Studies of the Finite Element Technique for Transonic Flows with Shocks PDF Download

Author: Aspi Rustom Wadia
Publisher:
ISBN:
Category : Finite element method
Languages : en
Pages : 120

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Author: Aspi Rustom Wadia
Publisher:
ISBN:
Category :
Languages : en
Pages :

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Author: T. J. Chung
Publisher:
ISBN:
Category :
Languages : en
Pages : 72

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This report examines the Galerkin finite element method for solving aerodynamics problems with emphasis on transonic flows. A shock element concept was proposed and computations were carried out. In this process, a quadratic isoparametric element is divided into quadrants with each quadrant having independent trial functions. This idea allows discontinuities at the center of an element and shocks are allowed to develop freely. Rankin-Hugoniot conditions are satisfied accurately. Although this method is efficient until freesteam Mach number reaches approximately 0.95, the solution seems to deteriorate significantly for M> 0.95. Toward the end of the reporting period, the author proposed a new approach--optimal control penalty finite elements. This method is suited ideally for problems of discontinuity and shock waves as a consequence of changes in the type of partial differential equations. The resulting equations are symmetric and positive-definite, their solution being type-idependent. Numerous examples indicate that both stability and accuracy are maintained very satisfactorily for Tricomi and small perturbation equations. Detailed calculations applied to the full potential equations using this approach are beyond the scope of the present study.

Author: T. F. Chen
Publisher:
ISBN:
Category :
Languages : en
Pages : 36

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Author: Arthur Rizzi
Publisher: Springer-Verlag
ISBN: 3663140083
Category : Science
Languages : de
Pages : 283

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Author: Akin Ecer
Publisher:
ISBN:
Category : Aerodynamics, Transonic
Languages : en
Pages : 116

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The finite element method is applied for the solution of transonic potential flows through a cascade of airfoils. Convergence characteristics of the solution scheme are discussed. Accuracy of the numerical solutions is investigated for various flow regions in the transonic flow configuration. The design of an efficient finite element computational grid is discussed for improving accuracy and convergence.

Author: United States. National Aeronautics and Space Administration. Scientific and Technical Information Office
Publisher:
ISBN:
Category : Aerodynamics, Transonic
Languages : en
Pages : 132

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Author: Aspi Rustom Wadia
Publisher:
ISBN:
Category :
Languages : en
Pages : 12

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The governing differential equation for the one-dimensional, transonic flow in a laval nozzle in the vicinity of the throat was obtained in the non-dimensional form. A least square finite element technique was used with a linearly interpolating polynomial to reduce the governing equation to a system of non-linear algebraic equations which were solved numerically by Newton's method. The system of partial differential equations for the two dimensional flow in a laval nozzle was also obtained in the non-dimensional form. The method of integral relations was used to replace the original system of partial differential equations by a system of ordinary differential equations. Using the least square finite element technique a computer program was developed for the construction and solution of the non-linear equations for the laval nozzle problem. The results including the location of the shock in the flow are presented. (Author).

Author: T. F. Chen
Publisher:
ISBN:
Category :
Languages : en
Pages : 36

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Author: H. C. Chen
Publisher:
ISBN:
Category :
Languages : en
Pages : 112

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A finite element program is described for computing steady and unsteady (oscillatory and transient) transonic flows over thin airfoils by solving directly the unsteady, nonlinear transonic potential equation based on small disturbance theory. The present numerical algorithm is developed using the concept of finite elements in conjunction with the least squares method of weighted residuals applied to both space and time. The basic element presently used is a product of an element in space and an element in time. The former has a cubic expansion inside each element, while the latter is a quadratic Lagrangian element. For each time step, the finite element discretization in both space and time results in a recurrence relationship in the form of a banded system of algebraic equations, which is solved by Gaussian elimination. The embedded shocks are smeared and a matching scheme for computing effectively flow over lifting airfoils is also incorporated in the program. The present computer program is composed of two parts: the first part (designated as UTRANL-I) generates, from a limited number of input cards, the necessary mesh information and, if desired, produces a CALCOMP mesh plot; the second part (UTRANL-II) carries out the analysis and displays the pressure coefficients along the chordline on printer plots. Two sample cases of flow over a NACA 64A 410 and a NACA 64A 006 airfoils are given to demonstrate the applicability and usage of the program. Te solution procedures are found to be quite efficient and accurate, permitting the aerodynamic forces to be calculated to engineering accuracy in less than ten minutes CPU time on a CDC 6600 computer for the most time consuming case among all those studied. (Author).