输运方程谱间断流线扩散耦合方法

本文讨论了谱有限元方法,构造了求解Ｂｏｌｔｚｍ ａｎｎ 方程球谐函数谱展开和间断流线扩散有限元耦合格式．建立了这种耦合方法的稳定性及最优阶收敛性误差估计．得到了比标准有限元更高的精度．     

Modeling rotational effects in eddy-viscosity closures

A new approach to sensitize turbulence closures based on the linear eddy-viscosity hypothesis to rotational effects is proposed. The principal idea is to ‘mimic' the behavior of a second moment closure (SMC) in rotating homogeneous shear flow; depending on the ratio of the mean flow to the imposed rotational time scales, the model should be able to bifurcate between two stable equilibrium solutions. These solutions correspond to exponential or algebraic time dependent growth or decay of turbulent kinetic energy. This fundamental behavior of SMCs is believed to be of importance also in the prediction of non-equilibrium turbulence. A near-wall turbulence model which is based on the linear eddy-viscosity hypothesis is modified in the present study. Wall proximity effects are modeled by the elliptic relaxation approach. This closure has been successfully applied in the computation of complex, non-equilibrium flows in inertial frames of reference. The objective of the present study is to extend the predictive capability of the model to include flows dominated by rotational effects. The new model is calibrated in rotating homogeneous turbulent shear flow and subsequently tested in three different cases characterized by profound effects of system rotation or streamline curvature. It is able to capture many of the effects due to imposed body forces that the original closure is incapable of. Good agreement is obtained between the present predictions and available experimental and DNS data.     

Conservative monotone streamline upwind formulation using simplex elements

A streamline upwind formulation is presented for the treatment of the advection terms in the general transport equation. The formulation is monotone and conservative and is based on the discontinuous nature of the advection mechanism. The results of there benchmark test cases for the full range of flow Peclet numbers are presented. The new formulation is shown to accurately model the advection phenomenon with significantly smaller numerical diffusion than the existing methods. The results are also free of all spatial oscillations. Considerable savings in computer storage and execution time have been achieved by employing the three-noded triangular element for which exact integrations exist. The formulation is straightforward and can be readily incorporated into any finite element code using the conventional Galerkin approach.     

线性对流扩散问题的差分流线扩散法

本文讨论发展型对流扩散方程的差分流线扩散（ＦＤＳＤ）格式,给出了该方法的稳定性和误差估计,并证明了该ＦＤＳＤ格式按Ｌ∞（Ｌ２（Ω））模具有拟最优阶精度     

Gradients at a curved shock in reacting flow

The inviscid equations of motion for the flow at the downstream side of a curved shock are solved for the shock–normal derivatives. Combining them with the shock–parallel derivatives yields gradients and substantial derivatives. In general these consist of two terms, one proportional to the rate of removal of specific enthalpy by the reaction, and one proportional to the shock curvature. Results about the streamline curvature show that, for sufficiently fast exothermic reaction, no Crocco point exists. This leads to a stability argument for sinusoidally perturbed normal shocks that relates to the formation of the structure of a detonation wave. Application to the deflection–pressure map of a streamline emerging from a triple shock point leads to the conclusion that, for non–reacting flow, the curvature of the Mach stem and reflected shock must be zero at the triple point, if the incident shock is straight. The direction and magnitude of the gradient at the shock of any flow quantity may be written down using the results. The sonic line slope in reacting flow serves as an example. Extension of the results – derived in the first place for plane flow – to three dimensions is straightforward. Received 12 February 1997 / Accepted 10 June 1997     

Isolating curvature effects in computing wall-bounded turbulent flows

An adjoint optimization method is utilized to design an inviscid outer wall shape required for a turbulent flow field solution of the So–Mellor convex curved wall experiment using the Navier–Stokes equations. The associated cost function is the desired pressure distribution on the inner wall. Using this optimized wall shape with a Navier–Stokes method, the abilities of various turbulence models to simulate the effects of curvature without the complicating factor of streamwise pressure gradient are evaluated. The one-equation Spalart–Allmaras (SA) turbulence model overpredicts eddy viscosity, and its boundary layer profiles are too full. A curvature-corrected version of this model improves results, which are sensitive to the choice of a particular constant. An explicit algebraic stress model does a reasonable job predicting this flow field. However, results can be slightly improved by modifying the assumption on anisotropy equilibrium in the model's derivation. The resulting curvature-corrected explicit algebraic stress model (EASM) possesses no heuristic functions or additional constants. It slightly lowers the computed skin friction coefficient and the turbulent stress levels for this case, in better agreement with experiment. The effect on computed velocity profiles is minimal.     

A Comparative Study of Least-squares,SUPG and Galerkin Methods for Convection Problems

Least-squares, SUPG and Galerkin methods are compared for a model convection problem in the context of smooth and discontinuous solutions. Our experiments focus on the impact of boundary condition implementation and grid orientation upon these methods, as well as their relative performance for both types of solutions.     

一类非线性对流扩散问题的FDSD预测校正格式

1．引言由Hughes和Brooks门提出,并经Johnson等人［‘－‘1发展的流线扩散法（Streamline－DiffusionMetho人以下简称SD方法）是求解对流占优扩散问题（包括纯双曲问题）的一种有效的数值方法．由于良好的数值稳定性及其高阶收敛率,SD方法已广泛地应用于计算流体等诸多科学工程计算．然而,传统的sD方法利用时一空有限元求解发展型问题,导致对高维问题工作量过于庞大;其编程实现较复杂,对非线性问题也不便进行线性化处理．为使SD方法能够较简便地应用于高维和非线性问题,孙撒问提出了仅对空间域作有限元离散,而对时间域作差分…     

一阶双曲问题的间断流线扩散法

1．引言众所周知，求解一阶双曲问题的Galerkin有限元法，仅具有次最优LZ一收敛阶估计，难于建立H＼误差估计【‘1，且Gderkill有限元解常呈现伪数值振荡．为改善计算精度与稳定性，诸多非标准有限元解法相继提出，其中，间断（Discontinuous）Galerkin有限元法（以下简称DG方法）与流线扩散（StreamlineDiffusion）有限元法（以下简称SD法）是两种具有鲜明特点，较为成功的算法．具体地，DG方法是一种迎风型显式算法，它从入流边界开始，沿流场方向，自上游往下游，逐个单元进行解算，计算十分简便且可局部并行化．SD方法则是一种P…     

非线性对流扩散问题的差分-流线扩散法

1．引言流线扩散法（简称SD方法）是由Huzhes和Brooks在1980年前后提出的一种数值求解对流占优扩散问题的新型有限元算法．随后，Johnson和N8vert将SD方法推广到发展型对流扩散问题（［1］，［2］，［3］）．熟知，对于对流扩散问题，标准有限元法虽具有高阶精度，但常产生数值振荡；古典人工粘性Galerkin法更具有较好的稳定性，但仅具有一阶精度．而（SD方法兼具良好的数值稳定性和高阶精度，因此得到了越来越多的重视，对于发展型对流扩散问题，传统的SD方法均采用时空有限元．这样做，虽然可使时间和空间方向上的精度很好的协调起…