Presentation is loading. Please wait.

Presentation is loading. Please wait.

AAE 556 Aeroelasticity Lecture 18

Published byJeremy Harper Modified over 5 years ago

Similar presentations

Presentation on theme: "AAE 556 Aeroelasticity Lecture 18"— Presentation transcript:

1 AAE 556 Aeroelasticity Lecture 18
Resonance, Mode shapes Purdue Aeroelasticity

2 Purdue Aeroelasticity
Summary MDOF systems with n degrees of freedom have n possible “modes of motion” Mode of motion means a (natural, resonant) frequency with a well-defined mode shape Eigenvectors – another word for mode shapes – provide information about node lines or node points Experiments provide node lines and frequencies to compare with analysis Purdue Aeroelasticity

3 Typical section equations of motion - 2 dof
measured from static equilibrium position Purdue Aeroelasticity

4 Review - Equations of motion for free vibration
Trial solution assume harmonic motion result Purdue Aeroelasticity

5 Harmonic forcing at or near the natural frequencies
Trial solution harmonic motion result Purdue Aeroelasticity

6 Harmonic forcing at or near the natural frequencies
At or near resonance, the amplitude of the response is large (here it is infinite because we have no damping) Purdue Aeroelasticity

7 Purdue Aeroelasticity
Defining mode shapes what will the vibrations look like if we force the system at natural frequencies? (1) (2) eigenvalues & eigenvectors Purdue Aeroelasticity

8 A different expression
Purdue Aeroelasticity

9 Purdue Aeroelasticity
System mode shapes If q is 1 then how much is h? Purdue Aeroelasticity

10 Purdue Aeroelasticity
example Purdue Aeroelasticity

11 Purdue Aeroelasticity
example reference bending actual reference torsion actual Purdue Aeroelasticity

12 Purdue Aeroelasticity
Mode shape When we let h/b=1 then we are asking about the amount of q in the plunge mode 1 unit Purdue Aeroelasticity

13 Shake testing identifies modes and frequencies
Purdue Aeroelasticity

14 Torsional frequency and mode shape
1 radian node point Purdue Aeroelasticity

15 Purdue Aeroelasticity
Node point definition A point in space where there is no displacement, velocity or acceleration when the structure is vibrating at a natural frequency x Purdue Aeroelasticity

16 Node point depends on eigenvector
x divide by b first mode Purdue Aeroelasticity

17 Node point for second frequency
Purdue Aeroelasticity

18 Purdue Aeroelasticity
Summary MDOF systems have n modes of motion Mode of motion means a (natural, resonant) frequency with a mode shape Eigenvectors – mode shapes – provide node lines or node points Experiment provides node lines and frequencies Purdue Aeroelasticity

Download ppt "AAE 556 Aeroelasticity Lecture 18"

Similar presentations

MDOF SYSTEMS WITH DAMPING General case Saeed Ziaei Rad.

MDOF SYSTEMS WITH DAMPING General case Saeed Ziaei Rad.
Kjell Simonsson 1 Vibrations in linear 1-degree of freedom systems; I. undamped systems (last updated 2011-08-26)

Kjell Simonsson 1 Vibrations in linear 1-degree of freedom systems; I. undamped systems (last updated )
Multi-degree of Freedom Systems Motivation: Many systems are too complex to be represented by a single degree of freedom model. Objective of this chapter:

Multi-degree of Freedom Systems Motivation: Many systems are too complex to be represented by a single degree of freedom model. Objective of this chapter:
Small Coupled Oscillations. Types of motion Each multi-particle body has different types of degrees of freedom: translational, rotational and oscillatory.

Small Coupled Oscillations. Types of motion Each multi-particle body has different types of degrees of freedom: translational, rotational and oscillatory.
CHAPTER 4: HARMONIC RESPONSE WITH A SINGLE DEGREE OF FREEDOM

CHAPTER 4: HARMONIC RESPONSE WITH A SINGLE DEGREE OF FREEDOM
WEEK-3: Free Vibration of SDOF systems

WEEK-3: Free Vibration of SDOF systems
Small Vibrations Concepts: Equilibrium position in multidimensional space Oscillations around that position If coordinate system is stationary Equations.

Small Vibrations Concepts: Equilibrium position in multidimensional space Oscillations around that position If coordinate system is stationary Equations.
Introduction to Structural Dynamics:

Introduction to Structural Dynamics:
Measuring Simple Harmonic Motion

Measuring Simple Harmonic Motion
TWO DEGREE OF FREEDOM SYSTEM. INTRODUCTION Systems that require two independent coordinates to describe their motion; Two masses in the system X two possible.

TWO DEGREE OF FREEDOM SYSTEM. INTRODUCTION Systems that require two independent coordinates to describe their motion; Two masses in the system X two possible.
S1-1 SECTION 1 REVIEW OF FUNDAMENTALS. S1-2 n This section will introduce the basics of Dynamic Analysis by considering a Single Degree of Freedom (SDOF)

S1-1 SECTION 1 REVIEW OF FUNDAMENTALS. S1-2 n This section will introduce the basics of Dynamic Analysis by considering a Single Degree of Freedom (SDOF)
 All objects have a NATURAL FREQUENCY at which they tend to vibrate. This frequency depends on the material the object is made of, the shape, and many.

 All objects have a NATURAL FREQUENCY at which they tend to vibrate. This frequency depends on the material the object is made of, the shape, and many.
Motion of a mass at the end of a spring Differential equation for simple harmonic oscillation Amplitude, period, frequency and angular frequency Energetics.

Motion of a mass at the end of a spring Differential equation for simple harmonic oscillation Amplitude, period, frequency and angular frequency Energetics.
Basic structural dynamics II

Basic structural dynamics II
Chapter 14 Outline Periodic Motion Oscillations Amplitude, period, frequency Simple harmonic motion Displacement, velocity, and acceleration Energy in.

Chapter 14 Outline Periodic Motion Oscillations Amplitude, period, frequency Simple harmonic motion Displacement, velocity, and acceleration Energy in.
A PPLIED M ECHANICS Lecture 06 Slovak University of Technology Faculty of Material Science and Technology in Trnava.

A PPLIED M ECHANICS Lecture 06 Slovak University of Technology Faculty of Material Science and Technology in Trnava.
Chapter 7. Free and Forced Response of Single-Degree-of-Freedom Linear Systems 7.1 Introduction Vibration: System oscillates about a certain equilibrium.

Chapter 7. Free and Forced Response of Single-Degree-of-Freedom Linear Systems 7.1 Introduction Vibration: System oscillates about a certain equilibrium.
1 Lecture D32 : Damped Free Vibration Spring-Dashpot-Mass System Spring Force k > 0 Dashpot c > 0 Newton’s Second Law (Define) Natural Frequency and Period.

1 Lecture D32 : Damped Free Vibration Spring-Dashpot-Mass System Spring Force k > 0 Dashpot c > 0 Newton’s Second Law (Define) Natural Frequency and Period.
PAT328, Section 3, March 2001MAR120, Lecture 4, March 2001S14-1MAR120, Section 14, December 2001 SECTION 14 STRUCTURAL DYNAMICS.

PAT328, Section 3, March 2001MAR120, Lecture 4, March 2001S14-1MAR120, Section 14, December 2001 SECTION 14 STRUCTURAL DYNAMICS.
Basic structural dynamics I Wind loading and structural response - Lecture 10 Dr. J.D. Holmes.

Basic structural dynamics I Wind loading and structural response - Lecture 10 Dr. J.D. Holmes.

Similar presentations

Ads by Google