Fluid Mechanics PDF

Summary

This document provides an overview of fluid mechanics, covering topics like characteristics of fluids, measures of fluid mass and weight, viscosity, compressibility, vapor pressure, and surface tension. It also introduces concepts from fluid statics and dynamics. The text suggests it is part of a course syllabus or lecture notes.

Full Transcript

FLUID MECHANICS
Syllabus (Hand-Out)
Fluid Mechanics Overview
Characteristics of Fluids
Measures of Fluid Mass and Weight
Viscosity
Compressibility
Vapor Pressure
Surface Tension
 Fluid Mechanics Overview

Fluid Mechanics

Gas Liquids Statics Dynamics

F  0 i  F  0 , Flows
i

Water, Oils, Stability
Air, He, Ar,
Alcohols, Buoyancy
N2, etc. Pressure Compressible/
etc.
Incompressible
Laminar/
Surface
Turbulent
Tension
Steady/Unsteady
Compressibility Density Viscosity Vapor Viscous/Inviscid
Pressure
Chapter 1: Introduction Fluid Dynamics:
Chapter 2: Fluid Statics
Rest of Course
 Characteristics of Fluids

Gas or liquid state
“Large” molecular spacing relative to a solid
“Weak” intermolecular cohesive forces
Can not resist a shear stress in a stationary
state
Will take the shape of its container
Generally considered a continuum
Viscosity distinguishes different types of fluids
 Measures of Fluid Mass and Weight: Density
The density of a fluid is defined as mass per unit volume.
m

v
m = mass, and v = volume.

Different fluids can vary greatly in density
Liquids densities do not vary much with pressure and temperature
Gas densities can vary quite a bit with pressure and temperature
Density of water at 4° C : 1000 kg/m3
Density of Air at 4° C : 1.20 kg/m3

1
Alternatively, Specific Volume: 

Measures of Fluid Mass and Weight: Specific Weight
The specific weight of fluid is its weight per unit volume.

  g
g = local acceleration of gravity, 9.807 m/s2

Specific weight characterizes the weight of the fluid system
Specific weight of water at 4° C : 9.80 kN/m3
Specific weight of air at 4° C : 11.9 N/m3
Measures of Fluid Mass and Weight: Specific Gravity
The specific gravity of fluid is the ratio of the density of the fluid
to the density of water @ 4° C.


SG 
 H 2O

Gases have low specific gravities
A liquid such as Mercury has a high specific gravity, 13.2
The ratio is unitless.
Density of water at 4° C : 1000 kg/m3
 Viscosity: Introduction
The viscosity is measure of the “fluidity” of the fluid which is not
captured simply by density or specific weight. A fluid can not resist a
shear and under shear begins to flow. The shearing stress and
shearing strain can be related with a relationship of the following form
for common fluids such as water, air, oil, and gasoline:
du
 
dy
 is the absolute viscosity or dynamics viscosity of the fluid, u is the
velocity of the fluid and y is the vertical coordinate as shown in the
schematic below:

“No Slip
Condition”
 Viscosity: Measurements
A Capillary Tube Viscosimeter is one method of measuring
the viscosity of the fluid.
Viscosity Varies from Fluid to Fluid and is dependent on
temperature, thus temperature is measured as well.
Units of Viscosity are N·s/m2 or lb·s/ft2

Movie Example using a Viscosimeter:
 Viscosity: Newtonian vs. Non-Newtonian
Toothpaste
Latex
Paint

Corn
Starch

Newtonian Fluids are Linear Relationships between stress and
strain: Most common fluids are Newtonian.
Non-Newtonian Fluids are Non-Linear between stress and strain
 Viscosity: Kinematic Viscosity




Kinematic viscosity is another way of representing
viscosity
Used in the flow equations
The units are of L2/T or m2/s and ft2/s
 Compressibility of Fluids: Bulk Modulus
dp
E 
d / 
P is pressure, and r is the density.

Measure of how pressure compresses the volume/density
Units of the bulk modulus are N/m2 (Pa) and lb/in.2 (psi).
Large values of the bulk modulus indicate incompressibility
Incompressibility indicates large pressures are needed to compress the
volume slightly
It takes 3120 psi to compress water 1% at atmospheric pressure and 60°
F.
Most liquids are incompressible for most practical engineering problems.
Compressibility of Fluids: Compression of Gases
Ideal Gas Law: p  RT

P is pressure, r is the density, R is the gas constant, and T is Temperature

Isothermal Process (constant temperature):
p Math
 cons tan t E  p

Isentropic Process (frictionless, no heat exchange):
p Math
k
 cons tan t E  kp

k is the ratio of specific heats, cp (constant pressure) to
cv (constant volume), and R = cp – cv.

If we consider air under at the same conditions as water, we can
show that air is 15,000 times more compressible than water.
However, many engineering applications allow air to be
considered incompressible.
Compressibility of Fluids: Speed of Sound
A consequence of the compressibility of fluids is that small disturbances
introduced at a point propagate at a finite velocity. Pressure disturbances
in the fluid propagate as sound, and their velocity is known as the speed of
sound or the acoustic velocity, c.

dp Ev
c or c 
d 

Isentropic Process (frictionless, no heat exchange because):

kp
c

Ideal Gas and Isentropic Process:

c  kRT
 Compressibility of Fluids: Speed of Sound
Speed of Sound in Air at 60 °F  1117 ft/s or 300 m/s
Speed of Sound in Water at 60 °F  4860 ft/s or 1450 m/s
If a fluid is truly incompressible, the speed of sound is infinite,
however, all fluids compress slightly.

Example: A jet aircraft flies at a speed of 250 m/s at an altitude of 10,700
m, where the temperature is -54 °C. Determine the ratio of the speed of
the aircraft, V, to the speed of sound, c at the specified altitude. Assume k
= 1.40
Ideal Gas and Isentropic Process:
c  kRT
c  1.40 * (286.9 J / kgK ) * 219 K
c  296.6 m / s
 Compressibility of Fluids: Speed of Sound
Example (Continued):
V
Ratio 
c
250 m / s
Ratio 
296.6 m / s
Ratio  0.84
 The above ratio is known as the Mach Number, Ma
 For Ma < 1 Subsonic Flow
 For Ma > 1 Supersonic Flow

For Ma > 1 we see shock waves and “sonic booms”:
1) Wind Tunnel Visualization known as Schlieren
method
2) Condensation instigated from jet speed allowing us to
see a shock wave
 Vapor Pressure: Evaporation and Boiling
Evaporation occurs in a fluid when liquid molecules at the surface have
sufficient momentum to overcome the intermolecular cohesive forces and escape
to the atmosphere.

Vapor Pressure is that pressure exerted on the fluid by the vapor in a closed
saturated system where the number of molecules entering the liquid are the same
as those escaping. Vapor pressure depends on temperature and type of fluid.

Boiling occurs when the absolute pressure in the fluid reaches the vapor pressure.
Boiling occurs at approximately 100 °C, but it is not only a function of temperature,
but also of pressure. For example, in Colorado Spring, water boils at temperatures
less than 100 °C.

Cavitation is a form of
Boiling due to low pressure
locally in a flow.
 Surface Tension
At the interface between a liquid and a gas or two immiscible liquids, forces
develop forming an analogous “skin” or “membrane” stretched over the
fluid mass which can support weight.

This “skin” is due to an imbalance of cohesive forces. The interior of the fluid is
in balance as molecules of the like fluid are attracting each other while on the
interface there is a net inward pulling force.

Surface tension is the intensity of the molecular attraction per unit length along
any line in the surface.

Surface tension is a property of the liquid type, the temperature, and the other
fluid at the interface.

This membrane can be “broken” with a surfactant which reduces the surface
tension.
 Surface Tension: Liquid Drop
The pressure inside a drop of fluid can be calculated using a free-body diagram:
Real Fluid Drops Mathematical Model

R is the radius of the droplet, s is the surface tension, Dp is the pressure
difference between the inside and outside pressure.
The force developed around the edge due to surface tension along the line:
F  2 R  Applied to Circumference
surface
This force is balanced by the pressure difference Dp:
2 Applied to Area
F pressure  DpR
 Surface Tension: Liquid Drop
Now, equating the Surface Tension Force to the Pressure Force, we
can estimate Dp = pi – pe:
2
Dp 
R
This indicates that the internal pressure in the droplet is greater that the
external pressure since the right hand side is entirely positive.

Is the pressure inside a bubble of water greater or less than that of a
droplet of water?
4
Prove to yourself the following result: Dp 
R
 Surface Tension: Capillary Action
Capillary action in small tubes which involve a liquid-gas-solid
interface is caused by surface tension. The fluid is either drawn up
the tube or pushed down.
“Wetted” “Non-Wetted”

Adhesion

Cohesion
Adhesion
Cohesion

Adhesion > Cohesion Cohesion > Adhesion

h is the height, R is the radius of the tube, q is the angle of contact.
The weight of the fluid is balanced with the vertical force caused by surface
tension.
 Flow In Circular Pipes
Objective
ä To measure the pressure drop in the straight section of smooth,
rough, and packed pipes as a function of flow rate.
ä To correlate this in terms of the friction factor and Reynolds number.
ä To compare results with available theories and correlations.
ä To determine the influence of pipe fittings on pressure drop
ä To show the relation between flow area, pressure drop and loss as a
function of flow rate for Venturi meter and Orifice meter.
 APPARATUS

Pipe Network
Rotameters
Manometers
 Theoretical Discussion
Fluid flow in pipes is of considerable importance in process.
Animals and Plants circulation systems.
In our homes.
City water.
Irrigation system.
Sewer water system
 Fluid could be a single phase: liquid or gases
Mixtures of gases, liquids and solids
 NonNewtonian fluids such as polymer melts, mayonnaise
 Newtonian fluids like in your experiment (water)
 Theoretical Discussion
Laminar flow
To describe any of these flows, conservation of mass and conservation of
momentum equations are the most general forms could be used to describe the
dynamic system. Where the key issue is the relation between flow rate and
pressure drop.

If the flow fluid is:
a. Newtonian
b. Isothermal
c. Incompressible (dose not depend on the pressure)
d. Steady flow (independent on time).
e. Laminar flow (the velocity has only one single component)
 Laminar flow
Navier-Stokes equations is govern the flow field (a set of equations containing
only velocity components and pressure) and can be solved exactly to obtain the
Hagen-Poiseuille relation.
Pz

Flow If the principle of conservation of
momentum is applied to a fixed
volume element through which fluid Vz(r)
is flowing and on which forces are
acting, then the forces must be Pz+dz
balanced (Newton second law)

r In
r

Body force due to gravity r
r+dr r

Pz+dz
 Laminar flow
Forces balance Continue
Sum of forces  Rate of change of momentum 
    
in the z - direction   in the z - direction 

dFz r  2r zr r dz Pz

dFz r  dr  2 (r  dr) zr r dr dz 1…Shear forces

Vz(r)
 p z 2  rdr 2….Pressure Pz+dz

 p z  dz 2 rdr r
r+dr r
3…..Body force
g2 rdrdz
 Laminar flow
Continue
Momentum is
Mass*velocity (m*v)
Momentum per unit volume is
*vz
Rate of flow of momentum is
*vz*dQ
dQ=vz2πrdr
but
vz = constant at a fixed value of
r

 v z (v2rdr) z  v z (v2rdr) z dz  0 Laminar flow
 Laminar flow
Continue

2 r zr r dz  2 (r  dr) zr r dr dz p z 2 rdr  p z dz 2rdr  g2rdrdz  0

dvz Dp  pz 0  pz L  gL
 
dr

R R 4 Dp Hagen-Poiseuille
Q  0
2vz dr 
8 L
 Turbulent flow

When fluid flow at higher
flowrates, the streamlines are not uz
steady and straight and the flow is Uz
averag
not laminar. Generally, the flow úz e
field will vary in both space and
time with fluctuations that
ur
comprise "turbulence
Ur
averag
For this case almost all terms in úr e
the Navier-Stokes equations are p
important and there is no simple p
averag
solution P’ e

P = P (D, , , L, U,) Time
 Turbulent flow

All previous parameters involved three fundamental dimensions,
Mass, length, and time
From these parameters, three dimensionless groups can be build

DP L
2  f (Re, )
U D

UD inertia
Re  
 Viscous forces
 Friction Factor for Laminar
Turbulent flows
From forces balance and the definition of Friction Factor

DP  Ac    S  L
Ac: cross section area of the pip  DP R
Ac 1
 rh  D S: Perimeter on which T acts (wetted
f 2 f
S 4 perimeter) 1/2 U U 2 L
DP Rh hydraulic radius
  R
2L
 r 4 DP
For Laminar flow Q
(Hagen - Poiseuill eq) 8 L DP R 8 16
DP 8U f 2  
 2 L U  UR Re
L R

DP D 0.25
For Turbulent Flow f  0.079Re
L 2 U 2
 Turbulence: Flow Instability
 In turbulent flow (high Reynolds number) the force leading to stability
(viscosity) is small relative to the force leading to instability (inertia).
 Any disturbance in the flow results in large scale motions superimposed
on the mean flow.
 Some of the kinetic energy of the flow is transferred to these large
scale motions (eddies).
 Large scale instabilities gradually lose kinetic energy to smaller scale
motions.
 The kinetic energy of the smallest eddies is dissipated by viscous
resistance and turned into heat. (=head loss)
 Velocity Distributions
Turbulence causes transfer of momentum
from center of pipe to fluid closer to the pipe
wall.
Mixing of fluid (transfer of momentum)
causes the central region of the pipe to have
relatively constant velocity (compared to
laminar flow)
Close to the pipe wall eddies are smaller (size
proportional to distance to the boundary)
 Surface Roughness

Additional dimensionless group /D need
to be characterize
Thus more than one curve on friction factor-
Reynolds number plot

Fanning diagram or Moody diagram
Depending on the laminar region.
If, at the lowest Reynolds numbers, the laminar portion
corresponds to f =16/Re Fanning Chart
or f = 64/Re Moody chart
 Friction Factor for Smooth, Transition,
and Rough Turbulent flow
DP D
f 
L 2 U 2
1
Smooth pipe, Re>3000 f

 4.0 * log Re* 
f  0.4

f  0.079Re0.25

1 D
 4.0 * log  2.28
Rough pipe, [ (D/)/(Re√ƒ)