FRIC webinar: High-Pressure Water Mist Applications for Façade Fires

ID nummer: FRIC webinar D4.1-2021.07</p

FRIC webinar: High-Pressure Water Mist Applications for Façade Fires

ID nummer: FRIC webinar D4.1-2021.07</p

Hydrogen uptake and diffusivity in steel armor wires with different chemical composition, carbide distribution, grain size, and degree of deformation

In this study, six flexible pipe steel armor wires used in oil and gas transportation are characterized, and their hydrogen diffusion coefficients and hydrogen uptakes are measured using an electrochemical hydrogen permeation technique. The wires have ferritic–pearlitic microstructures with round, lamellar, or partially lamellar carbides and the shape and orientation of the grains indicate that the microstructures were plastically deformed to different degrees. It was assumed that hydrogen was transported through the ferrite, so the presence of cementite in the steel armor wires leads to longer hydrogen diffusion paths through the ferrite, which was quantified with a tortuosity factor. After compensating for tortuosity, the normalized steady-state flux shows a tendency to increase as the grain size decreases. The effective diffusion coefficients increase with a decrease of the ferrite–cementite interface area, suggesting trapping on the ferrite–cementite interfaces. The uptake of diffusible hydrogen was lowest for the least plastically deformed materials and about twice as high for the more plastically deformed materials.Fil: Skilbred, Ellen S.. Norwegian University of Science and Technology; NoruegaFil: Kappes, Mariano Alberto. Consejo Nacional de Investigaciones Científicas y Técnicas; Argentina. Universidad Nacional de San Martín. Instituto Sabato; ArgentinaFil: Iannuzzi, Mariano. Norwegian University of Science and Technology; Noruega. Curtin University; AustraliaFil: Johnsen, Roy. Norwegian University of Science and Technology; Norueg