26 Best Books on Rotor Dynamics

“Rotor Dynamics” Book Review: This book represents an expanded and enhanced edition, offering an exploration of the subject matter. It draws upon a compilation of university lectures spanning the past two decades. The book extensively covers the analysis of torsional and bending vibrations in rotors, examining stability aspects, balancing techniques, and condition monitoring. It provides solutions to the presented problems. The application of transfer matrix methods to a broad range of rotor types is thoroughly explored, focusing on both bending and torsional vibrations. The book discusses the systems featuring fluid film bearings, cracked rotors, and two spool rotors, elucidating their operational characteristics. Prior familiarity with vibration theory is recommended to fully understand the content. The book includes numerous practical examples to illustrate key concepts. It also provides insights into diagnosing rotating machinery through vibration signature analysis.

“Analytical Methods in Rotor Dynamics: Second Edition (Mechanisms and Machine Science)” Book Review: This is a comprehensive book that focuses on the analysis of rotating machinery. The authors provide a detailed exploration of various analytical methods used in rotor dynamics, covering topics such as vibration analysis, stability, and critical speeds. The book also delves into the effects of unbalance, gyroscopic forces, and fluid film bearings. With its clear explanations and practical examples, this book is an essential resource for engineers, researchers, and students interested in understanding and analyzing the dynamic behavior of rotating systems.

“Modal Analysis of Rotor Dynamic System Using Time Domain Averaging” Book Review: This book is focused on modal data experiments and introduces the concept of virtual instrumentation as an innovative approach. By leveraging virtual instrumentation, it enables the overcoming of limitations imposed by traditional FFT analyzers. This software-based solution offers a cost-effective alternative to complex and expensive hardware, making it accessible to both engineers and professionals in various fields.

“Rotor Dynamic Analysis of Geared Shaft Systems” Book Review: This is a comprehensive book that focuses on the analysis of rotating machinery with geared shaft systems. The author provides a detailed exploration of rotor dynamics, covering topics such as vibration analysis, bearing dynamics, and gear meshing. The book discusses the effects of various factors on the performance and stability of geared shaft systems. With its clear explanations and practical examples, this book is a valuable resource for engineers, researchers, and students interested in understanding and analyzing the dynamic behavior of geared shaft systems.

“Computational Techniques of Rotor Dynamics with the Finite Element Method (Computational Techniques/Engin)” Book Review: This book explores the applications of the finite element method (FEM) and its utilization in computational techniques and cutting-edge engineering software. It focuses on the analysis of rotational structures, enabling a deeper understanding of the behavior of various machinery types, ranging from generators and wind turbines to airplane engines and propellers. The first section of the book provides a theoretical foundation of rotor dynamics, while the second section discusses the engineering analysis of rotating structures, encompassing modeling, computation techniques, and gyroscopic analysis using FEM. The book also highlights highly efficient and accurate computational and numerical techniques, focusing on the interpretation of computational results and their significance in developing stable rotating machinery. With its practical relevance, this book serves as a valuable resource for practicing engineers and graduate-level students alike.

“Dynamics of Rotors and Foundations” Book Review: This book is organized into four sections. It starts with the basic theory, and then moves on to explain how rotors behave when supported by different bearings. The third section focuses on the dynamics of turbine foundations. It also includes calculations for a turbomachine connected to its foundation. In the fourth section, there is a part dedicated to estimation procedures. The book provides theoretical and practical insights into rotors with transverse cracks. It covers mathematical concepts and provides information about a computer program. This book is intended for engineers and researchers working in the field. It can be useful for manufacturers, operators, university lecturers, and students.

“Fundamentals of Fluid Film Lubrication” Book Review: This book is dedicated to the theory, design, analysis, and practical application of fluid film lubrication. It offers proven methods for reducing friction in components of rotating machinery and introduces the field of tribology. The book covers a wide range of topics, including viscosity and rheology of lubricants, mechanics of lubricants, hydrodynamic lubrication, finite bearings, thermohydrodynamic analysis of fluid film bearings, and their design. It explores important subjects such as the dynamics of fluid film bearings, externally pressurized lubrication, fluid inertia effects and turbulence, gas lubricated bearings, hydrodynamic lubrication of rolling contacts, elastohydrodynamic lubrication, vibration analysis, and thermal effects in rolling-sliding contacts. Throughout the book, readers will find fully worked-out examples, practice problems, and numerous illustrations to enhance their understanding.

“Vibrations of Rotating Machinery (Mathematics for Industry)” Book Review: The book provides an understanding of vibrations in mechanical systems, starting with the analysis of single degree-of-freedom (DOF) systems. It then discusses the vibration analysis of multi-DOF systems using modal analysis techniques. The book covers various topics, including mode synthesis modeling for system reduction, the behavior of complex rotors, rotor balancing methods, the influence of gyroscopic effects on rotordynamics, and the evaluation of rotor-bearing system vibrations through Eigenvalue analysis, considering both forward and backward whirl rotor motions. It explores the rotordynamics associated with rotating shaft vibrations measured in a stationary reference frame, the analysis of blade vibrations utilizing Coriolis forces, the stability characteristics resulting from rotor internal damping, and the instabilities caused by asymmetric shaft stiffness and thermal unbalance.

“Practical Rotordynamics and Fluid Film Bearing Design” Book Review: This book is based on the author’s extensive experience in designing rotor and bearing systems. It covers the fundamental theory, design principles, and guidelines, along with practical examples that can help inexperienced engineers perform design work according to their specific needs. One key focus of this book is to bridge the gap between the knowledge of rotor dynamics and bearing design. The book emphasizes that rotor and bearing systems are interconnected and should be considered together. It covers important aspects such as the positions of critical components, rotor response to excitations, and rotor stability. Additionally, it addresses topics like lubrication, film thickness, power loss, temperature rise, film pressure, and flow rate. The book includes detailed examples and exercises to aid understanding. As a result, engineers working in this field should have knowledge about both rotor dynamics and bearing design.

“Rotordynamics of Gas-Lubricated Journal Bearing Systems (Mechanical Engineering Series)” Book Review: This book discusses the dynamics of gas journal bearings, presenting a mathematical model based on the Reynolds equation. It offers a detailed examination of various aspects, including the identification of stiffness and damping coefficients, mathematical modeling of rotor-gas bearing systems, key characteristics of gas bearings, stability analysis of rotor-gas bearing systems, applications of air rings, and stability considerations in rotor-bearing-air ring systems. The book also covers important topics such as free vibrations, step jump phenomena, harmonic forcing, orbit modeling of gas bearings, equations of motion for symmetrical and unsymmetrical systems, Eigenvalue calculations, bearings with direct and chamber feeding systems, stability of rotors with fixed or elastically mounted bushes in symmetrical systems, stability of unsymmetrical rotors with elastically mounted bushes, air rings with direct and chamber feeding systems, air hammer effects, and the determination of stiffness and damping coefficients for air rings. The content provides in-depth discussions and analysis to facilitate an understanding of gas journal bearings and their dynamics.

“Friction Dynamics: Principles and Applications” Book Review: The primary focus of this book is the friction dynamics of complex systems. It provides an overview of the fundamental concepts and analytical methods related to friction and dynamics. The book covers various topics, including the friction dynamics of vehicle brake systems, friction dynamics in oil drilling and lifting systems, friction dynamics of rotor systems, and fault diagnosis techniques. Designed for upper-level undergraduate and graduate engineering students, the book also explores advanced topics in vibrations and dynamics. With focus on practical applications, the book offers valuable insights into the friction dynamics of vehicle brake systems, oil-well drill strings and sucker rods, as well as the diagnosis of rotor system dynamics.

“Hydrodynamic Lubrication” Book Review: This book serves as an introduction to the field of tribology, focusing on friction, wear, and lubrication. It explores various types of lubrication, including solid friction and hydrodynamic lubrication. The foundational aspects of hydrodynamic lubrication are covered, including Tower’s experiment and Reynolds’ theory, with focus on interpretation. The book discusses the fundamentals of circular, infinitely long, finite length, and short journal bearings, as well as thrust bearings. Topics such as stability of a rotating shaft, oil whip, foil bearings, squeeze film, heat generation, temperature rise, and turbulent lubrication are extensively discussed. The book provides detailed insights into different thrust bearings, including infinitely long plane pad, finite length plane pad, and sector pad bearings. It also examines the influence of pad deformation on magnetic disk memory storage, oil whip theory, stability of multi-bearing systems, magnetic tape memory storage, foil disk, and the basic equations for thermohydrodynamic lubrication.

“Road Vehicle Dynamics: Fundamentals and Modeling (Ground Vehicle Engineering Series)” Book Review: The book primarily focuses on the integration of vehicle dynamics fundamentals and computer-based modeling. It introduces and presents SI units, quantities, terminology, and definitions, along with multibody dynamics and equations of motion. The road is extensively discussed, covering both deterministic and stochastic road models. The book discusses tire handling, including contact calculation, longitudinal and lateral forces, and vertical axis torques. Measurement and modeling techniques, as well as drivetrain components such as transmission, clutch, and power source, are explored. Suspension systems are also explained in detail, including the dynamic model of rack-and-pinion steering, double-wishbone suspension systems, and force elements like springs, anti-roll bars, and hydro-mounts. The book examines vehicle dynamics in the vertical, longitudinal, and lateral directions, using a simplified model approach to analyze the effects of nonlinear, dynamic, and active force elements. A three-dimensional vehicle model and typical results of standard driving maneuvers are included. The book provides end-of-chapter exercises, programming examples, and MATLAB results for practical application.

“Tribology and Dynamics of Engine and Powertrain: Fundamentals, Applications and Future Trends” Book Review: The book discusses the field of tribology, which focuses on the study of friction, wear, and lubrication. It provides an introduction to tribology and dynamics within the context of a multi-physics environment. The book covers a wide range of topics, including the fundamentals of tribology and dynamics, the mechanics and laws of friction and air, surface phenomena in thin-film tribology, the fundamentals of impact dynamics in semi-infinite and layered solids, fluid film lubrication, elastohydrodynamic lubrication, and the measurement of contact pressure under elastohydrodynamic lubrication conditions. The book explores engine and powertrain technologies and applications, examining the tribology of piston systems, valve train systems, engine bearings, drivetrain systems, as well as micro-systems and nano-conjunctions. Throughout the book, illustrations, examples, and end-of-chapter exercises are provided to enhance understanding and application.

“Structural Dynamics in Industry (ISTE)” Book Review: The book explores the field of structural dynamics, focusing on the response and behavior of structures when exposed to vibrations or shocks. It takes a systematic approach to explain the fundamental concepts, enabling the treatment of industrial structures in a generalized manner. The concepts are explained using examples and a minimal mathematical approach, before transitioning to real-life cases directly derived from industry.

“Smart Helicopter Rotors: Optimization and Piezoelectric Vibration Control (Advances in Industrial Control)” Book Review: This book focuses on optimizing and controlling vibrations using piezoelectric materials, specifically in rotor-forefront actuators. It explores how these materials can reduce vibrations in helicopter rotors, providing a smoother ride comparable to steam-powered fixed-wing aircraft. The authors introduce tracking edge folds and dynamic bending concepts to control vibrations. They discuss different tracking edge fold designs for full-authority control of dual after-edge actuators. The book addresses hysteresis nonlinearity in piezoelectric stack actuators using a novel computation method. It also explores the use of piezoelectric-induced shear stimulation for reducing vibrations in rotating blades. The significance of dynamic bending in mitigating vibrations caused by abrupt stoppages is emphasized. The principles, materials, and computations involved are thoroughly explained, supported by numerical simulations. This book is a valuable reference for professionals and researchers in aerospace, mechanical, and electrical engineering, particularly those interested in smart materials and vibration control. It is part of the Advances in Industrial Control series, which aims to share advancements in control engineering across various domains.

“Advances in Transitional Flow Modeling: Applications to Helicopter Rotors (SpringerBriefs in Applied Sciences and Technology)” by Chunhua Sheng Book Review: This book provides a description of mathematical techniques and validation procedures for predicting transitional flows using the Langtry-Menter local correlation-based transition model, integrated with both the one-equation Spalart-Allmaras (S-A) and two-equation Shear Stress Transport (SST) turbulence models. A comparative study is presented to combine the respective advantages of the two coupling methods in predicting the boundary layer transition phenomenon, ranging from fundamental benchmark flows to practical helicopter rotors. The book will be valuable for mechanical engineers involved in aerodynamic design and analysis of fixed-wing or rotary-wing aircraft, while also serving as advanced reading material for graduate students in the research areas of Computational Fluid Dynamics (CFD), turbulence modeling, and related fields.

“Nonlinear Dynamics of Rotor Bearing System in Automotive Turbochargers” by Tian Liang and Wang Weiji Book Review: This is a specialized book that delves into the complex dynamics of rotor bearing systems in automotive turbochargers. The authors provide a comprehensive analysis of the nonlinear behavior of turbocharger systems, exploring topics such as vibration, instability, and rotor-bearing interactions. The book covers various aspects of turbocharger design and performance, offering insights into the challenges and solutions in optimizing their operation. This book is a valuable resource for researchers and engineers working in the field of automotive engineering and turbocharger design.

“Introduction to Dynamics of Rotor-bearing Systems” by Wen Jeng Chen and Edgar J Gunter Book Review: This is introductory book that explores the fundamental principles and dynamics of rotor-bearing systems. The authors provide a clear and accessible overview of the key concepts, including vibration analysis, rotor dynamics, and bearing design. The book covers various topics such as modeling techniques, stability analysis, and rotor imbalance. It also discusses practical applications and case studies. With its easy-to-understand explanations and illustrative examples, this book serves as an excellent resource for students and engineers seeking to understand and analyze the dynamics of rotor-bearing systems.

“Dynamics of Rotor-bearing Systems” by M J Goodwin Book Review: The objective of this book is to provide an up-to-date review of rotor dynamics, covering both fundamental topics and specialized subjects that are typically found in journal articles. In Part I, the book focuses on classical topics in rotor dynamics, including the dynamic behavior of linear, steady-state rotating machines, as well as simple models and systems derived from finite element models. Part II, advanced rotor dynamics, delves into specific topics related to rotors, bearings, disks, and blades.

“Rotordynamics of Automotive Turbochargers: Linear and Nonlinear Rotordynamics – Bearing Design – Rotor Balancing” by Hung Nguyen-Schäfer Book Review: This book explores the field of rotordynamics specifically focusing on automotive turbochargers, with focus on the analysis of rotating machinery dynamics at extremely high rotor speeds of 300,000 rpm or more. This interdisciplinary field discusses several aspects, including thermodynamics and supermatching data to determine turbocharger operating conditions, fluid and bearing dynamics to calculate various operating thrust loads and design the floating ring bearings (two-oil-film bearings), and tribology to enhance rotor stability and reduce bearing friction. While a numerical background in modeling and simulation methods is beneficial, the book presents the fundamentals in a concise manner. It is intended for professionals working in the field of automotive turbocharger rotordynamics as well as graduate students in mechanical engineering.

“Proceedings of the 9th IFToMM International Conference on Rotor Dynamics (Mechanisms and Machine Science)” by Paolo Pennacchi Book Review: This book showcases the proceedings of the ninth IFToMM International Conference on Rotor Dynamics, a prestigious global event that brings together experts from academia and industry worldwide to foster the exchange of knowledge, ideas, and information on the latest advancements and applied technologies in the field of rotating machinery dynamics. The coverage is diverse, focusing on topics such as innovative approaches and emerging trends in bearing technologies, advanced analysis of dynamic behavior, condition monitoring of various rotating machines, vibration control, electromechanical and fluid-structure interactions in rotating equipment, rotor dynamics of micro, nano, and cryogenic machines, and applications of rotor dynamics in transportation engineering. With a history spanning 32 years, the IFToMM International Conference on Rotor Dynamics has become a pivotal platform for professionals in the field, and this book reflects the high-quality and diversity of content that the conference continues to deliver.

“Magnetic Bearings: Theory, Design, and Application to Rotating Machinery” by R Larsonneur and P Keogh Book Review: This book is a comprehensive guide that delves into the principles, design, and practical applications of magnetic bearings in rotating machinery. The authors cover a range of topics, including the theory behind magnetic bearings, their design considerations, and their application in various industries. The book explores topics such as magnetic forces, stability analysis, control strategies, and fault diagnosis. With its clear explanations and practical insights, this book serves as an invaluable resource for engineers and researchers working with magnetic bearings in the field of rotating machinery.