Table of contents | |
Introduction | |
Types of Fluid Flows | |
Flow Pattern | |
Velocity of Fluid Particle | |
Acceleration of Fluid Particle | |
Stream Function | |
Velocity Potential Function |
Fluid Kinematics deals with the motion of fluids such as displacement, velocity, acceleration, and other aspects. This topic is useful in terms of exams and knowledge of the candidate.
Kinematics is the branch of classical mechanics that describes the motion of bodies and systems without consideration of the forces the cause the motion.
Fluid flow may be classified under the following headings:
1. Steady & Unsteady Flow
2. Uniform and Non-Uniform Flow
3. Laminar and Turbulent Flow
4. Rotational & Irrotational Flow
Combining these, the most common flow types are:
(a) Steady uniform flow
Steady Uniform Flow
(b) Steady non-uniform flow
(c) Unsteady uniform flow
(d) Unsteady non-uniform flow
Note: The figure below illustrates streamlines, pathlines, and streaklines for the case of a smoke being continuously emitted by a chimney at point P, in the presence of a shifting wind.
In a steady flow, streamlines, pathlines, and streaklines all coincide.
In this example, they would all be marked by the smoke line.
Where u = dx/dt, v = dy/dt and w = dz/dt are the resultant vectors in X, Y and Z directions, respectively.
Note: It can be concluded that if stream function (ψ) exits, it is a possible case of fluid flow. But we can’t decide whether flow is rotational or irrotational. But if stream function ψ satisfies Laplace equation then, it is a possible case of irrotational flow otherwise it is rotational flow.
It is a scalar function of space and time such that its negative derivative with respect to any direction gives the fluid velocity in that direction. It is denoted by φ.
We know that continuity equation for steady flow is:
Rotational component ωz can be given by:
It shows that φ exits then, flow will be irrotational.
We know,
and
Example 1: The velocity field of a two-dimensional, incompressible flow is given by
where denote the unit vectors in x and y directions, respectively. If v(x,0)=coshx, then v ( 0 , − 1 ) v(0,−1)
(a) 1
(b) 2
(c) 3
(d) 4
Ans: (c)
Solution:
For an incompressible flow,
Given; the velocity field of a two-dimensional, incompressible flow,
Now, (for an incompressible flow)
Integrate both sides,
Now, from equation (1)
Example 2: Consider a unidirectional fluid flow with the velocity field given by
where u(0,t)=1. If the spatially homogeneous density field varies with time t as
the value of u(2,1) is _______. (Rounded off to two decimal places)
Assume all quantities to be dimensionless.
(a) 1.14
(b) 2.25
(c) 3.65
(d) 8.25
Ans: (a)
Continuity equation for unsteady flow
Since
Example 3: The velocity field of a certain two-dimensional flow is given by
where k=2s −1 . The coordinates x and y are in meters. Assume gravitational effects to be negligible. If the density of the fluid is 1000kg/m 3 and the pressure at the origin is 100 kPa, the pressure at the location (2 m, 2 m) is _____________ kPa. (Answer in integer)
(a) 64
(b) 26
(c) 84
(d) 98
Ans: (c)
Solution:
To find the pressure at location (2m,2m) we apply Bernouli's equation
We will apply this equation between two points Origin (0,0) and location (2 m,2 m)
At Origin (0,0)
At Iocation (2,2)
magnitude of velocity
Applying Bernouli's theorem
5 videos|103 docs|59 tests
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1. What is the significance of flow pattern in fluid kinematics? |
2. How is the velocity of a fluid particle determined in fluid kinematics? |
3. What is the role of stream function in fluid kinematics? |
4. How does acceleration of a fluid particle impact fluid kinematics? |
5. How can the velocity potential function be used in fluid kinematics analysis? |
5 videos|103 docs|59 tests
|
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