Classes and Properties of Exact Solutions to the ThreeDimensional Incompressible Navier-Stokes Equations
The Navier-Stokes equations together with the continuity equation are one of the long standing problems in mathematical physics. They form a system of nonlinear partial differential equations that describe the fluid flow phenomena, whether laminar or turbulent. The nonlinearity of the equations i...
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Format: | Thesis |
Language: | English |
Published: |
2010
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Online Access: | http://utpedia.utp.edu.my/8022/1/2010%20PhD-Classes%20And%20Properties%20Of%20Exact%20Solutions%20To%20Three-Dimensional%20Incompressible%20Navier-Sto.pdf http://utpedia.utp.edu.my/8022/ |
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Institution: | Universiti Teknologi Petronas |
Language: | English |
Summary: | The Navier-Stokes equations together with the continuity equation are one of the long
standing problems in mathematical physics. They form a system of nonlinear partial
differential equations that describe the fluid flow phenomena, whether laminar or
turbulent. The nonlinearity of the equations is obscure which defies all conventional
methods of analytical solution to the differential equations. The analytical methods
are found to be very important to model physical phenomena. They form basic
understanding of the phenomena at different circumstances, at least qualitatively. In
addition to their physics, the analytical methods are also useful to find and extend the
class of existence, uniqueness and regularity in the pure mathematics sense.
This thesis introduces new analytical methods of finding solutions of the
incompressible Navier-Stokes equations. The work is based on the criteria of wellposed
problem which is then solved by the proposed special classes of the solution
either qualitatively or quantitatively.
Firstly, general qualitative properties of solutions to the three-dimensional
incompressible flows are presented. The method rs performed from the
implementation of vector analysis into the energy equation with the consideration of
zero rate energy. Trivial solution is obtained from any initial-boundary value
problems. For the cases of non trivial solution, the analyticity of the solutions is
assumed to investigate the triviality at intersection regions. Some physical
consequences due to violation of the trivial solutions are also performed with the
application of the vorticity equations, which are related to the onset of turbulence.
Therefore, non trivial solutions will also represent turbulence whether they have
singularity or not.
This hypothesis is supplemented by investigation on the solution in the special
classes of v = v x <I> and v = V<I> + V x <I> of the three-dimensional incompressible
Navier-Stokes equations. Analysis is taken using the vorticity equations rather than
the original Navier Stokes equations based on qualitative mathematical work. Results show that the corresponding problem admits a unique and regular solution because the
original problems can be transformed to class of linear parabolic and elliptic
equations.
The first analytical solution is then produced using the four components coordinate
transformation .; = kx + ly + mz- ct. While, the second solution is produced using the
three components coordinate transformation .; = ly + mz- ct . Velocity vector in the
solutions is based on the relation v =Vet>+ v x ct> where <t> is a potential function that is
defined as <l>=P(x,~)R(~). The potential function is firstly substituted into the
continuity equation. The solution for R is produced using a certain mathematical
condition and the resultant expression is used sequentially in the Navier-Stokes
equations to reduce the problem to the class of nonlinear ordinary differential
equations in P terms. Here, more general solutions are also obtained based on the
particular solutions of P . The two solutions are based on a zero and constant pressure
gradients which are given to illustrate the applicability of the method.
The third analytical solution utilises a potential function m the form
ct> = P(x,y,q)R(y)s(.;) with the application of the transformed coordinate ~ = kz- dt).
In this solution, the pressure term is presented in a general functional form. The
solutions for R and S are obtained by imposing a certain mathematical condition.
General solutions are then obtained based on the particular solutions of P where the
equation is reduced to the form of linear differential equation. A method for finding
closed-form solutions for general linear differential equations is proposed and
uniqueness of the solution is proved and regularised.
The fourth analytical solution is derived using the vorticity equation. The solution
is produced by implementing a potential function in the form ct> = P(x,y,,;)R(y)s(.;)
with the application of the transformed coordinate ~ = kz- c; (t) . The pressure is then
solved by applying the velocity vector into the Navier-Stokes equations to complete
the solutions. Two examples are given to illustrate the applicability of the theorem.
The uniqueness of the solution is also proved.
Validation against two laminar flow experiments and three different turbulent flow
cases including numerical case are carried out and reported in this work. The flow
cases used in the validation are laminar jet flow, turbulent jet flow, boundary layer
flow, turbulent channel flow and combustion. Generally, the solution is able to follow the trends in the corresponding cases. Although the analytical solution is derived for
non-reacting flows, it proved capable of reproducing trends of cases including
combustion.
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