermoacoustic loading: A comparison of additive and subtractive manufacturing JVC Journal of Vibration and Control. ISSN 1077-5463, 1741-2986

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Abstract

Additive manufacturing (AM) is gaining in popularity as an approach to producing metallic components of complex geometry relatively cheaply and rapidly from digital representations. However, concerns about the impact of residual stresses induced by additive manufacturing on the distortion of parts has limited its application in some fields. Residual stresses in parts that lack rotational symmetry and, or have cross-sections with large aspect ratios could cause significant changes in the structural and dynamic performance of the parts due to changes in their shape. In this study, geometrically-reinforced thin plates of a nickel-chromium alloy have been manufactured using classical, subtractive machining processes, and additively using laser-powder bed fusion (PBF-LB). Their final shapes were measured using stereoscopic digital image correlation. Their thermoacoustic performance was investigated by subjecting them to random broadband excitation between 0 and 2000 Hz while applying a series of spatial distributions of heat so that the plates increased from room temperature to an equilibrium temperature of about 800°C and then were allowed to cool when the heating was switched off. Time-frequency spectrograms were measured during the heating and cooling over a greater frequency range (0 to 2000 Hz) than achieved previously. Mode shifting and mode switching, or jumping, was observed; however, the residual strains induced by the manufacturing processes dominated the thermoacoustic behaviour, with almost no effect from the method of manufacturing.

Item Type:	Article
Uncontrolled Keywords:	mode shifting, mode switching, additive manufacturing, time-frequency spectrograms
Divisions:	Faculty of Science & Engineering Faculty of Science & Engineering > School of Engineering Faculty of Science & Engineering > School of Engineering > Mechanical and Aerospace Engineering
Depositing User:	Symplectic Admin
Date Deposited:	24 Feb 2026 15:38
Last Modified:	13 Mar 2026 23:28
DOI:	10.1177/10775463261428641
Open Access URL:	https://doi.org/10.1177/10775463261428641
Related Websites:	Author Publisher
URI:	https://livrepository.liverpool.ac.uk/id/eprint/3197184
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