Deformation Control of TC4 Titanium Alloy in Thin-Walled Hyperbolic Structures During Hot Forming Processes

The thin-walled hyperbolic structures made from titanium alloy primarily encompass two typical forms: hyperbolic convex and hyperbolic concave (saddle). This paper addresses the technical challenges associated with the forming processes that frequently result in ripples or wrinkles in these configur...

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Veröffentlicht in:	Materials 2024-12, Vol.17 (24), p.6146
Hauptverfasser:	Zhang, Tao, Xia, Jianchao, Han, Xiuquan, Du, Lihua, Chen, Lihua, Han, Yujie, Cao, Fengchao, Wang, Duoduo, Liu, Xiaochuan
Format:	Artikel
Sprache:	eng
Schlagworte:	Aerospace engineering Aerospace industry Aircraft Constitutive models Defects Hot forming Hot pressing Manufacturing Mechanical properties Ripples Specialty metals industry Temperature Tensile tests Titanium Titanium alloys Titanium base alloys Yield stress
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creator	Zhang, Tao Xia, Jianchao Han, Xiuquan Du, Lihua Chen, Lihua Han, Yujie Cao, Fengchao Wang, Duoduo Liu, Xiaochuan
description	The thin-walled hyperbolic structures made from titanium alloy primarily encompass two typical forms: hyperbolic convex and hyperbolic concave (saddle). This paper addresses the technical challenges associated with the forming processes that frequently result in ripples or wrinkles in these configurations. Specifically, it investigates precision control techniques for the hot forming process of thin-walled hyperbolic skins from TC4 titanium alloy. The present study examines the relationship between the instability characteristics and defect features of the thin-walled hyperbolic skins, establishing a constitutive model for TC4 titanium alloy and conducting uniaxial tensile tests. For the hyperbolic convex skin and the hyperbolic saddle skin, small-margin coupled hot pressing and curved edge forming processes are employed, respectively. Results are analyzed to identify the forms and distribution patterns of forming defects across different geometries. Furthermore, the surface accuracy following the forming processes is compared, culminating in a summary of the relationship between the ratio of the sum of chord heights to the sum of chord lengths and the occurrence of ripples and wrinkles.
doi_str_mv	10.3390/ma17246146
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This paper addresses the technical challenges associated with the forming processes that frequently result in ripples or wrinkles in these configurations. Specifically, it investigates precision control techniques for the hot forming process of thin-walled hyperbolic skins from TC4 titanium alloy. The present study examines the relationship between the instability characteristics and defect features of the thin-walled hyperbolic skins, establishing a constitutive model for TC4 titanium alloy and conducting uniaxial tensile tests. For the hyperbolic convex skin and the hyperbolic saddle skin, small-margin coupled hot pressing and curved edge forming processes are employed, respectively. Results are analyzed to identify the forms and distribution patterns of forming defects across different geometries. 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subjects	Aerospace engineering Aerospace industry Aircraft Constitutive models Defects Hot forming Hot pressing Manufacturing Mechanical properties Ripples Specialty metals industry Temperature Tensile tests Titanium Titanium alloys Titanium base alloys Yield stress
title	Deformation Control of TC4 Titanium Alloy in Thin-Walled Hyperbolic Structures During Hot Forming Processes
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