Mechanism of the intermittent motion of two-phase debris flows

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• 作者：Liqun Lyu ; Zhaoyin Wang ; P. Cui
• 关键词：Two ; phase debris flow ; Intermittent motion ; Unsteady flow ; Flow power ; Energy dissipation
• 刊名：Environmental Fluid Mechanics
• 出版年：2017
• 出版时间：February 2017
• 年：2017
• 卷：17
• 期：1
• 页码：139-158
• 全文大小：4838KB
• 刊物类别：Earth and Environmental Science
• 刊物主题：Earth Sciences, general; Environmental Physics; Hydrology/Water Resources; Classical Mechanics; Hydrogeology; Oceanography;
• 出版者：Springer Netherlands
• ISSN：1573-1510
• 卷排序：17

文摘

A typical two-phase debris flow exhibits a high and steep flow head consisting of rolling boulders and cobbles with intermittent or fluctuating velocity. The relative motion between the solid phase and the liquid phase is obvious. The motion of a two-phase debris flow depends not only on the rheological properties of the flow, but also on the energy transmission between the solid and liquid phases. Several models have been developed to study two-phase debris flows. An essential shortcoming of most of these models is the omission of the interaction between the two phases and identification of the different roles of the different materials in two-phase debris flows. The tracer particles were used for the velocity of solid phase and the velocity of liquid phase was calculated by the water velocity on the surface of the debris flow in the experiments. This paper analyzed the intermittent feature of two-phase debris flows based on videos of debris flows in the field and flume experiments. The experiments showed that the height of the head of the two-phase debris flow increased gradually in the initiation stage and reached equilibrium at a certain distance from the start of the debris flow. The height growth and the velocity of the flow head showed fluctuating characteristics. Model equations were established and the analyses proved that the average velocity of the two-phase debris flow head was proportional to the flood discharge and inversely proportional to the volume of the debris flow head.