A novel coupled NS‐PFEM with stable nodal integration and polynomial pressure projection for geotechnical problems

Wang, Zeyu; Jin, Yin‐Fu; Yin, Zhen‐Yu; Wang, Yuze

doi:10.1002/nag.3417

Cited by 15 publications

(13 citation statements)

References 86 publications

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“…A similar conclusion has emerged from dynamic analysis for elastic or elastoplastic materials (i.e., soft soil), where the smoother stress, pressure, and equivalent plastic strain fields have been obtained by the SNS-PFEM. 19,33 Such a spatial instability did not influence the calculation of the static problem by the implicit NS-PFEM but affected the dynamic analysis by the explicit NS-PFEM. 23 Figure 15 suggests that the conclusions from the solid mechanics are applicable in the incompressible flow analysis as well.…”

Section: Water Jet Impingingmentioning

confidence: 98%

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A novel stabilized nodal integration formulation using particle finite element method for incompressible flow analysis

Yu,

Jin,

Yin

et al. 2024

Numerical Methods in Fluids

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In simulations using the particle finite element method (PFEM) with node‐based strain smoothing technique (NS‐PFEM) to simulate the incompressible flow, spatial and temporal instabilities have been identified as crucial problems. Accordingly, this study presents a stabilized NS‐PFEM‐FIC formulation to simulate an incompressible fluid with free‐surface flow. In the proposed approach, (1) stabilization is achieved by implementing the gradient strain field in place of the constant strain field over the smoothing domains, handling spatial and temporal instabilities in direct nodal integration; (2) the finite increment calculus (FIC) stabilization terms are added using nodal integration, and a three‐step fractional step method is adopted to update pressures and velocities; and (3) a novel slip boundary with the predictor–corrector algorithm is developed to deal with the interaction between the free‐surface flow with rigid walls, avoiding the pressure concentration induced by standard no‐slip condition. The proposed stabilized NS‐PFEM‐FIC is validated via several classical numerical cases (hydrostatic test, water jet impinging, water dam break, and water dam break on a rigid obstacle). Comparisons of all simulations to the experimental results and other numerical solutions reveal good agreement, demonstrating the strong ability of the proposed stabilized NS‐PFEM‐FIC to solve incompressible free‐surface flow with high accuracy and promising application prospects.

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Section: Water Jet Impingingmentioning

confidence: 98%

“…[28][29][30][31][32] The SNS-PFEM was then proposed by introducing the stabilized nodal integration into the framework of NS-PFEM for simulating geotechnical problems with large deformation. 19,33,34 Nevertheless, this algorithm has not been applied in fluid analysis.…”

Section: Introductionmentioning

confidence: 99%

A novel stabilized nodal integration formulation using particle finite element method for incompressible flow analysis

Yu,

Jin,

Yin

et al. 2024

Numerical Methods in Fluids

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“…For geotechnical engineering, numerous applications involve multiscale and multiphysics processes, such as internal erosion, hydraulic fracturing, energy piles, municipal waste disposal, production from unconventional oil and gas reservoirs, heat stimulation and depressurization of natural gas hydrate formation, pavement subjected to heating-cooling cycles, contaminant transport, and CO 2 sequestration (Sun et al, 2018;Li et al, 2020;Shao et al, 2020;Yang et al, 2020Yang et al, , 2022Liu et al, 2021;Qian et al, 2021;Jin and Yin, 2022;Wang et al, 2022b). In the literature, the terminology "multiphysics" always implies two or more physical fields in the so-called thermo-hydro-mechanicalchemical-bio-electrical coupling.…”

Section: Introductionmentioning

confidence: 99%

Multiscale multiphysics modeling in geotechnical engineering

Yin

Zhang

Laouafa

2023

J. Zhejiang Univ. Sci. A

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“…In comparison to PFEM, the main advantages of SPFEM include: (1) field variable mapping in PFEM is completely avoided; (2) free of volumetric locking; (3) higher computational efficiency due to low-order elements and fewer integration points; (4) more adaptive to mesh distortion. The SPFEM has so far been applied to the quasi-static problems in solid mechanics, 14 dynamic problems in geomechanics, 15,17 fluid dynamic problems, 18 fluid-solid interaction problems, 19,20 saturated porous media problems, [21][22][23] and multiscale coupled SPFEM/DEM modeling. 24 These studies have shown that SPFEM can provide promising results in solving large deformation problems.…”

Section: Introductionmentioning

confidence: 99%

Circumventing volumetric locking in stabilized smoothed particle finite element method and its application to dynamic large deformation problems

Liu,

Huang,

Gou

et al. 2023

Num Anal Meth Geomechanics

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The smoothed particle finite element method (SPFEM) is an effective framework for large deformation analysis. The original SPFEM possesses the rank deficiency issue due to the direct nodal integration technique, which can be overcome by incorporating the strain gradient stabilization method. However, an extra volumetric locking due to the strain gradient stabilization term has been found. In this study, we propose a simple and efficient approach, the B‐dev approach, which only considers the deviatoric part of the smoothed strain gradient for stabilization to overcome the volumetric locking issue. First, the correctness of the stabilized SPFEM method is verified by an elastic cantilever beam vibration problem without considering incompressibility. Then, through the example of the strip footing penetration problem, the volumetric locking in the stabilized SPFEM is demonstrated and the capability of the proposed B‐dev approach in terms of overcoming the volumetric locking is verified. Furthermore, the stabilized SPFEM with B‐dev approach is applied to two types of elastoplastic problems in geotechnical engineering. All numerical results illustrate that the proposed approach can improve the performance of the stabilized SPFEM in dealing with incompressible and large deformation problems in geomechanics.

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A novel coupled NS‐PFEM with stable nodal integration and polynomial pressure projection for geotechnical problems

Cited by 15 publications

References 86 publications

A novel stabilized nodal integration formulation using particle finite element method for incompressible flow analysis

A novel stabilized nodal integration formulation using particle finite element method for incompressible flow analysis

Multiscale multiphysics modeling in geotechnical engineering

Circumventing volumetric locking in stabilized smoothed particle finite element method and its application to dynamic large deformation problems

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