Synopses & Reviews
The two-volume work
Engineering Vibration Analysis is devoted to problems on vibration theory analysis, which is currently one of the fundamental courses in mechanical engineering departments at technical universities.
The first volume is devoted to systems with a finite number of degrees of freedom and continuous systems are analyzed in the second. In the first part of each volume problems are posed and in the second part the detailed solutions to these problems are dealt with. Conventional and advanced problems requiring deeper knowledge of the vibration theory are analyzed. In particular, problems are formulated associated with the determination of frequencies and vibration modes, the study of free and forced vibrations, as well as with parametric and nonlinear vibration analysis. The problems associated with determination of critical parameters, dynamic stability and with random vibrations are also considered. The algorithms for their solutions are presented with probability characteristics calculation, and a reliability estimation (probability of non-failure operation) of the corresponding mechanical system.
Review
From the reviews: "The book contains a collection of problems concerning the vibrations of rods. ... The statics and dynamics of curvilinear rods, together with basic equations, are presented in appendices. The book can be considered as a problem book for students and engineers who work in the area of vibrations of engineering structures." (Yuri N. Sankin, Zentralblatt MATH, Vol. 1103 (5), 2007)
Review
From the reviews:
"The book contains a collection of problems concerning the vibrations of rods. ... The statics and dynamics of curvilinear rods, together with basic equations, are presented in appendices. The book can be considered as a problem book for students and engineers who work in the area of vibrations of engineering structures." (Yuri N. Sankin, Zentralblatt MATH, Vol. 1103 (5), 2007)
Synopsis
The two-volume work "Engineering Vibration Analysis" is devoted to problems on vibration theory analysis, which is currently one of the fundamental courses in mechanical engineering departments at technical universities. The first volume is devoted to systems with a finite number of degrees of freedom and continuous systems are analyzed in the second. In the first part of each volume problems are posed and in the second part the detailed solutions to these problems are dealt with. Conventional and advanced problems requiring deeper knowledge of the vibration theory are analyzed. In particular, problems are formulated associated with the determination of frequencies and vibration modes, the study of free and forced vibrations, as well as with parametric and nonlinear vibration analysis. The problems associated with determination of critical parameters, dynamic stability and with random vibrations are also considered. The algorithms for their solutions are presented with probability characteristics calculation, and a reliability estimation (probability of non-failure operation) of the corresponding mechanical system.
Synopsis
Constantly increasing attention is paid in the course 'Vibration 'Theory' to vibration of mechanical systems with distributed parameters, since the real elements of machines, devices, and constructions are made of materials that are not perfectly rigid. 'Therefore, vibrations of the objects including, for ex- ample, rod elastic elements excite the vibrations of these elements, which can produce a substantial effect on dynamic characteristics of moving objects and on readings of instruments. For a mechanical engineer working in the field of design of new technolo- gies the principal thing is his know-how in developing the sophisticated math- ematical models in which all specific features of operation of the objects under design in real conditions are meticulously taken into account. So, the main emphasis in this book is made on the methods of derivation of equations and on the algorithms of solving them (exactly or approximately) taking into con- sideration all features of actual behavior of the forces acting upon elastic rod elements. 'The eigen value and eigen vector problems are considered at vibrations of curvilinear rods (including the rods with concentrated masses). Also consid- ered are the problems with forced vibrations. When investigating into these problems an approximate method of numerical solution of the systems of lin- ear differential equations in partial derivatives is described, which uses the principle of virtual displacements. Some problems are more complicated than others and can be used for practical works of students and their graduation theses.
Synopsis
The two-volume work Engineering Vibration Analysis is devoted to problems on vibration theory analysis, which is currently one of the fundamental courses in mechanical engineering departments at technical universities. The first volume is devoted to systems with a finite number of degrees of freedom and continuous systems are analyzed in the second. In the first part of each volume problems are posed and in the second part the detailed solutions to these problems are dealt with. Conventional and advanced problems requiring deeper knowledge of the vibration theory are analyzed. In particular, problems are formulated associated with the determination of frequencies and vibration modes, the study of free and forced vibrations, as well as with parametric and nonlinear vibration analysis. The problems associated with determination of critical parameters, dynamic stability and with random vibrations are also considered. The algorithms for their solutions are presented with probability characteristics calculation, and a reliability estimation (probability of non-failure operation) of the corresponding mechanical system.
Table of Contents
Problems and Examples.- Answers and solutions.-
Part A: Statics of rods: basic equations.-
Part B: Basic equations of rod kinematics.-
Part C: Basic equations of rod dynamics.-
Part D: Exact numerical method of determining the frequencies and modes of rod vibrations.-
Part E: Approximate numerical determination of frequencies at small vibrations of rods.-
Part F: Approximate solution of equation of rod forced vibrations.