Ice sintering: Dependence of sintering force on temperature, load, duration, and particle size
Journal article, 2022

We present experiments along with an approximate, semi-analytic, close-form solution to predict ice sintering force as a function of temperature, contact load, contact duration, and particle size during the primary stage of sintering. The ice sintering force increases nearly linear with increasing contact load but nonlinear with both contact duration and particle size in the form of a power law. The exponent of the power law for size dependence is around the value predicted by general sintering theory. The temperature dependence of the sintering force is also nonlinear and follows the Arrhenius equation. At temperatures closer to the melting point, a liquid bridge is observed upon the separation of the contacted ice particles. We also find that the ratio of ultimate tensile strength of ice to the axial stress concentration factor in tension is an important factor in determining the sintering force, and a value of nearly 1.1 MPa can best catch the sintering force of ice in different conditions. We find that the activation energy is around 41.4 KJ / mol, which is close to the previously reported data. Also, our results suggest that smaller particles are "stickier " than larger particles. Moreover, during the formation of the ice particles, cavitation and surface cracking is observed which can be one of the sources for the variations observed in the measured ice sintering force.& nbsp;(c) 2022 Author(s). All article content, except where otherwise noted, is licensed under a Creative Commons Attribution (CC BY) license (http://creativecommons.org/licenses/by/4.0/).

Author

Hassan Bahaloo

Luleå University of Technology

Tobias Eidevåg

Chalmers, Chemistry and Chemical Engineering, Chemical Technology

Per Gren

Luleå University of Technology

Johan Casselgren

Luleå University of Technology

Fredrik Forsberg

Luleå University of Technology

Per Abrahamsson

AFRY

Mikael Sjoedahl

Luleå University of Technology

Journal of Applied Physics

0021-8979 (ISSN) 1089-7550 (eISSN)

Vol. 131 2 025109

Subject Categories

Applied Mechanics

Meteorology and Atmospheric Sciences

Other Materials Engineering

DOI

10.1063/5.0073824

More information

Latest update

2/10/2022