mechanical viraction types merit and demerits.ppt
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Aug 09, 2024
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About This Presentation
vibration
Slide Content
MAK4041-Mechanical VibrationsMAK4041-Mechanical Vibrations
Important Notes:Important Notes:
The course notes were compiled
mostly from
1) The book by Graham Kelly,
“Mechanical Vibrations,
Theory and Applications”,
2012.
2) Bruel Kjaer Technical notes,
3) Dan Russel’s webpage:
http://www.acs.psu.edu/drussell
Therefore, they are gratefully
acknowledged.
Important Notes:Important Notes:
The course notes were compiled
mostly from
1) The book by Graham Kelly,
“Mechanical Vibrations,
Theory and Applications”,
2012.
2) Bruel Kjaer Technical notes,
3) Dan Russel’s webpage:
http://www.acs.psu.edu/drussell
Therefore, they are gratefully
acknowledged.
WEEK-1: WEEK-1:
Introduction to Mechanical VibrationsIntroduction to Mechanical Vibrations
Introduction to Mechanical VibrationsIntroduction to Mechanical Vibrations
What is vibration?
Vibrations are oscillations of a system about
an equilbrium position.
Vibrations are oscillations of a system about
an equilbrium position.
Vibration…
It is also an
everyday
phenomenon we
meet on everyday
life
It is also an
everyday
phenomenon we
meet on everyday
life
Vibration …
Useful Vibration Harmful vibration
Noise
Destruction
Compressor
Ultrasonic
cleaning
Testing
Wear
Fatigue
Useful Vibration Harmful vibration
Noise
Destruction
Compressor
Ultrasonic
cleaning
Testing
Wear
Fatigue
Vibration parameters
All mechanical systems
can be modeled by
containing three basic
components:
spring, damper, mass
When these components are subjected to constant force,
they react with a constant
displacement, velocity and acceleration
All mechanical systems
can be modeled by
containing three basic
components:
spring, damper, mass
When these components are subjected to constant force,
they react with a constant
displacement, velocity and acceleration
Free vibration
Equilibrium pos.
When a system is initially disturbed by a displacement,
velocity or acceleration, the system begins to vibrate with
a constant amplitude and frequency depend on its
stiffness and mass.
This frequency is called as natural frequency, and the
form of the vibration is called as mode shapes
Equilibrium pos.
When a system is initially disturbed by a displacement,
velocity or acceleration, the system begins to vibrate with
a constant amplitude and frequency depend on its
stiffness and mass.
This frequency is called as natural frequency, and the
form of the vibration is called as mode shapes
Forced Vibration
If an external force applied to a
system, the system will follow the
force with the same frequency.
However, when the force
frequency is increased to the
system’s natural frequency,
amplitudes will dangerously
increase in this region. This
phenomenon called as
“Resonance”
’
If an external force applied to a
system, the system will follow the
force with the same frequency.
However, when the force
frequency is increased to the
system’s natural frequency,
amplitudes will dangerously
increase in this region. This
phenomenon called as
“Resonance”
’
Bridge collapse:
http://www.youtube.com/watch?v=j-zczJXSxnw
Hellicopter resonance:
http://www.youtube.com/watch?v=0FeXjhUEXlc
Resonance vibration test:
http://www.youtube.com/watch?v=LV_UuzEznHs
Flutter (Aeordynamically induced vibration) :
http://www.youtube.com/watch?v=OhwLojNerMU
Watch these …
http://www.youtube.com/watch?v=j-zczJXSxnw
Hellicopter resonance:
http://www.youtube.com/watch?v=0FeXjhUEXlc
Resonance vibration test:
http://www.youtube.com/watch?v=LV_UuzEznHs
Flutter (Aeordynamically induced vibration) :
http://www.youtube.com/watch?v=OhwLojNerMU
Watch these …
Lumped (Rigid) ModellingNumerical Modelling
Element-based
methods
(FEM, BEM)
Statistical and Energy-
based methods
(SEA, EFA, etc.)
Modelling of vibrating systems
Element-based
methods
(FEM, BEM)
Statistical and Energy-
based methods
(SEA, EFA, etc.)
Modelling of vibrating systems
• Mathematical modeling of a physical system requires the
selection of a set of variables that describes the behavior
of the system.
• The number of degrees of freedom for a system is the
number of kinematically independent variables necessary
to completely describe the motion of every particle in the
system
DOF=1
Single degree of freedom (SDOF)
DOF=2
Multi degree of freedom (MDOF)
Degree of Freedom (DOF)
selection of a set of variables that describes the behavior
of the system.
• The number of degrees of freedom for a system is the
number of kinematically independent variables necessary
to completely describe the motion of every particle in the
system
DOF=1
Single degree of freedom (SDOF)
DOF=2
Multi degree of freedom (MDOF)
Degree of Freedom (DOF)
Equivalent model of systems
Example 1: Example 2:
SDOF
DOF=1
MDOF
DOF=2
Example 1: Example 2:
SDOF
DOF=1
MDOF
DOF=2
Equivalent model of systems
Example 3:
SDOF
MDOF
DOF=2
DOF= 3 if body 1 has no rotation
DOF= 4 if body 1 has rotation
body 1
Example 3:
SDOF
MDOF
DOF=2
DOF= 3 if body 1 has no rotation
DOF= 4 if body 1 has rotation
body 1
What are their DOFs?
SDOF systems
Helical springs
F: Force, D: Diameter, G: Shear modulus of the rod,
N: Number of turns, r : Radius
Shear stress:
Stiffness coefficient:
Springs in combinations:
Parallel combination Series combination
Helical springs
F: Force, D: Diameter, G: Shear modulus of the rod,
N: Number of turns, r : Radius
Shear stress:
Stiffness coefficient:
Springs in combinations:
Parallel combination Series combination
Elastic elements as springs
Moment of Inertia
What are the equivalent stiffnesses?
Example
A 200-kg machine is attached to the end of a cantilever beam of length L=
2.5 m, elastic modulus E= 200x10
9
N/m
2
, and cross-sectional moment of
inertia I = 1.8x10
–6
m4. Assuming the mass of the beam is small compared to
the mass of the machine, what is the stiffness of the beam?
A 200-kg machine is attached to the end of a cantilever beam of length L=
2.5 m, elastic modulus E= 200x10
9
N/m
2
, and cross-sectional moment of
inertia I = 1.8x10
–6
m4. Assuming the mass of the beam is small compared to
the mass of the machine, what is the stiffness of the beam?
Damping
Viscous Damping
Viscous Damping
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