Abstract
The fully automated generation of computational meshes for twin-screw machine geometries constitutes a mandatory aspect for the numerical simulation (and shape-optimization) of these devices but proves to be a challenging task in practice. Therefore, the successful generation of computational meshes requires sophisticated mathematical tools. Commercially available classical mesh generators can produce high quality meshes from no more than a description of the rotor contours. However, since we are particularly interested in numerical simulations using the principles of Isogeometric Analysis, a spline-based geometry description rather than a classical mesh is needed.In this paper, we propose a practical approach for the automated generation of spline-based twin-screw machine geometry parameterizations in two dimensions. For this purpose, we adopt the principles of Elliptic Grid Generation and present a parameterization algorithm that is compatible with an automated simulation pipeline based on the principles of isogeometric analysis.To demonstrate the proposed techniques, we apply them to an example geometry and present the resulting parameterizations. Finally, we give a qualitative explanation of how the discussed techniques can be utilized to generate geometry parameterizations in three dimensions and their applications to shape-optimization on a variable rotor-pitch.
Highlights
The generation of analysis-suitable meshes for twin-screw geometries constitutes the first step towards the numerical simulation and shape-optimization of twin-screw machines
Since we are interested in numerical simulations using the principles of Isogeometric Analysis, a spline-based geometry description rather than a classical mesh is needed
We are interested in using Isogeometric Analysis (IgA) [4] techniques to perform shape-optimization on twin-screw machine geometries with variable rotor pitch
Summary
The generation of analysis-suitable meshes for twin-screw geometries constitutes the first step towards the numerical simulation and shape-optimization of twin-screw machines. Contour Approximation and Choice of Basis Given four input point clouds corresponding to each boundary of Ω: Pα = {piα}Ii=α1 with α ∈ {s, e, n, w}, the selection of a suitable spline basis Σ and the corresponding boundary control points di (see section 2) constitutes a preliminary step before (17) is tackled computationally For this purpose we select a coarse initial basis Σ (resulting from two coarse univariate knotvectors) and four sets of monotone increasing parametric values {ξαi }Ii=α1, each starting on ξα1 = 0 and ending on ξαIα = 1. To generate the O-parameterizations from (i), we first generate exact (chord-length parameterized) cubic spline-fits through the input point clouds of the rotors and casings, using one of the FITPACK [12] routines We evaluate both spline fits in N uniformly-spaced points over the parametric interval [0, 1] and utilize the resulting point clouds to build male and female reparameterization functions ηm and ηf , respectively (see section 6). To achieve boundary conformity between separator and C-grids, we employ the same knot-vector(s) in the ξ-direction
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