9 research outputs found
Development of a Moving and Stationary Mixed Particle Method for Solving the Incompressible Navier-Stokes Equations at High Reynolds Numbers
No full textDevelopment of an upwinding particle interaction kernel for simulating incompressible Navier-Stokes equations
No full textDevelopment of a Particle Interaction Kernel Function in MPS Method for Simulating Incompressible Free Surface Flow
No full textDevelopment of a Particle Interaction Kernel for Convection-Diffusion Scalar Transport Equation
No full text
Development of an upwinding particle interaction kernel for simulating incompressible Navier-Stokes equations
No full text
Development of a Particle Interaction Kernel for Convection-Diffusion Scalar Transport Equation
No full textDevelopment of a Particle Interaction Kernel Function in MPS Method for Simulating Incompressible Free Surface Flow
Full text linkWe aimed to derive a kernel function that accounts for the interaction among moving particles within the framework of particle method. To predict a computationally more accurate moving particle solution for the Navier-Stokes equations, kernel function is a key to success in the development of interaction model. Since the smoothed quantity of a scalar or a vector at a spatial location is mathematically identical to its collocated value provided that the kernel function is chosen to be the Dirac delta function, our guideline is to derive the kernel function that is closer to the delta function as much as possible. The proposed particle interaction model using the newly developed kernel function will be validated through the two investigated Navier-Stokes problems which have either the semianalytical or the benchmark solutions
