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1. List of contributors

Author

D.R. Cornell, M. Deckers, Y. Enomoto, N. Funahashi, M. Haraguchi, S. Hecker, A. Kaliwoda, Yasutomo Kaneko, Hiroshi Kanki, Rimpei Kawashita, Ivan McBean, T. Nakata, K. Nishimura, H. Nomoto, A. Ohji, Masato Ohta, N. Okita, L. Paulukuhn, Paolo Pennacchi, Y. Sakai, S. Senoo, Raub W. Smith, Y. Takagi, T. Takahashi, Akinori Tani, T. Tanuma, J. Tominaga, and A.J. White

Published
2022
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2. Vibration in Magnetic Bearing Rotor Systems

Author

Hiroshi Kanki, Osami Matsushita, Patrick Keogh, Masato Tanaka, and Masao Kobayashi

Subjects
Engineering, Electromagnet, Rotor (electric), business.industry, Vibration control, Magnetic bearing, Mechanical engineering, law.invention, Vibration, Magnetic circuit, law, Digital control, business, Magnetic levitation
Abstract

In contrast to conventional rolling element and oil film bearings, magnetic bearings have had a relatively short history. The practical implementation of active magnetic bearings using electromagnets has been accelerated and driven recently by the development of digital control technology. Since 1988, the International Symposium on Magnetic Bearings (ISMB) series has been convened every two years and has been leading the studies in this field. In the industrial sector, the ISO TC108/SC2/WG7 “Working Group on Active Magnetic Bearings” started its activities in 1997 to develop standards to promote the adoption of rotating machinery with active magnetic bearings and to support the steady and smooth advancement of associated industries. The standards have been released as the ISO 14839 series. This chapter describes the basic specifications of magnetic bearings, along with the related vibration control technologies.

Published
2019
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3. Basics of Plain Bearings

Author

Masato Tanaka, Patrick Keogh, Hiroshi Kanki, Osami Matsushita, and Masao Kobayashi

Subjects
Vibration, Materials science, Bearing (mechanical), Reaction, Rotor (electric), law, Fluid bearing, Mechanics, Sommerfeld number, Rotation, Plain bearing, law.invention
Abstract

Oil-lubricated plain bearings are used widely to support the main rotors of rotating machinery, because the hydrodynamic oil films formed in the bearing clearances can guarantee smooth rotation of shafts and effectively prevent or suppress rotor vibrations. This chapter explains the principles of oil film formation in typical plain bearings, based on conventional hydrodynamic lubrication theory. The circumferential oil film shape at the steady-state equilibrium is determined, so that the hydrodynamic pressure generated in the oil film can balance the oil film reaction force vectorially with the applied bearing load. In other words, the oil film separates the journal from the bearing surface and the journal can float and rotate on the oil film. The oil film shape determines the journal center position represented by the journal eccentricity ratio and the attitude angle in polar coordinates. The steady-state journal center position and in turn the corresponding oil film shape vary with the operating condition of the journal bearing, that is, Sommerfeld number. When the journal center is slightly perturbed at the equilibrium, the oil film is slightly deformed, resulting in the slightly modified pressure distribution. Then, the corresponding oil film force is found to consist of the static reaction force at the equilibrium and also the two mutually perpendicular components of the small dynamic reaction force. Each of the two components is expressed by the linear sum of the two stiffness components and also the two damping components. In total, four stiffness components and four damping coefficients are determined at the equilibrium. These coefficients are the key factors that dominate the vibrational behavior of the rotor supported in the plain bearings. The coefficients obtained for various types of journal bearing are found to vary with the Sommerfeld number. Consequently, journal bearings need to be selected and designed so that the dynamic coefficients of the hydrodynamic oil films can enable satisfactory control of rotor vibration.

Published
2019
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5. Exercises of ISO Certification Examination for Vibration Experts

Author

Masao Kobayashi, Hiroshi Kanki, Osami Matsushita, Patrick Keogh, and Masato Tanaka

Subjects
Mathematics education, Certification, Troubleshooting, Apprenticeship, Know-how, Engineering mathematics, Field (computer science), Multiple choice, Test (assessment)
Abstract

According to ISO 18436-2, entitled “Condition monitoring and diagnostics of machines—Requirements for training and certification of personnel—Part 2: Vibration condition monitoring and diagnostics,” the introduction of the certification examination for vibration experts is mentioned. The certification level is divided into four categories: 1—for beginners; 2—for elemental experts (apprentices); 3—for advanced experts; and 4—for super-experts. This chapter, including 100 questions, is prepared for ambitious experts challenging categories 3, 4, and higher. Every question requires knowledge strongly related to basic engineering mathematics, practical signal processing, vibrational dynamics theory, standard modal analysis, model order reduction, and so forth. It excludes knowledge gained purely from experience. If you are students, it is a good opportunity to know how to apply undergraduate knowledge to the field. If you are vibration consultants, apply these simple and understandable modeling techniques in troubleshooting for your customers. Based on the experience of one of the authors as a JSME (Japan) examiner, he found that questions of the examination are divided approximately into two groups. The first group includes questions related to knowledge of field experience in the maintenance service, for example, permissible vibration levels decided by API and/or ISO standards, how to measure and report vibration data, and so on. The second group involves questions concerning mathematics and dynamics, for example, rotor balancing, the FFT algorithm, modal analysis, applying complex numbers. Many examinees may have difficulty to recall and manage the theoretical background for questions if they graduated some time ago. A total of 100 questions have been selected, specifically to enrich an expert’s understanding of the mathematics and dynamics for them. The following advises the reader on how to use this chapter: (1) Questions 1–30: The first 30 are multiple choice questions with five options. It is in the same style as the certification exam; hence, examinees can check their level. The actual exam contains 100 questions in a 4–5 h period. Therefore, it is recommended that you complete these 30 questions within 60 min. Finally, check your answers with the correct answers in Table Q30, located in Sect. 12.1. (2) Questions 31–100: The aim of these questions is to sharpen examinees’ thinking, so the questions may be slightly beyond their knowledge. On average, the difficulty of these questions is almost equivalent to vibration category level 3 and 4; some may be near category 4 and higher. Do not be afraid to try these questions to test your knowledge. From Question 31 onwards, the content is divided into two ways: Questions stated in Sect. 12.2 with answers and hints associated with each question in Sect. 12.3. Please try these exercises, which challenge readers to become world-leading experts in the rotor dynamic vibration field.

Published
2019
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6. An Overview of Vibration Problems in Rotating Machinery

Author

Masato Tanaka, Hiroshi Kanki, Osami Matsushita, Masao Kobayashi, and Patrick Keogh

Subjects
Vibration, Noise, Computer science, Condition monitoring, Control engineering, Iso standards, Field (computer science)
Abstract

This book aims to explain various phenomena and mechanisms of vibrations in rotating machinery based on theory and field experiences. It also aims to help engineers in carrying out diagnosis and in implementing countermeasures for various vibration problems in the field. It is normally easy to know the condition of machinery by means of measurement of vibrations and/or noise. However, it is rather difficult to interpret the observed phenomena correctly, derive real causes of the problems, and ascertain effective countermeasures, because a sufficient knowledge of case studies is needed. This chapter provides an overview of vibration problems in rotating machinery and general approaches for the countermeasures, and is intended to be helpful in solving vibration problems at the front line. Condition monitoring of a machine and vibration diagnostics including relevant ISO standards are illustrated. Case studies of vibration problems and the countermeasures in excess of 1000 cases, which have been collected until now by the Vibration Database (v_BASE) Committee under the Japan Society of Mechanical Engineers (JSME), are also referred to in this chapter.

Published
2019
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7. Stability of a Rotor in Plain Bearings

Author

Patrick Keogh, Masao Kobayashi, Masato Tanaka, Hiroshi Kanki, and Osami Matsushita

Subjects
Physics::Fluid Dynamics, Vibration, Physics, Mechanical equilibrium, Bearing (mechanical), Rotor (electric), law, Bending stiffness, Characteristic equation, Mechanics, Plain bearing, Rotation, law.invention
Abstract

This chapter explains the self-excited nature of vibration of a rotor caused by the destabilizing oil film force (oil whip or oil whirl); another self-excited vibration of a rotor caused by the destabilizing fluid force in seals and impellers (flow-excited vibration); and how to prevent the vibrations effectively by selecting appropriate specifications of plain bearings. Both of the unstable vibrations show two-dimensional whirl orbits of the rotor around the steady-state equilibrium position in the shaft rotating plane. The dominant component of the shaft whirl orbit is found to be the forward one, that is, orbiting in the same direction as the shaft rotation. The orbit size is sometimes enlarged when bending deformation of the rotating flexible shaft is added. In contrast with the unbalance vibration explained in Chap. 3, the whirl frequencies of the unstable vibrations are generally lower than the shaft rotating frequency, that is, subsynchronous, close to the natural frequency of the rotor-bearing system. These self-excited vibrations break out when the rotor-bearing systems exceed stability limits. When a linear vibration analysis is applied to the rotor-bearing system, the characteristic equation is derived in the form of an algebraic polynomial equation of the sixth degree from the equations of motion. When the Routh–Hurwitz criterion is applied to the characteristic equation, the stability limit of shaft speed can be obtained in the form of mathematical expression consisting of the rotordynamic coefficients of bearing oil film and the bending stiffness variable of shaft. The stability limit can be also found by means of eigenvalue analysis applied to the characteristic equation. In other words, when all the real parts of the eigenvalues have negative values for the given operating condition, the rotor-bearing system can remain stable. When at least one real part has a positive value, the system becomes unstable, starting oil whirl or oil whip. The effects of operating conditions and journal bearing configurations are demonstrated, and various effective countermeasures are derived. The flow-excited vibrations of a rotor by non-contact seals are characterized by dependence on load, because, with increase in load, the working fluid increases in pressure and flow rate, strengthening the destabilizing force (cross-coupled stiffness force) of the fluid flow. The magnitude of the destabilizing force is strongly dependent on the swirl velocity of the fluid in the direction of shaft rotation at the seal inlet. Consequently, one of the effective countermeasures against seal flow-excited vibration is to support the rotor by anisotropic bearings having oil film forces that give rise to elliptical whirl orbits. This is because the backward whirl component of the elliptical whirl orbit reduces the effect of the destabilizing seal force.

Published
2019
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8. Unbalance Vibration of a Rotor in Plain Bearings

Author

Hiroshi Kanki, Patrick Keogh, Osami Matsushita, Masato Tanaka, and Masao Kobayashi

Subjects
Physics, Bearing (mechanical), Rotor (electric), business.industry, Plane (geometry), Equations of motion, Structural engineering, Displacement (vector), law.invention, Vibration, Physics::Popular Physics, law, Orbit (dynamics), Physics::Chemical Physics, Plain bearing, business
Abstract

Oil-lubricated plain bearings used widely for large-sized rotating machinery can effectively suppress unbalance vibration amplitude of a rotor. This chapter outlines the nature of unbalance vibration amplitude of a rotor supported in plain bearings. The mathematical expression of unbalance vibration of a rotor is given in the rotating plane of the shaft. The two equations of motion given in the x–y-plane are converted into a single equation of motion derived with the complex expression of the displacement of the rotor. Then, the rotor is found to make an elliptical whirl orbit with major and minor axes around its equilibrium. The eight rotordynamic coefficients of a bearing oil film can be converted into the four effective coefficients expressed with the two coordinates of the major and minor axes. The vibration response and the whirl orbit are calculated and shown with varying shaft speed. The effects of bearing type and design variables on the unbalance vibration response are also calculated and compared. Furthermore, the effect of bearing pedestal characteristics on the unbalance vibration response is shown. Finally, it is shown how rotor-bearing systems can be designed to reduce the maximum amplitude of unbalance vibration when passing critical speeds.

Published
2019
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9. Our Latest Topics Relating to Simplified Modeling of Rotating Systems

Author

Masao Kobayashi, Patrick Keogh, Hiroshi Kanki, Osami Matsushita, and Masato Tanaka

Subjects
Model order reduction, Bearing (mechanical), Computer science, business.industry, Rotor (electric), Mode (statistics), Structural engineering, Bending, Instability, law.invention, Vibration, law, business, Eigenvalues and eigenvectors
Abstract

This chapter is divided into three parts, which include our latest areas of interest. (1) Guyan reduction or mode synthesis: With respect to vibration analysis for actual machines, many types of codes, 3D-FEM and 1D-FEM (e.g., MyROT introduced in R1_Chap. 12), are available for engineering design based upon multi-DOF (degree of freedom) modeling. However, case studies of vibration problems show the benefits for understanding the vibration mechanisms and their practical and potential solutions using simplified models. In this book, Guyan reduction and the mode synthesis technique are strongly recommended for this purpose. (2) System instability in oil film bearing rotors: This model order reduction (MOR) is applied to a flexible rotor supported by oil film bearings to analyze system instability, often referred to as oil whip, oil whirl, and casing whirl. Stability analysis is generally performed by using complex eigenvalue codes in the 1D-FEM modeling. However, this chapter yields an alternative way without complex eigenvalue calculation, i.e., how to predict the limiting speed for stability and the resultant unstable frequency. (3) Blade modeling coupled with shaft vibration: The MOR by the mode synthesis technique is applied to a flexible blading system to analyze the vibration coupled with the rotating shafting system. Uncoupled eigen frequencies and modes may be analyzed initially for the rotating blading system only by a 3D-FEM code, based upon the rotating coordinates. As the result, the corresponding 2-DOF models for each eigen mode of blading are proposed by two methods depending upon the number of the nodal diameter, κ = 0 and κ = 1. The former is coupled with torsional and axial shaft vibration models and the latter with bending (lateral) shaft vibration models, respectively. These blade reduced models are combined into shaft vibration data by a 1D-FEM code for the evaluation of the coupling effect. The effectiveness of these procedures is confirmed by numerical examples.

Published
2019
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10. Case Studies of Self-excited Vibration of Rotor Stability Problems

Author

Masao Kobayashi, Hiroshi Kanki, Osami Matsushita, Masato Tanaka, and Patrick Keogh

Subjects
Physics, Vibration, Impeller, Bearing (mechanical), Axial compressor, Stator, law, Rotor (electric), Rotational speed, Natural frequency, Mechanics, Physics::Chemical Physics, law.invention
Abstract

Frequencies associated with self-excited vibrations are, in most cases, the natural frequencies of the system. The natural frequencies are not proportional to the rotational speed. Therefore, self-excited vibration is a form of non-synchronous vibration. In rotor systems, the lowest natural frequency is often below the rated rotational speed and it may become unstable, hence self-excited vibration is also known as sub-synchronous vibration. This chapter describes various case studies of self-excited vibrations, which are inherent in rotating machinery, as for a journal bearing, seal, centrifugal impeller, and blade for an axial flow machine. Also, the phenomena of internal friction, fluid trapped in a rotor, and rotor contacting with a stator, may produce strong self-excited vibration. While illustrating these unstable phenomena, the cause or mechanism of the instabilities and appropriate solutions are discussed by citing the v_BASE data. In addition, squeeze film dampers, which are used to stabilize the system by adding a damping effect, are explained.

Published
2019
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11. Case Studies of Forced Vibration Problems of a Rotor

Author

Hiroshi Kanki, Masato Tanaka, Patrick Keogh, Osami Matsushita, and Masao Kobayashi

Subjects
Universal joint, Forcing (recursion theory), business.product_category, Torsional vibration, Computer science, Mechanical engineering, Pulley, law.invention, Vibration, Impeller, law, Vibration response, Fluid dynamics, business
Abstract

The major problem in forced vibration response is resonance, where the frequencies of exciting forces coincide with the natural frequencies. Rotating machinery has different characteristics in resonance problems from general non-rotating structures. Therefore, the problems need be solved with this knowledge in mind, not only at the design stage, but also on-site. In the case of forced vibration, centrifugal forcing due to unbalance is a very typical example; however, various other external forces produced by different mechanisms may also become problematic and be experienced routinely. Examples include mechanically induced forces in gears, cross joints, and pulley belt systems; an electromagnetic force in a motor/generator; and rotating stall and impeller/blade interaction forces, which are induced by the fluid flow. Furthermore, torsional vibration is inevitable for rotating machinery and may become a large problem. In this chapter, these phenomena and appropriate countermeasures to implement are elucidated while referring to previously mentioned examples.

Published
2019
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12. Signal Processing for Rotor Vibration Diagnosis

Author

Masao Kobayashi, Masato Tanaka, Patrick Keogh, Hiroshi Kanki, and Osami Matsushita

Subjects
Vibration, Spectrum analyzer, Signal processing, Computer science, Frequency domain, Acoustics, Fast Fourier transform, Physics::Atomic and Molecular Clusters, Waveform, Time domain, Filter (signal processing), Physics::Chemical Physics
Abstract

In the vibration diagnosis of rotating machines, the first attention is the evaluation of the unbalance vibration, i.e., the rotational synchronous point of vibration, noted as “1X” or “1N” vibration. A vector monitor (R1_Fig. 5.8) is a measuring instrument including a tracking filter that extracts only the 1X vibration component from the actual vibration waveform. In this chapter, the principle and the application of this vector monitor are explained. In the following, attention is given to the transformation from the waveforms in the time domain to amplitude (spectrum) in the frequency domain by using a FFT analyzer. We learn about the theory of signal processing related to FFT analysis, which is capable of providing numerous displays for easy understanding and effective diagnosis for vibration troubleshooting.

Published
2019
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13. Vibration of Rolling Element Bearings

Author

Masao Kobayashi, Masato Tanaka, Patrick Keogh, Hiroshi Kanki, and Osami Matsushita

Subjects
Materials science, Bearing (mechanical), business.industry, Structural engineering, Interchangeability, Sizing, law.invention, Vibration, Rolling-element bearing, law, Ball (bearing), Envelope (mathematics), business, Groove (engineering)
Abstract

Rolling element bearings are used widely in rotating machinery. A significant variety of rolling element bearing types is available, and they are categorized by the shape of the ball or roller elements; the radial or axial loading direction; the ball type such as deep groove or angular contact; the roller type such as plain or tapered; etc. As most of them are standardized in ISO/JIS, interchangeability is guaranteed. This chapter introduces the dynamic properties of some rolling bearings, but does not make any reference to the static properties given in bearing manufacturers’ catalogues, such as load capacity, sizing, life estimation, and so on.

Published
2019
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14. Vibration Analysis of Blade and Impeller Systems

Author

Masao Kobayashi, Osami Matsushita, Masato Tanaka, Patrick Keogh, and Hiroshi Kanki

Subjects
Physics::Fluid Dynamics, Vibration, Physics, Impeller, Normal mode, Rotor (electric), law, Coordinate system, Mechanics, Gas compressor, Slip factor, Finite element method, law.invention
Abstract

This chapter discusses vibrations of rotating structures such as blades in turbines and impellers in pumps or compressors. The natural frequencies of a rotating structure may be analyzed using the 3-D finite element method and classified by the number of the nodal diameters or circular nodal modes. These results are represented in the rotational coordinate system. The difference between the inertial coordinate system fixed to the stationary side and the rotational coordinate system fixed with the rotor must be taken into account in analysis of: (1) resonance caused by any static load distributed in the circumference direction of the stationary side facing blades or impellers, and (2) resonance caused by harmonic excitation at a certain point in the stationary side facing blades or impellers.

Published
2017
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15. Rotor Vibration Analysis Program: MyROT

Author

Osami Matsushita, Patrick Keogh, Masato Tanaka, Masao Kobayashi, and Hiroshi Kanki

Subjects
Discretization, business.industry, Computer science, Rotor (electric), Stiffness, Structural engineering, Rotordynamics, Finite element method, law.invention, Vibration, law, medicine, medicine.symptom, business, Beam (structure), Eigenvalues and eigenvectors
Abstract

This chapter describes MyROT, a versatile software package for the rotor vibration analysis of rotating machinery. The calculation is based on a combination of beam elements according to finite element modeling , termed 1D-FEM, which is discretized by defining the mass, stiffness and damping matrices according to the actual geometry of the rotating shaft. These matrices are applied to calculations of natural frequencies, complex eigenvalues for stability analysis, unbalance vibration by frequency response analysis (FRA) and so on. Specifically, this chapter describes the theoretical background for formulation and presents outputs of typical rotor dynamic calculations in order to show how this program is convenient in analyzing rotordynamics. A trial version of the package is available at http://www.nda.ac.jp/cc/mech/member/osami.html. An input data manual and other documents related to the package may also be downloaded from the site.

Published
2017
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16. Stability Problems in Rotor Systems

Author

Osami Matsushita, Hiroshi Kanki, Masao Kobayashi, Masato Tanaka, and Patrick Keogh

Subjects
Steady state (electronics), Rotor (electric), Computer science, Stiffness, Rotation, law.invention, Rubbing, Mechanism (engineering), Vibration, Control theory, law, medicine, Nyquist plot, medicine.symptom
Abstract

This chapter discusses three typical topics of rotor dynamics problems: internal/external damping effects, vibration due to non-symmetrical shaft stiffness and thermal unbalance behavior. Though a rotor should rotate in a stable manner in a rotation test, problems are encountered in some cases. Most of the problems are related to unbalance, against which the countermeasure is balancing. However, more serious problems may occur that cannot be solved by balancing. In such cases other solutions must be sought. This chapter discusses the following three problems that may be encountered: (1) Internal damping: Loose fittings on the shaft cause damping due to sliding friction. It might seem that any damping is welcome, but this type of damping is rather a destabilizing factor at high speeds of rotation. (2) Asymmetric section of the rotor: Asymmetry in shaft stiffness, e.g. due to a key slot on the shaft often generates troublesome vibration. (3) Vibration due to thermal bow: The unbalance vibration vector of a rotor can be monitored during operation by a Nyquist plot. While the vector point normally remains unchanged during steady state operation, thermal deformation of the rotor, e.g., due to rubbing will move it. The mechanism of this phenomenon is described. For simplicity, a single-degree-of-freedom model is used in the following discussion.

Published
2017
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17. Basics for a Single-Degree-of-Freedom Rotor

Author

Patrick Keogh, Masao Kobayashi, Osami Matsushita, Masato Tanaka, and Hiroshi Kanki

Subjects
Physics, Vibration, Damping ratio, Modal, Rotor (electric), law, Bode plot, Mathematical analysis, Equivalent weight, Resonance, Natural frequency, law.invention
Abstract

This chapter specifies the definitions, calculation and measurement of basic vibration properties: natural frequency, modal damping, resonance and Q-value ( Q-factor).

Published
2017
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18. Modal Analysis of Multi-Degree-of-Freedom Systems

Author

Masao Kobayashi, Osami Matsushita, Patrick Keogh, Masato Tanaka, and Hiroshi Kanki

Subjects
Computer Science::Robotics, Vibration, Damping ratio, Orthogonality, Normal mode, Rotor (electric), law, Modal analysis, Mathematical analysis, Natural frequency, Eigenvalues and eigenvectors, Mathematics, law.invention
Abstract

The preceding chapter dealt with the basics of rotor vibrations concerning a single-degree-of-freedom (single-dof, 1-dof) system. An actual machine should, however, be analyzed as a multi-degree-of-freedom (multi-dof) system where multiple masses are arranged according to the shape of the rotor shafting. The equation of motion for such a system is represented using matrices. Eigenvalue analysis of the multi-dof system gives the natural frequencies and eigenmodes. These are important factors in rotor design because they represent the resonance frequencies and the vibration mode shapes at critical speeds. This chapter also discusses modal analysis, in which a multi-dof system is reduced to an assemblage of single-dof systems utilizing the orthogonal condition of the eigenmodes. In other words, a complicated actual system is simplified to a set of simple 1-dof systems corresponding to each mode. In addition, a simple estimation method of the natural frequency and the damping ratio is presented based on the orthogonality condition.

Published
2017
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19. Mode Synthesis and Quasi-modal Method

Author

Masao Kobayashi, Hiroshi Kanki, Patrick Keogh, Osami Matsushita, and Masato Tanaka

Subjects
Modal, Computer science, Deflection (engineering), Modal analysis, Diagonal, Mode (statistics), Topology, Mass matrix, Transfer function, Modal method
Abstract

Modal analysis consists of superposing eigenmodes ϕ i , weighted according to the modal coordinates η i, through all modes. The modal coordinates no longer have the representation of the original physical coordinates. This chapter discusses methods to reduce the order of the system while preserving the physical coordinates as far as possible. One such method is based on Guyan reduction, in which only the “relatively important” nodes are chosen out of numerous nodes in a finely meshed model. The static deflection modes are developed to reduce the system matrices. The reduced system consists of the physical coordinates of the chosen nodes. Mode synthesis is another method. Here the “most important” nodes are treated with the Guyan reduction method, while the other nodes are considered as internal to the system and undergo modal analysis. Mode synthesis gives a model containing both physical and modal coordinates. Since, however, the mass matrix of this model is not diagonal, no equivalent model of the multiple mass system can be derived. The quasi-modal method is a solution that gives a physical model equivalent to the reduced model obtained by mode synthesis. A convenient model providing an appropriate physical meaning is obtained. In addition, a procedure will be presented in which the response of a bearing journal to a force acting on the rotor is created by the mode synthesis model as a plant transfer function.

Published
2017
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20. Approximate Evaluation for Eigenvalues of Rotor-Bearing Systems

Author

Patrick Keogh, Masao Kobayashi, Osami Matsushita, Masato Tanaka, and Hiroshi Kanki

Subjects
Vibration, Matrix differential equation, Bearing (mechanical), Rotor (electric), law, Mathematical analysis, Equations of motion, Natural frequency, Displacement (vector), Eigenvalues and eigenvectors, Mathematics, law.invention
Abstract

This chapter discusses an approximate evaluation method to consider the effects of the dynamic characteristics of a bearing on the complex eigenvalues (damping characteristics as the real part and damped natural frequency as the imaginary part). The method consists basically of two steps: (1) System reduction down to a single-dof system is executed based on the orthogonality condition of modes in the conservative system, and the equation of motion of reduced system is expressed in the complex displacement form, and (2) Approximate analysis of the complex eigenvalues of the system is used to ascertain the effects of the bearing parameters on the natural frequencies and damping characteristics. This combination provides a simple model that helps understanding the phenomena of practical interest, such as the effects of the cross-stiffness of the bearing on the system instability or the stabilizing effect of anisotropy in the bearing stiffness. In addition, the shapes of resonance curves in unbalance vibration are discussed in relation to the dynamic characteristics of the bearing.

Published
2017
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22. Bridge Between Inertial and Rotational Coordinate Systems

Author

Hiroshi Kanki, Masato Tanaka, Masao Kobayashi, Osami Matsushita, and Patrick Keogh

Subjects
Vibration, Physics, Inertial frame of reference, Coordinate system, Mathematical analysis, Equations of motion, Rotational speed, Lambda, Eigenvalues and eigenvectors, Displacement (vector)
Abstract

This chapter discusses a bridge for the knowledge with respect to the rotor-shaft vibration defined in an inertial coordinate system and the rotating structure vibration formulated in a rotating coordinate system. The equations of motion for rotor vibration discussed hitherto have been based on the description concerning the absolute complex displacement z = x + jy measured in an inertial (fixed, stationary) coordinate system. This description is requested from a practical viewpoint, because the vibrations measurement corresponds to displacement sensors (or gap sensors, displacement meters) placed on a stationary part of machine. Alternatively, this vibration can be measured by strain gauges fixed at a rotational coordinate system, as written by the displacement z r . These variables are mutually related by: \( z = z_{r} {\text{e}}^{{j\Omega t}} \) (Ω = rotational speed) Therefore, if an eigenvalue is λ in the inertial coordinate system and \( \lambda_{r} \) in the rotational coordinate system, these entities are mutually related by: $$ \lambda = \lambda_{r} + j\Omega $$ This chapter moves the viewpoint concerning vibration measurement from z to z r .

Published
2017
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23. Gyroscopic Effect on Rotor Vibrations

Author

Patrick Keogh, Masao Kobayashi, Masato Tanaka, Hiroshi Kanki, and Osami Matsushita

Subjects
Vibration, Physics, law, Rotor (electric), Gyroscope, Natural frequency, Rotational speed, Mechanics, Helicopter rotor, Rotordynamics, Rotation, law.invention
Abstract

This chapter discusses the gyroscopic effect characterizing rotordynamics as being different from the structural dynamics, associated with the non-rotating parts of the rotor system, such as the casing and foundation. A top spinning at a high speed whirls slowly in a tilted position. Similarly, a rotor of a rotating machine whirls while rotating around the driven shaft axis. The spinning top does not fall due to a moment, generated by the gyroscopic effect, which is proportional to the rotational speed. This gyroscopic effect of a rotor system appears as the self-centering tendency during rotation, which may be considered as an increase in the centering stiffness. It is absolutely essential to understand the influence of the gyroscopic effect on the natural frequency and the resonances in the frequency response in rotating machinery vibrations.

Published
2017
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24. Rotor System Evaluation Using Open-Loop Characteristics

Author

Osami Matsushita, Masao Kobayashi, Patrick Keogh, Hiroshi Kanki, and Masato Tanaka

Subjects
Vibration, Frequency response, Damping ratio, law, Control theory, Phase margin, Natural frequency, Helicopter rotor, Transfer function, Impulse response, law.invention, Mathematics
Abstract

This chapter discusses an evaluation method for rotor vibration characteristics by utilizing the open-loop frequency response of the system, instead of conventional eigenvalue analysis. The vibration characteristics of a rotor system are represented by the (damped) natural frequency and damping ratio. They have been estimated in the previous chapters from the viewpoint of the eigenvalue solution, the impulse response waveform, and the resonance curve (FRA) under harmonic excitation. The open-loop characteristics are from a concept in control engineering. A rotor-bearing system can be conceived as a control system as shown in Fig. 8.1, of which the open-loop characteristics are related to the vibration characteristics: the gain cross-over frequency is an estimate of the natural frequency, and the phase margin is an indicator for the damping ratio. Details of estimation are described below.

Published
2017
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25. Introduction of Rotordynamics

Author

Masato Tanaka, Hiroshi Kanki, Osami Matsushita, Patrick Keogh, and Masao Kobayashi

Subjects
Vibration, Bearing (mechanical), Rotor (electric), law, Stator, Computer science, Mechanical engineering, Rotordynamics, Energy source, Spin (aerodynamics), law.invention, Power (physics)
Abstract

This book explains various phenomena and mechanisms that induce vibrations in rotating machinery, based on theory and field experiences (Chaps. 1– 12 in volume 1). It also provides guidance in undertaking diagnosis and implementing effective countermeasures against various vibration problems in the field (in volume 2). Consequently, volume 1 is intended mainly for beginners and students, while volume 2 is mainly for design engineers and practitioners. This chapter of volume 1 emphasizes the subtlety of vibration problems in rotating machinery and the importance of reliable technologies that help to stabilize and reduce vibrations. It also outlines a wide variety of rotating machinery, vibration problems found in the field, and mathematical approaches to analyze vibration problems. In high-speed rotating machinery, the steady rotating state corresponds to a stationary equilibrium condition with a high rotational energy. Vibration brings the machine into a “dynamic” state. If the rotating system becomes unstable in the dynamic state, resulting in self-excited vibration, the machine enters a very dangerous operational condition. Since the energy source of self-excited vibration in a rotating system is provided by the spin of the rotor, the only way to avoid this dangerous situation is to stop the energy source, for example, by shutting down the power source in the case of a motor driven system. Vibrations caused by an external force, unless kept small enough, may also lead to a serious problems through contact between the rotor and the stationary part (stator).

Published
2017
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26. Unbalance and Balancing

Author

Masao Kobayashi, Patrick Keogh, Masato Tanaka, Hiroshi Kanki, and Osami Matsushita

Subjects
Rotor (electric), Angular displacement, Computer science, Linearity, Rotor vibration, law.invention, Vibration, Physics::Popular Physics, Linear relationship, Amplitude, law, Control theory, Waveform, Physics::Chemical Physics
Abstract

Most of the cases of rotor vibration problems come from excessive vibration or resonance due to unbalance. A quick remedy to compensate for it is balancing. Balancing is based on the assumptions of a linear relationship between input (unbalance) and output (vibration), namely, The amplitude of unbalance vibration is proportional to the level of unbalance, and A shift in the angular position of unbalance on a rotor results in a corresponding phase shift of the vibration waveform. While this linearity is the sole theoretical concept to explain how balancing works, practical methods of balancing include various alternatives based on operators’ experiences. Readers are expected to explore the numerical examples prepared so as to experience a wide variety of techniques.

Published
2017
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40. Simplification of formulas for compression wave and oscillating flow in circular pipe

Author

Yoshichika Sato and Hiroshi Kanki

Subjects
Physics::Fluid Dynamics, Cross section (physics), Work (thermodynamics), Acoustics and Ultrasonics, Multivalued function, Turbulence, Computation, Mathematical analysis, Phase velocity, Equivalence (measure theory), Algorithm, Longitudinal wave, Mathematics
Abstract

We had already obtained the analytical solutions for the compression wave and steady-state oscillating flow in a pipe with a circular cross section [Sato Y, Kanki H. Formulas for compression wave and oscillating flow in circular pipe. To be published in Appl Acoust [accepted 11 Sept. 2006]]. This work contains three key-components. The first key is to simplify the formulas using the unique mathematic technique without losing the accuracy. Simplifying the formulas is the one of the most important factors for formulas used in engineering use. The results will enable us to greatly reduce the work and computation costs. The second is to verify the flow distribution calculated by our formulas. The third is to study the possibility of application of our method to the analysis in turbulent flow region. Kawata et al. have represented the validity of one-dimensional quasi-analysis in turbulent flow region, using the method of D’Souza et al. and the shear viscosity. Therefore, in this paper the validity of the analysis in a turbulence region was verified by proving theoretically that the methods of D’Souza et al. and ours are intrinsically equivalent. The proof of equivalence was accomplished using the formulas simplified in this paper.

Published
2008
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45. Study on Stability of High Pressure Turbine (Effect of Partial Admission)

Author

Hiroshi Kanki and Akinori Tanitsuji

Subjects
Engineering, Power station, business.industry, Rotor (electric), Mechanical Engineering, Work (physics), Nozzle, food and beverages, Structural engineering, Turbine, Industrial and Manufacturing Engineering, law.invention, Vibration, Mechanics of Materials, law, Control theory, Steam turbine, business, Scale model
Abstract

Subsynchronous vibration of high-pressure steam turbine is one of the difficult problems to improve the reliability of power plant. Extensive work has been done to prevent the low frequency vibration of high-capacity steam turbine and most of the problems were practically solved (1). In the future, we must build up theoretical approach to design a new turbine operating under the steam condition of high-temperature and high-pressure. To design such an advanced steam turbine, it is necessary to solve the effect of partial admission on control stage of the steam turbine. This paper describes the experimental results from the scale model of the steam turbine and theoretical analysis of destabilizing forces. In theoretical analysis, destabilizing forces that take partial admission into consideration were analyzed. As a result, it was clarified that large destabilizing force was generated in partial admission condition and the destabilizing force varied periodically by the instant rotor position. In experimental study, we designed the new inlet seal for the prevention against the vibration. From the experimental result that increase of total flow rate leads the system stable, we showed the effectiveness of new inlet seal. And we paid attention to the step-up that is the step between blade and nozzle. As a result, it was experimentally proved that the step-up had a large influence on the rotor stability.

Published
2006
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