Wetting Angle Measurement of Liquid PbBi on RAFM Steel Surface Based on Ellipse Fitting

Bao Guo Pan; Wei Hua Wang; De Lin Chu; Jin Hong Yang; Luo Qin Mei; Qiang Hua Zhang; Peng Wang; Jun Wang

doi:10.4028/www.scientific.net/AMR.820.102

Paper Titles

Flammability and Thermal Degradation of Polystyrene/Cadmium Sulfate Nanocomposites
p.84

Stopping Power for Ions Moving in Magnetized Plasma
p.88

SEM Image and EDS Composition Analysis of Al₂O₃ Power under Low Vacuum Level Condition
p.92

Research on Ultrasonic Testing of Coarse-Grain Materials with Hilbert-Huang Transform
p.97

Wetting Angle Measurement of Liquid PbBi on RAFM Steel Surface Based on Ellipse Fitting
p.102

Residual Stress Analysis of Polycrystalline Diamond after Electrical Discharge Machining
p.106

Effect of Buffer Layer Thickness on Fatigue and Residual Stress of Welded High-Strength Low-Alloy
p.110

Research on Hydraulic Control System of Straightening Machine with Nine Rolls for Plates Based on BP Neural Network PID Controller
p.117

Five-Axis NC Simulating Manufacturing of Titanium Alloy Integral Impeller
p.122

HomeAdvanced Materials ResearchAdvanced Materials Research Vol. 820Wetting Angle Measurement of Liquid PbBi on RAFM...

Wetting Angle Measurement of Liquid PbBi on RAFM Steel Surface Based on Ellipse Fitting

Abstract:

The fusion power is considered an ideal energy for the future due to abundant, green and safety. Wetting properties between the liquid metal and the structural materials in the liquid blanket of the fusion reactor related to the heat exchange efficiency and the irradiated plasma resistance, and directly related to the service life of the reactor structural materials. This article describes the wetting angle measurement experimental procedure of liquid lead-bismuth (PbBi) at reduced activation ferritic/martensitic steel (RAFM steel) surface based on the high-temperature static sessile drop method under the protection of high purity argon, including the images enhancement processing obtained by CCD camera, using ellipse fitting method to calculate the wetting angle, and were measured at 350-600°C. The experimental results show that the wetting angles of liquid PbBi and RAFM steel are greater than 140°, non-wetting.