A CFD code is used to solve a two-dimensional ( x and y ), incompressible, laminar flow without free surfaces. The fluid is Newtonian. Appropriate boundary conditions e used. List the variables (unknowns) in the problem, and list the corresponding equations to be solved by the computer.

Question

Want to see more full solutions like this?

Answer 1

Textbook Question

Chapter 15, Problem 1CP

A CFD code is used to solve a two-dimensional (x and y), incompressible, laminar flow without free surfaces. The fluid is Newtonian. Appropriate boundary conditions e used. List the variables (unknowns) in the problem, and list the corresponding equations to be solved by the computer.

Expert Solution & Answer

To determine

The list of variables and corresponding equation used to solve on the computer.

Explanation of Solution

According to the data given in question for an incompressible Newtonian laminar flow fluid with no free surface. The unknown quantity present in the Stokes flow equation are u, v and P.

The corresponding equation for the given flow condition is continuity of Navier-Stokes equation. The other equation is: -

X- component of Navier-Stokes equation
Y-component of Navier-Stokes equation

Navier-Stokes equation in Cartesian co-ordinate system is given as:

x-component:

ρ(∂u∂t + u∂u∂x + v∂u∂y + w∂u∂z) = −∂P′∂x + μ∇2u

y-component of Navier-Stokes equation:

ρ(∂v∂t + u∂v∂x + v∂v∂y + w∂v∂z) = −∂P′∂y + μ∇2v

z-component:

ρ(∂w∂t + u∂w∂x + v∂w∂y + w∂w∂z) = −∂P′∂z + μ∇2w

Now,

During, non-dimensionalization a modified pressure is introduced. This helps in absorbing the hydrostatic pressure. It is defined as:

P′ = P + ρgz

Here,

P is pressure,

P′ is modified pressure

Z is the vertical direction vector

ρ is the density of fluid

When these equations are combined with appropriate boundary condition the problem can be solved.

Want to see more full solutions like this?

Subscribe now to access step-by-step solutions to millions of textbook problems written by subject matter experts!

Students have asked these similar questions

Solving fluid dynamic problem, flow through a cylinder, a uniform gradient only applied in z direction, If r is the radial polar co-ordinate, derive the velocity v_z(r) for steady flow at low Reynolds number. The result is about pressure gradient divide by 4 times viscosity and multiply by the difference of square of two distances. Do I need to convert distance into to radial polar co-ordinate in the result? How to consider this result in cylindrical coordinate?

A 1:7 scale model simulates the operation of alarge turbine that is to generate 200 kW with a flowrate of 1.5 m3/s.What flow rate should be used inthe model, and what power output is expected?(a) Water at the same temperature is used in bothmodel and prototype.(b) The model water is at 25°C and the prototypewater is at 10°C.

A water pump increases the pressure of the water passing through it. The flow is assumed to be incompressible. For each of the three cases listed below, how does average water speed change across the pump? In particular, is Vout less than, equal to, or greater than Vin? Show your equations, and explain. (a) Outlet diameter is less than inlet diameter (Dout < Din) (b) Outlet and inlet diameters are equal (Dout = Din) (c) Outlet diameter is greater than inlet diameter (Dout > Din)

Answer 2

Textbook Question

Chapter 15, Problem 1CP

A CFD code is used to solve a two-dimensional (x and y), incompressible, laminar flow without free surfaces. The fluid is Newtonian. Appropriate boundary conditions e used. List the variables (unknowns) in the problem, and list the corresponding equations to be solved by the computer.

Expert Solution & Answer

To determine

The list of variables and corresponding equation used to solve on the computer.

Explanation of Solution

According to the data given in question for an incompressible Newtonian laminar flow fluid with no free surface. The unknown quantity present in the Stokes flow equation are u, v and P.

The corresponding equation for the given flow condition is continuity of Navier-Stokes equation. The other equation is: -

X- component of Navier-Stokes equation
Y-component of Navier-Stokes equation

Navier-Stokes equation in Cartesian co-ordinate system is given as:

x-component:

ρ(∂u∂t + u∂u∂x + v∂u∂y + w∂u∂z) = −∂P′∂x + μ∇2u

y-component of Navier-Stokes equation:

ρ(∂v∂t + u∂v∂x + v∂v∂y + w∂v∂z) = −∂P′∂y + μ∇2v

z-component:

ρ(∂w∂t + u∂w∂x + v∂w∂y + w∂w∂z) = −∂P′∂z + μ∇2w

Now,

During, non-dimensionalization a modified pressure is introduced. This helps in absorbing the hydrostatic pressure. It is defined as:

P′ = P + ρgz

Here,

P is pressure,

P′ is modified pressure

Z is the vertical direction vector

ρ is the density of fluid

When these equations are combined with appropriate boundary condition the problem can be solved.

Want to see more full solutions like this?

Subscribe now to access step-by-step solutions to millions of textbook problems written by subject matter experts!

Answer 3

Textbook Question

Chapter 15, Problem 1CP

A CFD code is used to solve a two-dimensional (x and y), incompressible, laminar flow without free surfaces. The fluid is Newtonian. Appropriate boundary conditions e used. List the variables (unknowns) in the problem, and list the corresponding equations to be solved by the computer.

Expert Solution & Answer

To determine

The list of variables and corresponding equation used to solve on the computer.

Explanation of Solution

According to the data given in question for an incompressible Newtonian laminar flow fluid with no free surface. The unknown quantity present in the Stokes flow equation are u, v and P.

The corresponding equation for the given flow condition is continuity of Navier-Stokes equation. The other equation is: -

X- component of Navier-Stokes equation
Y-component of Navier-Stokes equation

Navier-Stokes equation in Cartesian co-ordinate system is given as:

x-component:

ρ(∂u∂t + u∂u∂x + v∂u∂y + w∂u∂z) = −∂P′∂x + μ∇2u

y-component of Navier-Stokes equation:

ρ(∂v∂t + u∂v∂x + v∂v∂y + w∂v∂z) = −∂P′∂y + μ∇2v

z-component:

ρ(∂w∂t + u∂w∂x + v∂w∂y + w∂w∂z) = −∂P′∂z + μ∇2w

Now,

During, non-dimensionalization a modified pressure is introduced. This helps in absorbing the hydrostatic pressure. It is defined as:

P′ = P + ρgz

Here,

P is pressure,

P′ is modified pressure

Z is the vertical direction vector

ρ is the density of fluid

When these equations are combined with appropriate boundary condition the problem can be solved.

Want to see more full solutions like this?

Subscribe now to access step-by-step solutions to millions of textbook problems written by subject matter experts!

Answer 4

Textbook Question

Chapter 15, Problem 1CP

A CFD code is used to solve a two-dimensional (x and y), incompressible, laminar flow without free surfaces. The fluid is Newtonian. Appropriate boundary conditions e used. List the variables (unknowns) in the problem, and list the corresponding equations to be solved by the computer.

Expert Solution & Answer

To determine

The list of variables and corresponding equation used to solve on the computer.

Explanation of Solution

According to the data given in question for an incompressible Newtonian laminar flow fluid with no free surface. The unknown quantity present in the Stokes flow equation are u, v and P.

The corresponding equation for the given flow condition is continuity of Navier-Stokes equation. The other equation is: -

X- component of Navier-Stokes equation
Y-component of Navier-Stokes equation

Navier-Stokes equation in Cartesian co-ordinate system is given as:

x-component:

ρ(∂u∂t + u∂u∂x + v∂u∂y + w∂u∂z) = −∂P′∂x + μ∇2u

y-component of Navier-Stokes equation:

ρ(∂v∂t + u∂v∂x + v∂v∂y + w∂v∂z) = −∂P′∂y + μ∇2v

z-component:

ρ(∂w∂t + u∂w∂x + v∂w∂y + w∂w∂z) = −∂P′∂z + μ∇2w

Now,

During, non-dimensionalization a modified pressure is introduced. This helps in absorbing the hydrostatic pressure. It is defined as:

P′ = P + ρgz

Here,

P is pressure,

P′ is modified pressure

Z is the vertical direction vector

ρ is the density of fluid

When these equations are combined with appropriate boundary condition the problem can be solved.

Want to see more full solutions like this?

Subscribe now to access step-by-step solutions to millions of textbook problems written by subject matter experts!

Answer 5

Textbook Question

Answer 6

Textbook Question

Answer 7

Expert Solution & Answer

To determine

The list of variables and corresponding equation used to solve on the computer.

Explanation of Solution

According to the data given in question for an incompressible Newtonian laminar flow fluid with no free surface. The unknown quantity present in the Stokes flow equation are u, v and P.

The corresponding equation for the given flow condition is continuity of Navier-Stokes equation. The other equation is: -

X- component of Navier-Stokes equation
Y-component of Navier-Stokes equation

Navier-Stokes equation in Cartesian co-ordinate system is given as:

x-component:

ρ(∂u∂t + u∂u∂x + v∂u∂y + w∂u∂z) = −∂P′∂x + μ∇2u

y-component of Navier-Stokes equation:

ρ(∂v∂t + u∂v∂x + v∂v∂y + w∂v∂z) = −∂P′∂y + μ∇2v

z-component:

ρ(∂w∂t + u∂w∂x + v∂w∂y + w∂w∂z) = −∂P′∂z + μ∇2w

Now,

During, non-dimensionalization a modified pressure is introduced. This helps in absorbing the hydrostatic pressure. It is defined as:

P′ = P + ρgz

Here,

P is pressure,

P′ is modified pressure

Z is the vertical direction vector

ρ is the density of fluid

When these equations are combined with appropriate boundary condition the problem can be solved.

Answer 8

Expert Solution & Answer

To determine

The list of variables and corresponding equation used to solve on the computer.

Explanation of Solution

According to the data given in question for an incompressible Newtonian laminar flow fluid with no free surface. The unknown quantity present in the Stokes flow equation are u, v and P.

The corresponding equation for the given flow condition is continuity of Navier-Stokes equation. The other equation is: -

X- component of Navier-Stokes equation
Y-component of Navier-Stokes equation

Navier-Stokes equation in Cartesian co-ordinate system is given as:

x-component:

ρ(∂u∂t + u∂u∂x + v∂u∂y + w∂u∂z) = −∂P′∂x + μ∇2u

y-component of Navier-Stokes equation:

ρ(∂v∂t + u∂v∂x + v∂v∂y + w∂v∂z) = −∂P′∂y + μ∇2v

z-component:

ρ(∂w∂t + u∂w∂x + v∂w∂y + w∂w∂z) = −∂P′∂z + μ∇2w

Now,

During, non-dimensionalization a modified pressure is introduced. This helps in absorbing the hydrostatic pressure. It is defined as:

P′ = P + ρgz

Here,

P is pressure,

P′ is modified pressure

Z is the vertical direction vector

ρ is the density of fluid

When these equations are combined with appropriate boundary condition the problem can be solved.

Answer 9

Expert Solution & Answer

Answer 10

Expert Solution & Answer

Answer 11

To determine

The list of variables and corresponding equation used to solve on the computer.

Answer 12

Explanation of Solution

According to the data given in question for an incompressible Newtonian laminar flow fluid with no free surface. The unknown quantity present in the Stokes flow equation are u, v and P.

The corresponding equation for the given flow condition is continuity of Navier-Stokes equation. The other equation is: -