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Дата изменения: Wed Jul 10 21:28:28 2002
Дата индексирования: Mon Oct 1 21:30:55 2012
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Abstract

Abstract

 

Mathematical Treatment of Exhaus Systems with Acoustic Properties Using Mathlie II. Application

J.Volkmann, R.Schmid, G.Baumann (Department of Mathematical Physics, University of Ulm, Ulm , Germany)

e-mail: volk@physik.uni-ulm.de

The second part of our presentation contains the application of results from the first part to differential equations coming out from the consideration of reacting gas systems. From a physical point of view exhaust systems combine  aspects of hydrodynamical or fluiddynamical properties, thermal properties resulting mainly from chemical reactions and the acoustic properties of the pipe system. The designing goals for an exhaust system are determined by optimizing the space, cleaning the exhaust gas and minimizing the noise. To simulate an  exhaust system under the restriction of low sound and pollutation output we need an  efficient mathematical model and efficient  mathematical solution procedures. The basic  equations describing the physical properties  of an exhaust system are the gasdynamics  equations. By using modern group analysis in  connection with computer algebra we can apply tools to solve the basic equations analytically. Using the variaty of the friction as an arbitrary function as well as the heat flux we will demonstrate how the algebra and the solution of the equations depends on these terms. In addition we examine the influence of  the gas model (ideal or real gas) on the algebra and solutions of the equations. The  calculations carried out in our examination are supported by the computer algebra package MathLie [G. Baumann, Symmetry Analysis of  Differential Equations using Mathematica,  TELOS/Springer (1998)] and agebraic extensions.

 

Section : 12