Simulation of Ice-Structure Interactions Using a Coupled SPH-DEM Method

Day 1 Mon, November 05, 2018 Pub Date : 2018-11-01 DOI:10.4043/29139-MS

S. Mintu, D. Molyneux

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引用次数: 5

Abstract

Ice-structure interaction (ISI) is a complex process, which requires a thorough understanding of the underlying physics to ensure safe operations in the ice-covered regions. Application of discrete element method (DEM) to compute ice loads on structures is a widely accepted approach, where the equations of rigid body motions are solved for all ice pieces in the computational domain. In most ISI simulations, the ice zone is assumed to be resting on a static water foundation omitting the hydrodynamic effects (added mass, water drag, wave damping) of the interacting bodies. This assumption can introduce erroneous results to simulations of the floating ice floes behavior, which in turn will incur uncertainties in planning ice management activities. In this paper, a smooth particle hydrodynamics (SPH) based computational fluid dynamics (CFD) code is coupled with a three-dimensional DEM model to take the hydrodynamic effects of the interacting bodies including the ice pieces into account. The ice zone is modeled as discrete elements, which allows computing interaction forces by considering contact laws. The water foundation is modeled using smooth particles, which are modelled with the Naiver-Stokes equations. Several applications of ship and offshore structures interacting with level ice and pack ice are simulated. A scenario of an offshore supply vessel operating in the marginal ice zone (MIZ) that is subject to wave forces is also simulated to show how this approach can be used for modelling complex real-world problems. This scenario is unique in a sense that it yields a multi-physics solution, where ice-structure-wave are all included in a single CFD simulation as a fully coupled analysis. The cost of the simulation is significantly reduced by running the computations on a Graphics Processing Unit (GPU) instead of a typical CPU workstation. Some of the initial results of ice-structure interactions are presented in this paper and a reasonable agreement with reduced scale model test results are found.

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用SPH-DEM耦合方法模拟冰-结构相互作用

冰-结构相互作用(ISI)是一个复杂的过程，需要对潜在的物理原理有透彻的了解，以确保在冰雪覆盖地区的安全操作。应用离散元法(DEM)计算结构冰荷载是一种被广泛接受的方法，该方法在计算域中求解所有冰块的刚体运动方程。在大多数ISI模拟中，假定冰区位于静态水基础上，忽略了相互作用体的水动力效应(附加质量、水阻力、波浪阻尼)。这种假设可能会给浮冰行为的模拟带来错误的结果，从而给规划冰管理活动带来不确定性。本文将基于光滑粒子流体力学(SPH)的计算流体力学(CFD)代码与三维DEM模型相结合，考虑了包括冰块在内的相互作用体的水动力效应。冰区建模为离散单元，可以通过考虑接触律来计算相互作用力。水的基础是用光滑的颗粒，这是naver - stokes方程建模。模拟了船舶和近海结构与水平冰和浮冰相互作用的几种应用。本文还模拟了一艘近海补给船在受波浪力影响的边缘冰区(MIZ)作业的情景，以展示如何将这种方法用于模拟复杂的现实问题。这种情况的独特之处在于，它产生了多物理场解决方案，其中冰结构波作为完全耦合的分析都包含在单个CFD模拟中。通过在图形处理单元(GPU)而不是典型的CPU工作站上运行计算，可以显著降低模拟的成本。本文给出了一些冰-结构相互作用的初步结果，并与缩比模型试验结果有较好的一致性。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Day 1 Mon, November 05, 2018

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