Vibration Dynamics and Control

Similar documents
Table of Contents. Preface... 13

Vibrations in Mechanical Systems

COPYRIGHTED MATERIAL. Index

Vibrations and Waves in Continuous Mechanical Systems

VIBRATION PROBLEMS IN ENGINEERING

Static & Dynamic. Analysis of Structures. Edward L.Wilson. University of California, Berkeley. Fourth Edition. Professor Emeritus of Civil Engineering

Introduction to Mechanical Vibration

Self-Excited Vibration

Towards Rotordynamic Analysis with COMSOL Multiphysics

Structural Dynamics Lecture 4. Outline of Lecture 4. Multi-Degree-of-Freedom Systems. Formulation of Equations of Motions. Undamped Eigenvibrations.

Esben Byskov. Elementary Continuum. Mechanics for Everyone. With Applications to Structural Mechanics. Springer

Structural Dynamics Lecture Eleven: Dynamic Response of MDOF Systems: (Chapter 11) By: H. Ahmadian

Introduction to Continuous Systems. Continuous Systems. Strings, Torsional Rods and Beams.

ROTATING MACHINERY VIBRATION

202 Index. failure, 26 field equation, 122 force, 1

Part 1: Discrete systems

The written qualifying (preliminary) examination covers the entire major field body of knowledge

Theory and Practice of Rotor Dynamics Prof. Dr. Rajiv Tiwari Department of Mechanical Engineering Indian Institute of Technology Guwahati

Fundamentals of noise and Vibration analysis for engineers

Finite element method based analysis and modeling in rotordynamics

EQUIVALENT SINGLE-DEGREE-OF-FREEDOM SYSTEM AND FREE VIBRATION

Dynamics of structures

Program System for Machine Dynamics. Abstract. Version 5.0 November 2017

PART A. CONSTITUTIVE EQUATIONS OF MATERIALS

Advanced Vibrations. Elements of Analytical Dynamics. By: H. Ahmadian Lecture One

The Finite Element Method for Solid and Structural Mechanics

Perturbation of periodic equilibrium

STATICS Chapter 1 Introductory Concepts

ANALYSIS AND IDENTIFICATION IN ROTOR-BEARING SYSTEMS

Nonlinear Problems of Elasticity

Introduction to Ordinary Differential Equations with Mathematica

Study of coupling between bending and torsional vibration of cracked rotor system supported by radial active magnetic bearings

SAMCEF For ROTORS. Chapter 1 : Physical Aspects of rotor dynamics. This document is the property of SAMTECH S.A. MEF A, Page 1

Nonlinear Rolling Element Bearings in MADYN 2000 Version 4.3

NON-LINEAR VIBRATION. DR. Rabinarayan Sethi,

Dynamics of Offshore Structures

Dynamic Analysis of Pelton Turbine and Assembly

Structural Dynamics A Graduate Course in Aerospace Engineering

Structural Dynamics Lecture 2. Outline of Lecture 2. Single-Degree-of-Freedom Systems (cont.)

41514 Dynamics of Machinery

Contents. I Introduction 1. Preface. xiii

METHODS OF THEORETICAL PHYSICS

1820. Selection of torsional vibration damper based on the results of simulation

Use of Full Spectrum Cascade for Rotor Rub Identification

STATICS & DYNAMICS. Engineering Mechanics. Gary L. Gray. Francesco Costanzo. Michael E. Plesha. University of Wisconsin-Madison

An Introduction to the Finite Element Method

vii Preface ix Acknowledgements

Advanced Vibrations. Distributed-Parameter Systems: Exact Solutions (Lecture 10) By: H. Ahmadian

Theoretical Manual Theoretical background to the Strand7 finite element analysis system

Chaotic Vibration and Design Criteria for Machine Systems with Clearance Connections

Table of Contents. Preface...xvii. Part 1. Level

Back Matter Index The McGraw Hill Companies, 2004

T1 T e c h n i c a l S e c t i o n

Chapter 2: Rigid Bar Supported by Two Buckled Struts under Axial, Harmonic, Displacement Excitation..14

Finite element analysis of rotating structures

Dynamics of Machinery

Alfa-Tranzit Co., Ltd offers the new DYNAMICS R4.0 program system for analysis and design of rotor systems of high complexity

Complex modes analysis for powertrain and driveline applications

Effects of Structural Forces on the Dynamic Performance of High Speed Rotating Impellers.

Microstructural Randomness and Scaling in Mechanics of Materials. Martin Ostoja-Starzewski. University of Illinois at Urbana-Champaign

Dr.Vinod Hosur, Professor, Civil Engg.Dept., Gogte Institute of Technology, Belgaum

Dynamic Analysis Contents - 1

METHODS OF ENGINEERING MATHEMATICS

on the figure. Someone has suggested that, in terms of the degrees of freedom x1 and M. Note that if you think the given 1.2

WORK SHEET FOR MEP311

41514 Dynamics of Machinery

Differential Equations

Rotor Dynamics. By Jaafar Alsalaet Department of Mechanical Engineering College of Engineering University of Basrah

Stochastic Dynamics of SDOF Systems (cont.).

DYNAMIC ANALYSIS OF ROTOR-BEARING SYSTEM FOR FLEXIBLE BEARING SUPPORT CONDITION

Dept.of Mechanical Engg, Defence Institute of Advanced Technology, Pune. India

Foundations of Ultraprecision Mechanism Design

Codal Provisions IS 1893 (Part 1) 2002

Introduction to Vibration. Professor Mike Brennan

Boundary Nonlinear Dynamic Analysis

Varuvan Vadivelan. Institute of Technology LAB MANUAL. : 2013 : B.E. MECHANICAL ENGINEERING : III Year / V Semester. Regulation Branch Year & Semester

Influence of friction coefficient on rubbing behavior of oil bearing rotor system

Rotor-dynamics Analysis Process

WEEKS 8-9 Dynamics of Machinery


Dynamics of Rotor Systems with Clearance and Weak Pedestals in Full Contact

COMPUTATIONAL ELASTICITY

Dynamics of Structures

Free vibration analysis of elastically connected multiple-beams with general boundary conditions using improved Fourier series method

Dynamics and control of mechanical systems

Introduction to structural dynamics

Name: Fall 2014 CLOSED BOOK

This equation of motion may be solved either by differential equation method or by graphical method as discussed below:

LANMARK UNIVERSITY OMU-ARAN, KWARA STATE DEPARTMENT OF MECHANICAL ENGINEERING COURSE: MECHANICS OF MACHINE (MCE 322). LECTURER: ENGR.

Study & Analysis of A Cantilever Beam with Non-linear Parameters for Harmonic Response

Dynamic instability of supercritical driveshafts mounted on dissipative supports effect of viscous and hysteretic internal damping

Numerical Sound Synthesis

Elastic Multibody Dynamics

Boundary. DIFFERENTIAL EQUATIONS with Fourier Series and. Value Problems APPLIED PARTIAL. Fifth Edition. Richard Haberman PEARSON

STRUCTURAL DYNAMICS BASICS:

MOOC QP Set 2 Principles of Vibration Control

Tyn Myint-U Lokenath Debnath. Linear Partial Differential Equations for Scientists and Engineers. Fourth Edition. Birkhauser Boston Basel Berlin

Design Procedures For Dynamically Loaded Foundations

Contents as of 12/8/2017. Preface. 1. Overview...1

FINITE ELEMENT ANALYSIS OF A ROTOR SUPPORTED WITH HYDRODYNAMIC JOURNAL BEARINGS

Transcription:

Giancarlo Genta Vibration Dynamics and Control Spri ringer

Contents Series Preface Preface Symbols vii ix xxi Introduction 1 I Dynamics of Linear, Time Invariant, Systems 23 1 Conservative Discrete Vibrating Systems 25 1.1 Oscillator with a single degree of freedom 25 1.2 Systems with many degrees of freedom 28 1.3 Coefficients of influence and compliance matrix 32 1.4 Lagrange equations 32 1.5 Configuration space 40 1.6 State space 41 1.7 Exercises 46 2 Equations in the Time, Frequency, and Laplace Domains 49 2.1 Equations in the time domain 49 2.2 Equations in the frequency domain 50 2.3 Equations in the Laplace domain 54 2.4 Exercises 57

xiv Contents 3 Damped Discrete Vibrating Systems 59 3.1 Linear viscous damping 59 3.2 State-space approach 65 3.3 Rayleigh dissipation function 67 3.4 Structural or hysteretic damping 72 3.5 Non-viscous damping 78 3.6 Structural damping as nonviscous damping 84 3.7 Systems with frequency-dependent parameters 90 3.8 Exercises 92 4 Free Vibration of Conservative Systems 93 4.1 Systems with a single degree of freedom 93 4.2 Systems with many degrees of freedom 97 4.3 Properties of the eigenvectors 99 4.4 Uncoupling of the equations of motion 101 4.5 Modal participation factors 106 4.6 Structural modification Ill 4.7 Exercises 113 5 Free Vibration of Damped Systems 115 5.1 Systems with a single degree of freedomviscous damping 115 5.2 Systems with a single degree of freedom-hysteretic damping 122 5.3 Systems with a single degree of freedom - nonviscous damping 123 5.4 Systems with many degrees of freedom 125 5.5 Uncoupling the equations of motion: space of the configurations 126 5.6 Uncoupling the equations of motion: state space 131 5.7 Exercises 133 6 Forced Response in the Frequency Domain: Conservative Systems 135 6.1 System with a single degree of freedom 135 6.2 System with many degrees of freedom 142 6.3 Modal computation of the response 144 6.4 Coordinate transformation based on Ritz vectors 148 6.5 Response to periodic excitation 151 6.6 Exercises 151 7 Forced Response in the Frequency Domain: Damped Systems 153 7.1 System with a single degree of freedom: steady-state response 153

Contents xv 7.2 System with a single degree of freedom: nonstationary response 160 7.3 System with structural damping 161 7.4 System with many degrees of freedom 163 7.5 Modal computation of the response 165 7.6 Multi-degrees of freedom systems with hysteretic damping 168 7.7 Response to periodic excitation 169 7.8 The dynamic vibration absorber 170 7.9 Parameter identification 175 7.10 Exercises 177 8 Response to Nonperiodic Excitation 179 8.1 Impulse excitation 179 8.2 Step excitation 181 8.3 Duhamel's integral 184 8.4 Solution using the transition matrix 187 8.5 Solution using Laplace transforms 187 8.6 Numerical integration of the equations of motion 189 8.7 Exercises 191 9 Short Account of Random Vibrations 193 9.1 General considerations 193 9.2 Random forcing functions 194 9.3 White noise 197 9.4 Probability distribution 198 9.5 Response of linear systems 199 9.6 Exercises 211 10 Reduction of the Number of Degrees of Freedom 213 10.1 General considerations 213 10.2 Static reduction of conservative models 214 10.3 Guyan reduction 216 10.4 Damped systems 218 10.5 Dynamic reduction 219 10.6 Modal reduction 219 10.7 Component-mode synthesis 220 10.8 Exercises 224 11 Controlled Linear Systems 225 11.1 General considerations 225 11.2 Control systems 227 11.3 Controllability and observability 231 11.4 Open-loop control 232 11.5 Closed-loop control 234 11.6 Basic control laws 237

xvi Contents 11.7 Delayed control 246 11.8 Control laws with frequency-dependent gains 248 11.9 Robustness of the controller 253 11.10 State feedback and state observers 253 11.11 Control design 257 11.12 Modal approach to structural control 259 11.13 Exercises 261 12 Vibration of Beams 263 12.1 Beams and bars 263 12.2 Axial behavior of straight bars 265 12.3 Torsional vibrations of straight beams 279 12.4 Flexural vibrations of straight beams: The Euler-Bernoulli beam 280 12.5 Bending in the yz-pl&ne 305 12.6 Coupling between flexural and torsional vibrations of straight beams 306 12.7 The prismatic homogeneous Timoshenko beam 310 12.8 Interaction between axial forces and flexural vibrations of straight beams 314 12.9 Exercises 318 13 General Continuous Linear Systems 321 13.1 Elastic continuums 321 13.2 Flexural vibration of rectangular plates 324 13.3 Vibration of membranes 329 13.4 Propagation of elastic waves in taut strings 332 13.5 Propagation of sound waves in pipes 335 13.6 Linear continuous systems with structural damping... 337 13.7 Exercises 338 14 Discretization of Continuous Systems 341 14.1 Overview of discretization techniques 341 14.2 The assumed-modes methods 343 14.3 Lumped-parameters methods 349 14.4 Transfer-matrices methods 350 14.5 Holtzer's method for torsional vibrations of shafts 353 14.6 Myklestadt's method for flexural vibrations of beams... 357 14.7 Exercises 360 15 The Finite Element Method 363 15.1 Element characterization 363 15.2 Timoshenko beam element 367 15.3 Mass and spring elements 376 15.4 Plate element: Kirchoff formulation 377 15.5 Plate element: Mindlin formulation 380

Contents xvii 15.6 Brick elements 382 15.7 Isoparametric elements 384 15.8 Some considerations on the consistent mass matrix... 387 15.9 Assembling the structure 388 15.10 Constraining the structure 390 15.11 Dynamic stiffness matrix 393 15.12 Damping matrices 395 15.13 Finite elements in time 396 15.14 Exercises 399 16 Dynamics of Multibody Systems 401 16.1 General considerations 401 16.2 Lagrange equations in terms of pseudo-coordinates 407 16.3 Motion of a rigid body 411 16.4 Exercises 420 17 Vibrating Systems in a Moving Reference Frame 421 17.1 General considerations 421 17.2 Vibrating system on a rigid carrier 426 17.3 Lumped-parameters discretization 430 17.4 Modal discretization 436 17.5 Planar systems 441 17.6 Beam attached to a rigid body: planar dynamics 442 17.7 The rotating beam 445 17.8 Exercises 446 II Dynamics of Nonlinear and time Variant Systems 449 18 Free Motion of Conservative Nonlinear Systems 451 18.1 Linear versus nonlinear systems 451 18.2 Equation of motion 452 18.3 Free oscillations 456 18.4 Direct integration of the equations of motion 458 18.5 Harmonic balance 463 18.6 Ritz averaging technique 466 18.7 Iterative techniques 469 18.8 Perturbation techniques 471 18.9 Solution in the state plane 475 18.10 Exercises 478 19 Forced Response of Conservative Nonlinear Systems 481 19.1 Approximate evaluation of the response to a harmonic forcing function 481 19.2 Undamped Duffing's equation 483

xviii Contents 19.3 Conclusions 496 19.4 Exercises 498 20 Free Motion of Damped Nonlinear Systems 501 20.1 Nonlinear damping 501 20.2 Motion about an equilibrium position (in the small)... 503 20.3 Direct integration of the equation of motion 504 20.4 Equivalent damping 508 20.5 Solution in the state plane 509 20.6 Stability in the small 512 20.7 The Van der Pol oscillator 514 20.8 Exercises 516 21 Forced Response of Damped Nonlinear Systems 519 21.1 Reduction of the size of the problem 519 21.2 First approximation of the response to a harmonic forcing function 521 21.3 Duffing's equation with viscous damping 525 21.4 Duffing's equation with structural damping 528 21.5 Backbone and limit envelope 529 21.6 Multiple Duffing equations 534 21.7 Approximated sub- and super-harmonic response 539 21.8 Van der Pol method: stability of the steady-state solution 541 21.9 Strongly nonlinear systems 545 21.10 Poincare mapping 546 21.11 Chaotic vibrations 550 21.12 Exercises 555 22 Time Variant and Autoparametric Systems 557 22.1 Linear time-variant systems 557 22.2 Hill's equation 559 22.3 Pendulum on a moving support: Mathieu equation... 560 22.4 The elastic pendulum 566 22.5 Autoparametric systems 569 22.6 Exercises 575 III Dynamics of Rotating and Reciprocating Machinery 577 23 Elementary Rot or dynamics: The Jeffcott Rotor 579 23.1 Elementary rotordynamics 579 23.2 Vibrations of rotors: the Campbell diagram 581

Contents xix 23.3 Forced vibrations of rotors: critical speeds 584 23.4 Fields of instability 587 23.5 The undamped linear Jeffcott rotor 590 23.6 Jeffcott rotor with viscous damping 596 23.7 Jeffcott rotor with structural damping 606 23.8 Equations of motion in real coordinates 608 23.9 Stability in the supercritical field 608 23.10 Acceleration through the critical speed 610 23.11 Exercises 614 24 Dynamics of Multi-Degrees-of-Freedom Rotors 615 24.1 Model with 4 degrees of freedom: gyroscopic effect... 615 24.2 Rotors with many degrees of freedom 630 24.3 Real versus complex coordinates 634 24.4 Fixed versus rotating coordinates 636 24.5 State-space equations 637 24.6 Static solution 637 24.7 Critical-speed computation 638 24.8 Unbalance response 639 24.9 Campbell diagram and roots locus 640 24.10 Acceleration of a torsionally stiff rotor 641 24.11 Exercises 645 25 Nonisotropic Rotating Machines 647 25.1 Jeffcott rotor on nonisotropic supports 648 25.2 Nonisotropic Jeffcott rotor 652 25.3 Secondary critical speeds due to rotor weight 656 25.4 Equation of motion for an anisotropic machine 657 25.5 Exercises 670 26 Nonlinear Rotors 671 26.1 General considerations 671 26.2 Nonlinear Jeffcott rotor: equation of motion 672 26.3 Unbalance response 673 26.4 Free circular whirling 676 26.5 Stability of the equilibrium position 678 26.6 Exercises 688 27 Dynamic Problems of Rotating Machines 689 27.1 Rotors on hydrodynamic bearings 689 27.2 Dynamic study of rotors on magnetic bearings 706 27.3 Flexural vibration dampers 723 27.4 Signature of rotating machinery 728 27.5 Exercises 732

xx Contents 28 Rotor Balancing 733 28.1 General considerations 733 28.2 Rigid rotors 734 28.3 Flexible rotors 737 28.4 Exercises 744 29 Torsional Vibration of Crankshafts 745 29.1 Specific problems of reciprocating machines 745 29.2 Equivalent system for the study of torsional vibrations.. 746 29.3 Computation of the natural frequencies 758 29.4 Forced vibrations 762 29.5 Torsional instability of crank mechanisms 784 29.6 Exercises 787 30 Vibration Control in Reciprocating Machines 789 30.1 Dissipative dampers 789 30.2 Damped vibration absorbers 793 30.3 Rotating-pendulum vibration absorbers 796 30.4 Experimental measurement of torsional vibrations 799 30.5 Axial vibration of crankshafts 800 30.6 Short outline on balancing of reciprocating machines... 801 30.7 Exercises 805 A Solution Methods 807 A.l General considerations 807 A.2 Solution of linear sets of equations 808 A.3 Computation of eigenfrequencies 812 A.4 Solution of nonlinear sets of equations 822 A.5 Numerical integration in time of the equation of motion. 824 В Laplace Transform Pairs 831 Index 849

2024 © sciencedocbox.com Privacy Policy | Terms of Service | Feedback