A novel multi-resolution technique called border mapping multi-resolution (BMMR) is proposed for projection-based particle methods. The BMMR aims to obtain background equivalent particle distributions in the two sides...
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A novel multi-resolution technique called border mapping multi-resolution (BMMR) is proposed for projection-based particle methods. The BMMR aims to obtain background equivalent particle distributions in the two sides of a border between subdomains with a 2:1 resolution ratio so that a single resolution framework is adopted to near-border particles calculations. The novelty of the BMMR is that it obtains the background grid from the mapping of the actual particle distribution in the border and, as a result, the location of the particles in the background grid exactly matches the location of the actual particles. In this way, such technique aims to reduce the error from the interpolation of the physical quantities in the background grid and to avoid sudden changes in the particle distribution that may lead to unstable local pressure calculation. In the coarse side of the border, the refinement is made by a triangulation and by placing fictitious particles in the midpoints of the triangles. In the fine side of the border, the derefinement is made by defining a set of fine particles that result in a particle distribution that best resembles a coarse one. The accuracy and computational performance of the BMMR implemented in a moving particle semi-implicit (MPS) simulation system are verified by using benchmark test cases of 2D free surface flows. (c) 2022 Elsevier B.V. All rights reserved.
The two-layer sloshing of water and diesel oil is studied numerically by using the consistent particlemethod (CPM). CPM is a projection-based particle method with the distinct feature of having consistency and high-o...
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The two-layer sloshing of water and diesel oil is studied numerically by using the consistent particlemethod (CPM). CPM is a projection-based particle method with the distinct feature of having consistency and high-order accuracy in computing spatial derivatives. A validation against published experimental data is conducted. Then, the two-layer sloshing under swayonly and coupled sway-heave excitations is studied. For the coupled excitation cases, it is found that the sum/difference of sway and heave frequencies being close to the odd multiple of the system's natural frequency induces secondary violent sloshing even when both excitations are further away from the natural frequency.
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