The Structure and Mechanical Properties of VT23 Welded Joints with Surface Layer Modified by Ultrasonic Mechanical Forging

The Structure and Mechanical Properties of VT23 Welded Joints with Surface Layer Modified by Ultrasonic Mechanical Forging

The structure and mechanical properties of welded joints of VT23 titanium alloy received by method of laser welding after modifying the surface layers by ultrasonic mechanical forging (Treatment 1 and Treatment 2) were investigated. The experimental tests have revealed that the Treatment 2 provides...

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Veröffentlicht in:Key engineering materials 2017-07, Vol.743, p.264-268
Hauptverfasser: Smirnova, Anastasia, Pochivalov, Yury, Orishich, Anatoly, Malikov, Aleksandr G., Gorbunov, Anton, Panin, Victor, Fomin, Vasily
Format: Artikel
Sprache:eng
Schlagworte:
Beta phase
Brittleness
Chromium
Clustering
Ductility
Fatigue life
Fatigue tests
Forging
Laser beam welding
Mechanical properties
Metal fatigue
Molybdenum
Plastic deformation
Surface layers
Titanium alloys
Titanium base alloys
Vanadium
Welded joints
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container_end_page 268
container_issue
container_start_page 264
container_title Key engineering materials
container_volume 743
creator Smirnova, Anastasia
Pochivalov, Yury
Orishich, Anatoly
Malikov, Aleksandr G.
Gorbunov, Anton
Panin, Victor
Fomin, Vasily
description The structure and mechanical properties of welded joints of VT23 titanium alloy received by method of laser welding after modifying the surface layers by ultrasonic mechanical forging (Treatment 1 and Treatment 2) were investigated. The experimental tests have revealed that the Treatment 2 provides a multiple increase in the relaxation property in fatigue life test. The formation of nonuniform distribution of vanadium, chromium and molybdenum in the welded joint increases the strength and, at the same time, the brittleness of β-phase. Mechanical treatment of the surface layers in the second mode provides a multiple increase in ductility up to 13%, in the as-received condition up to 9.9%. In consequence of plastic deformation, the β-phase intensity reduces twice with Treatment 2 which is related to its clustering. As follows from a presented data, the fatigue life of the VT23 titanium alloy has increased more than threefold.
doi_str_mv 10.4028/www.scientific.net/KEM.743.264
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subjects Beta phase
Brittleness
Chromium
Clustering
Ductility
Fatigue life
Fatigue tests
Forging
Laser beam welding
Mechanical properties
Metal fatigue
Molybdenum
Plastic deformation
Surface layers
Titanium alloys
Titanium base alloys
Vanadium
Welded joints
title The Structure and Mechanical Properties of VT23 Welded Joints with Surface Layer Modified by Ultrasonic Mechanical Forging
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