Fluid Kinematics | Fluid Mechanics for Civil Engineering - Civil Engineering (CE) PDF Download

Introduction

Kinematics is the geometry of motion. Kinematics of fluid describes the fluid motion and its consequences without consideration of the nature of forces causing the motion.

Fluid Kinematics | Fluid Mechanics for Civil Engineering - Civil Engineering (CE)


Main Aspects

The subject has three main aspects:

  1. Development of methods and techniques for describing and specifying the motions of fluids.
  2. Determination of the conditions for the kinematic possibility of fluid motions.
  3. Characterization of different types of motion and associated deformation rates of any fluid element.Fluid Kinematics | Fluid Mechanics for Civil Engineering - Civil Engineering (CE)

Scalar & Vector Fields

 Scalar: Scalar is a quantity that can be expressed by a single number representing its magnitude.
Example: Mass, Density, and Temperature.

➢ Scalar Field: If at every point in a region, a scalar function has a defined value, the region is called a scalar field.
Example: Temperature distribution in a rod.

 Vector: Vector is a quantity that is specified by both magnitude and direction.
Example: Force, Velocity, and Displacement.

➢ Vector Field: If at every point in a region, a vector function has a defined value, the region is called a vector field.
Example: Velocity field of a flowing fluid.

 Flow Field: The region in which the flow parameters i.e. velocity, pressure, etc. are defined at each and every point at any instant of time is called a flow field. Thus, a flow field would be specified by the velocities at different points in the region at different times.

Description of Fluid Motion

(a) Lagrangian Method

  • Using the Lagrangian method, the fluid motion is described by tracing the kinematic behavior of each particle constituting the flow.

  • Identities of the particles are made by specifying their initial position (spatial location) at a given time. The position of a particle at any other instant of time then becomes a function of its identity and time.

➢ Analytical expression of the last statement
Fluid Kinematics | Fluid Mechanics for Civil Engineering - Civil Engineering (CE)
whereFluid Kinematics | Fluid Mechanics for Civil Engineering - Civil Engineering (CE)is the position vector of a particle (with respect to a fixed point of reference) at a time t. (6.1)
Fluid Kinematics | Fluid Mechanics for Civil Engineering - Civil Engineering (CE)is its initial position at a given time, t =t0
Equation (6.1) can be written into scalar components with respect to a rectangular cartesian frame of coordinates as:
► x = x(x0,y0,z0,t) (6.1a)
► y = y(x0,y0,z0,t) (6.1b)
► z = z(x0,y0,z0,t) (6.1c)
where, x0,y0,z0 are the initial coordinates and x, y, z are the coordinates at a time t of the particle.
HenceFluid Kinematics | Fluid Mechanics for Civil Engineering - Civil Engineering (CE)can be expressed as:

Fluid Kinematics | Fluid Mechanics for Civil Engineering - Civil Engineering (CE) Fluid Kinematics | Fluid Mechanics for Civil Engineering - Civil Engineering (CE) are the unit vectors along  x, y and z axes respectively.
The velocityFluid Kinematics | Fluid Mechanics for Civil Engineering - Civil Engineering (CE)and acceleration of the fluid particle can be obtained from the material derivatives of the position of the particle with respect to time.
Therefore,Fluid Kinematics | Fluid Mechanics for Civil Engineering - Civil Engineering (CE) (6.2a)

In terms of scalar components:
Fluid Kinematics | Fluid Mechanics for Civil Engineering - Civil Engineering (CE)

where u, v, w are the components of velocity in x, y, z directions respectively.

Similarly, for the acceleration, Fluid Kinematics | Fluid Mechanics for Civil Engineering - Civil Engineering (CE)(6.3a)and hence,
Fluid Kinematics | Fluid Mechanics for Civil Engineering - Civil Engineering (CE)
where ax, ay, az are accelerations in x, y, z directions respectively.

➢ Advantages of Lagrangian Method

  • Since the motion and trajectory of each fluid particle are known, its history can be traced.
  • Since particles are identified at the start and traced throughout their motion, conservation of mass is inherent.

➢ Disadvantages of Lagrangian Method

  •  The solution of the equations presents appreciable mathematical difficulties except for certain special cases and therefore, the method is rarely suitable for practical applications.

(b) Eulerian Method

  • The method was developed by Leonhard Euler.
  • This method is of a greater advantage since it avoids the determination of the movement of each individual fluid particle in all details.
  • It seeks the velocityFluid Kinematics | Fluid Mechanics for Civil Engineering - Civil Engineering (CE)and its variation with time t at each and every locationFluid Kinematics | Fluid Mechanics for Civil Engineering - Civil Engineering (CE)in of the flow field.
  • In the Eulerian view, all hydrodynamic parameters are functions of location and time.

➢ Mathematical representation of the flow field in the Eulerian method
Fluid Kinematics | Fluid Mechanics for Civil Engineering - Civil Engineering (CE)= v (Fluid Kinematics | Fluid Mechanics for Civil Engineering - Civil Engineering (CE), t) (6.4), whereFluid Kinematics | Fluid Mechanics for Civil Engineering - Civil Engineering (CE)andFluid Kinematics | Fluid Mechanics for Civil Engineering - Civil Engineering (CE)Therefore:
► u = u (x, y, z, t)
► v = v (x, y, z, t)
► w = w (x, y, z, t) 

Question for Fluid Kinematics
Try yourself:In which method of describing fluid motion, the observer remains stationary and observes changes in the fluid parameters at a particular point only?
View Solution

(c) The Relation Between Eulerian & Lagrangian Method

The Eulerian description can be written as:
Fluid Kinematics | Fluid Mechanics for Civil Engineering - Civil Engineering (CE)(6.5)
or
dx/dt = u(x,y,z,t)
dy/dt = v(x,y,z,t)
dz/dt = w(x,y,z,t)
The integration of Eq. (6.5) yields the constants of integration which are to be found from the initial coordinates of the fluid particles.
Hence, the solution of Eq. (6.5) gives the equations of Lagrange as:
Fluid Kinematics | Fluid Mechanics for Civil Engineering - Civil Engineering (CE)or x = x(x0,y0,z0,t)
y = y(x0,y0,z0,t)
z = z(x0,y0,z0,t)
The above relation is the same as the Lagrangian formulation.

Fluid Kinematics | Fluid Mechanics for Civil Engineering - Civil Engineering (CE)In principle, the Lagrangian method of description can always be derived from the Eulerian method.

The document Fluid Kinematics | Fluid Mechanics for Civil Engineering - Civil Engineering (CE) is a part of the Civil Engineering (CE) Course Fluid Mechanics for Civil Engineering.
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FAQs on Fluid Kinematics - Fluid Mechanics for Civil Engineering - Civil Engineering (CE)

1. What is the difference between scalar and vector fields in fluid mechanics?
Ans. A scalar field in fluid mechanics refers to a quantity that only has magnitude, such as temperature or pressure. On the other hand, a vector field in fluid mechanics refers to a quantity that has both magnitude and direction, such as velocity or acceleration.
2. How can the Lagrangian method be used to study fluid motion?
Ans. The Lagrangian method is a mathematical approach used to analyze fluid motion by tracking individual fluid particles over time. It involves studying the motion, position, and velocity of each particle as it moves through the fluid, providing a detailed understanding of how the fluid behaves.
3. What is fluid kinematics in civil engineering?
Ans. Fluid kinematics in civil engineering deals with the study of fluid motion and characteristics without considering the forces that cause the motion. It focuses on analyzing the velocity, acceleration, and displacement of fluid particles, enabling engineers to design and optimize fluid systems, such as water distribution networks or wastewater treatment plants.
4. What are some applications of fluid kinematics in civil engineering?
Ans. Fluid kinematics in civil engineering has several practical applications. It is used to analyze the flow of water in pipes, design drainage systems to prevent flooding, study river hydraulics for bridge and dam construction, and determine the movement of pollutants in water bodies for environmental impact assessments.
5. Can you provide an example of a scalar field in fluid mechanics?
Ans. Yes, one example of a scalar field in fluid mechanics is pressure. Pressure is a scalar quantity that only has magnitude and is used to describe the distribution of forces exerted by a fluid on its surroundings. By measuring pressure at different points in a fluid, engineers can understand how the fluid flows and interacts with its surroundings.
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