TY - JOUR

T1 - Suspended water droplet confined laser shock processing at elevated temperatures

AU - Liu, J.

AU - Zhang, X.

AU - He, Y.

AU - Zhao, Z.

AU - Xia, M.

AU - Hu, Y.

PY - 2022/8/31

Y1 - 2022/8/31

N2 - The temperature-assisted laser shock process has application prospects in various manufacturing fields such as forming and surface strengthening. However, the large-scale application of this process is limited by the instability and failure of confinement medium at high temperatures (>300 °C). To address this problem, this paper proposes a novel laser shock strategy based on the Leidenfrost effect, wherein suspended droplets are used as the confinement medium. The dynamic behaviors of the droplets during laser shock process were studied. The focusing enhancement effect of the droplets was comprehensively explored. By combining the dynamic behaviors and focusing enhancement effect of the droplets, a theoretical model of the laser shock pressure under droplet confinement was established. Finally, a typical application of the droplet-confined laser shock process in the fields of forming and strengthening was demonstrated to verify its effectiveness and feasibility at high temperatures. The proposed process provides a flexible, convenient, and green plasma confinement strategy that allows stable operation of laser shock at high temperatures. Moreover, the droplet confinement strategy broadens the application prospects of laser shock, and provides a technical support for enabling enhanced ductility and dynamic strain aging of alloys at high temperatures.

AB - The temperature-assisted laser shock process has application prospects in various manufacturing fields such as forming and surface strengthening. However, the large-scale application of this process is limited by the instability and failure of confinement medium at high temperatures (>300 °C). To address this problem, this paper proposes a novel laser shock strategy based on the Leidenfrost effect, wherein suspended droplets are used as the confinement medium. The dynamic behaviors of the droplets during laser shock process were studied. The focusing enhancement effect of the droplets was comprehensively explored. By combining the dynamic behaviors and focusing enhancement effect of the droplets, a theoretical model of the laser shock pressure under droplet confinement was established. Finally, a typical application of the droplet-confined laser shock process in the fields of forming and strengthening was demonstrated to verify its effectiveness and feasibility at high temperatures. The proposed process provides a flexible, convenient, and green plasma confinement strategy that allows stable operation of laser shock at high temperatures. Moreover, the droplet confinement strategy broadens the application prospects of laser shock, and provides a technical support for enabling enhanced ductility and dynamic strain aging of alloys at high temperatures.

KW - Droplet

KW - Laser shock

KW - High temperatures

KW - Dynamics

KW - Focusing enhancement

U2 - 10.1016/j.ijmachtools.2022.103917

DO - 10.1016/j.ijmachtools.2022.103917

M3 - Journal article

VL - 179

JO - International Journal of Machine Tools and Manufacture

JF - International Journal of Machine Tools and Manufacture

SN - 0890-6955

M1 - 103917

ER -