Dr. Millerjothi, BITS Pilani, Dubai Campus

Chapter:1 ▪ Brief review of fundamental concepts of vibration ▪ Vibration Analysis ▪ Analysis of Simple vibrating systems

Dr. Millerjothi, BITS Pilani, Dubai Campus

✓Vibrations can lead to excessive deflections and failure on the machines and structures.

✓ To reduce vibration through proper design of machines and their mountings.

✓ To utilize profitably in several consumer and industrial applications.

✓ To improve the efficiency of certain machining, casting, forging & welding processes.

✓ To stimulate earthquakes for geological research and conduct studies in design of nuclear reactors.

Importance of the Study of Vibration

Dr. Millerjothi, BITS Pilani, Dubai Campus

!✓Vibrational problems of prime movers due to

inherent unbalance in the engine. ✓Wheel of some locomotive rise more than

centimeter off the track – high speeds – due to imbalance.

✓ Turbines – vibration cause spectacular mechanical failure.

EXAMPLE OF PROBLEMS

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DISADVANTAGES

!✓Cause rapid wear. ✓Create excessive noise. ✓ Leads to poor surface finish (eg: in metal

cutting process, vibration cause chatter). ✓Resonance – natural frequency of vibration of a

machine/structure coincide with the frequency of the external excitation (eg: Tacoma Narrow Bridge – 1948)

Dr. Millerjothi, BITS Pilani, Dubai Campus

Applications

Dr. Millerjothi, BITS Pilani, Dubai Campus

Basic Concepts of Vibration

❑ Vibration = any motion that repeats itself after an interval of time. !

❑ Vibratory System consists of: 1) spring or elasticity 2) mass or inertia 3) damper !!❑ Involves transfer of potential energy to kinetic energy and vice

versa.

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❑ Degree of Freedom (d.o.f.) = min. no. of independent coordinates required to determine completely the positions of all parts of a system at any instant of time

❑ Examples of single degree-of-freedom systems:

Basic Concepts of Vibration

Dr. Millerjothi, BITS Pilani, Dubai Campus

Basic Concepts of Vibration

❑ Examples of single degree-of-freedom systems:

Dr. Millerjothi, BITS Pilani, Dubai Campus

Basic Concepts of Vibration

❑ Examples of Two degree-of-freedom systems:

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Basic Concepts of Vibration

❑ Examples of Three degree of freedom systems:

Dr. Millerjothi, BITS Pilani, Dubai Campus

Basic Concepts of Vibration

❑ Example of Infinite number of degrees of freedom system: !!!

❑ Infinite number of degrees of freedom system are termed continuous or distributed systems.

❑ Finite number of degrees of freedom are termed discrete or lumped parameter systems.

❑ More accurate results obtained by increasing number of degrees of freedom.

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Classification  of  vibration

❑ Free Vibration:A system is left to vibrate on its own after an initial disturbance and no external force acts on the system. E.g. simple pendulum

❑ Forced Vibration:A system that is subjected to a repeating external force. E.g. oscillation arises from diesel engines ➢Resonance occurs when the frequency of the external

force coincides with one of the natural frequencies of the system

Dr. Millerjothi, BITS Pilani, Dubai Campus

Dr. Millerjothi, BITS Pilani, Dubai Campus

❑ Undamped Vibration:When no energy is lost or dissipated in friction or other resistance during oscillations

❑ Damped Vibration: When any energy is lost or dissipated in friction or other resistance during oscillations

❑ Linear Vibration:When all basic components of a vibratory system, i.e. the spring, the mass and the damper behave linearly

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Damped and Undamped vibrations

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❑ Nonlinear Vibration:If any of the components behave nonlinearly

❑ Deterministic Vibration:If the value or magnitude of the excitation (force or motion) acting on a vibratory system is known at any given time

❑ Nondeterministic or random Vibration: When the value of the excitation at a given time cannot be predicted

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❑ Examples of deterministic and random excitation:

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Harmonic motion

❑ Periodic Motion: motion repeated after equal intervals of time

❑ Harmonic Motion: simplest type of periodic motion ❑ Displacement (x): !❑ Velocity: !

❑ Acceleration:

τπt

Ax 2sin=

)2/sin(cos πωωωω +=== tAtAdtdx

x!

)(sinsin 222

2

πωωωω +=−== tAtAdtxd

x!!

xx 2ω−=!!

Dr. Millerjothi, BITS Pilani, Dubai Campus

The similarity between cyclic (harmonic) and sinusoidal motion.

Dr. Millerjothi, BITS Pilani, Dubai Campus

Dr. Millerjothi, BITS Pilani, Dubai Campus

The trigonometric functions of sine and cosine are related to the exponential function by Euler’s equation.

exp(iθ) = cos(θ) + i sin(θ) The vector P rotating at constant angular Speed ω can be represented as !!!!Where x =real component and y = imaginery component.

Dr. Millerjothi, BITS Pilani, Dubai Campus

Dr. Millerjothi, BITS Pilani, Dubai Campus

Vibrations of several different frequencies exist simultaneously. Such vibrations result in a complex waveform which is repeated periodically as shown

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A periodic function:

Harmonic Analysis

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Fourier Series Expansion: If x(t) is a periodic function with periodic τ, its Fourier Series representation is given by

∑∞

=

++=

+++

+++=

1

0

21

210

)sincos(2

...2sinsin

...2coscos2

)(

nnn tnbtna

a

tbtb

tataatx

ωω

ωω

ωω

Dr. Millerjothi, BITS Pilani, Dubai Campus

•Complex  Fourier  Series: The  Fourier  series  can  also  be  represented  in  terms  of  complex  numbers.  

titetite

ti

ti

ωω

ωωω

ω

sincos

sincos

−=

+=−

Also,

ieet

eet

titi

titi

2sin

2cos

ωω

ωω

ω

ω

−

−

−=

+=

and

Dr. Millerjothi, BITS Pilani, Dubai Campus

•Frequency  Spectrum:  Harmonics  plotted  as  vertical  lines  on  a  diagram  of  amplitude  (an  and  bn  or  dn  and  Φn)  versus  frequency  (nω).

Dr. Millerjothi, BITS Pilani, Dubai Campus

Even and odd functions:

∑∞

=

+=

=−

1

0 cos2

)(

)()(

nn tna

atx

txtx

ω

Even  function  &  its  Fourier  series  expansion

Odd  function  &  its  Fourier  series  expansion

∑∞

=

=

−=−

1

sin)(

)()(

nn tnbtx

txtx

ω

Dr. Millerjothi, BITS Pilani, Dubai Campus

Half-Range Expansions:

The  function  is  extended  to  include  the  interval    –  τ to  0  as  shown  in  the  figure.  The  Fourier  series  expansions  of  x1(t)  and  x2(t)  are  known  as  half-­‐range  expansions.

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Example 1Addition of Harmonic Motions

Find the sum of the two harmonic motions

!

Solution: Method 1: By using trigonometric relations:

Since the circular frequency is the same for both x1(t) and x2(t), we express the sum as

).2cos(15)( and cos10)(21

+== ttxttx ωω

E.1)()()()cos()(21txtxtAtx +=+= αω

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That is, !!That is, !!By equating the corresponding coefficients of cosωt and sinωt

on both sides, we obtain

( )E.2)()2sinsin2cos(cos15cos10

)2cos(15cos10sinsincoscosttt

ttttAωωω

ωωαωαω

−+=

++=−

E.3)()2sin15(sin)2cos1510(cos)sin(sin)cos(cos

ttAtAtω

ωαωαω

−

+=−

( )1477.14

)2sin15(2cos1510

2sin15sin2cos1510cos

22

=

++=

=

+=

A

AA

α

α

Dr. Millerjothi, BITS Pilani, Dubai Campus

and

E.5)(5963.742cos1510

2sin15tan 1

°=

!"#

$%&

+= −α

Dr. Millerjothi, BITS Pilani, Dubai Campus

Method 2: By using complex number representation:: the two harmonic motions can be denoted in terms of complex numbers:

!!!!The sum of x1(t) and x2(t) can be expressed as

[ ] [ ][ ] [ ] E.7)(15ReRe)(

10ReRe)()2()2(

22

11

++ ≡=

≡=titi

titi

eeAtxeeAtx

ωω

ωω

[ ] E.8)(Re)( )( αω += tiAetx

Example  2

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where A and α can be determined using the following equations

!!!!!!and A = 14.1477 and α = 74.5963º

2,1;)( 22 =+= jbaA jjj

2,1;tan 1 =!!"

#$$%

&= − j

ab

j

jjθ

Dr. Millerjothi, BITS Pilani, Dubai Campus

Vibration Terminology

❑ Definitions of Terminology: ➢Amplitude (A) is the maximum displacement of a vibrating

body from its equilibrium position

➢Period of oscillation (T) is time taken to complete one cycle of motion !

➢Frequency of oscillation (f) is the no. of cycles per unit time

ωπ2

=T

πω2

1==

Tf

Dr. Millerjothi, BITS Pilani, Dubai Campus

➢Natural frequency is the frequency which a system oscillates without external forces

➢Phase angle (φ) is the angular difference between two synchronous harmonic motions

( )φω

ω

+=

=

tAxtAx

sinsin

22

11

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➢Beats are formed when two harmonic motions, with frequencies close to one another, are added

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➢The peak value generally indicates the maximum stress that the vibrating part is undergoing.

➢The average value indicates a steady or static value. It is found from

!!For example, the average value of complete A sin t is zero, but

of a half cycle

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➢The mean square value of a time function x(t) is found from average of the squared values, integrated over some time interval T

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➢Decibel   is   originally   defined   as   a   ratio   of   electric  powers.  It  is  now  often  used  as  a  notation  of  various  quantities   such   as   displacement,   velocity,  acceleration,  pressure,  and  power

!!"

#$$%

&=

!!"

#$$%

&=

0

0

log20dB

log10dB

XX

PP

where  P0  is  some  reference  value  of  power  and  X0  is  specified  reference  voltage.

Dr. Millerjothi, BITS Pilani, Dubai Campus

Problem 3

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Solution

Dr. Millerjothi, BITS Pilani, Dubai Campus

Dr. Millerjothi, BITS Pilani, Dubai Campus

Dr. Millerjothi, BITS Pilani, Dubai Campus

Dr. Millerjothi, BITS Pilani, Dubai Campus