Abstract
Two dimensional equations of steady motion for third order fluids are expressed in a special coordinate system generated by the potential flow corresponding to an inviscid fluid. For the inviscid flow around an arbitrary object, the streamlines are the phicoordinates and velocity potential lines are psi-coordinates which form an orthogonal curvilinear set of coordinates. The outcome, boundary layer equations, is then shown to be independent of the body shape immersed into the flow. As a first approximation, assumption that second grade terms are negligible compared to viscous and third grade terms. Second grade terms spoil scaling transformation which is only transformation leading to similarity solutions for third grade fluid. By using Lie group methods, infinitesimal generators of boundary layer equations are calculated. The equations are transformed into an ordinary differential system. Numerical solutions of outcoming nonlinear differential equations are found by using combination of a Runge-Kutta algorithm and shooting technique.
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Communicted by ZHOU Zhe-wei
Biography: Muhammet Yürüsoy (Tel: +90-272-228 11 311(217); E-mail; yurusoy@aku.edu.zr)
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Yürüsoy, M. Similarity solutions of boundary layer equations for a special non-Newtonian fluid in a special coordinate systme. Appl Math Mech 25, 587–594 (2004). https://doi.org/10.1007/BF02437607
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DOI: https://doi.org/10.1007/BF02437607