Vibration Engineering for a Sustainable Future: Experiments, Materials and Signal Processing, Vol. 2

This volume presents the proceedings of the Asia-Pacific Vibration Conference (APVC) 2019, "Vibration Engineering for a Sustainable Future," emphasizing work devoted to numerical simulation and modelling. The APVC is one of the larger conferences held biannually with the intention to foster scientific and technical research collaboration among Asia-Pacific countries.  The APVC provides a forum for researchers, practitioners, and students from, but not limited to, areas around the Asia-Pacific countries in a collegial and stimulating environment to present, discuss and disseminate recent advances and new findings on all aspects of vibration and noise, their control and utilization. All aspects of vibration, acoustics, vibration and noise control, vibration utilization, fault diagnosis and monitoring are appropriate for the conference, with the focus this year on the vibration aspects in dynamics and noise & vibration. This 18th edition of the APVC was held in November 2019in Sydney, Australia. The previous seventeen conferences have been held in Japan (‘85, ’93, ‘07), Korea (’87, ’97, ‘13), China (’89, ’01, ’11, ‘17), Australia (’91, ‘03), Malaysia (’95, ‘05), Singapore (‘99), New Zealand (‘09) and Vietnam (‘15).  

Table of Contents:
Chapter 1. Simulation and Measurement of an electric driven turbo charger test rig with full floating ring bearing.- Chapter 2. Visualization of Strain Distribution in Tire Tread Block Using Intermittent Digital Camera System.- Chapter 3. Field Measurements of the Propagation of Vibration Between an Underground Tunnel and Ground Surface Through Sydney Sandstone and Shale.- Chapter 4. Experimental Study on Rail Corrugation Development with 1/10 Scale Model.- Chapter 5. Measurement and Dynamic Mode Analysis of Flow-Induced Noise with Combined Proper Orthogonal Decomposition.- Chapter 6. Accuracy Improvement to the Identified Modal Parameters of Systems with General Viscous Damping.- Chapter 7. Classification of Characteristic Modes for Vibration Reduction.- Chapter 8. Vision-based Modal Testing of Hyper-Nyquist Frequency Range Using Time-Phase Transformation.- Chapter 9. Experimental Investigation on the Effect of Tuned Mass Damper on Mode Coupling Chatter in Turning Process of Thin-Walled Cylindrical Workpiece.- Chapter 10. Eliminating the iIfluence of Additional Sensor Mass on Atructural Natural Frequency in the Modal Experiment.- Chapter 11. A Study of the Vibration Reduction Effect of Sound Absorbing Material within Acoustic Box.- Chapter 12. Experimental Study on the Effects of Pickguard Material on the Sound Quality of Electric Guitars.- Chapter 13. Influence of Pulverized Material on Vibration and Sound Characteristics of an Operating Ball Mill.- Chapter 14. Three-Dimensional Strain Calculation of Rubber Composite with Fiber-Shaped Particles by Feature Point Tracking Using X-Ray Computed Tomography.- Chapter 15. Experimental Study on a Passive Vibration Isolator Utilizing Dynamic Characteristics of a Post-Buckled Shape Memory Alloy.- Chapter 16. Vibration Reduction of a Composite Plate with Inertial Nonlinear Energy Sink.- Chapter 17. Vibration Analysis of Harmonically Excited Antisymmetric Cross-Ply and Angle-Ply Laminated Composite Plates.- Chapter 18. Analysis of Influence of Multilayer Ceramic Capacitor Mounting Method on Circuit Board Vibration.- Chapter 19. Comparison of the Input Identification Methods for the Rigid Structure Mounted on the Elastic Suppor.- Chapter 20. Iterative Learning Control for Vision-Based Robotic Grasping.- Chapter 21. Floor Response Spectrum of Nuclear Power Plant Structures Considering Soil-Structure Interaction.- Chapter 22. Real-time Identification of Vehicle Motion-Modes.- Chapter 23. Estimation of Normalized Eigenmodes and Natural Frequencies by Using the Effect of Accelerometers Mass.- Chapter 24. Pitting Fault Severity Diagnosis of Spur Gears Using Vibration and Acoustic Emission Sensor Measurements.- Chapter 25. Loosening Detection of a Bolted Joint Based on Monitoring Dynamic Characteristics in the Ultrasonic Frequency Region.- Chapter 26. Gas Turbine Fault Detection Using A Self-Organising Map.- Chapter27. A Comparative Analysis Between EMD and VMD Based Tacho-less Order Tracking Techniques for Fault Detection in Gears.- Chapter 28. An Effective Indicator for Defect Detection in Concrete Structures by Rotary Hammering.- Chapter 29. A Vibration-based Strategy for Structural Health Monitoring with Cosine Similarity.- Chapter 30. A New Testing Method for Bolt Loosening with Transmitted Ultrasonic Pulse.- Chapter 31. Vibration Isolation Performance of an LQR-stabilised Planar Quasi-zero Stiffness Magnetic Levitation System.- Chapter 32. Proposition of Isolation Table Considering the Long-Period Earthquake Ground Motion .- Chapter 33. Experimental Vibration Analysis of SeismicIisolation System Using Inertial Mass Damper.- Chapter 34. Development of Sliding-Type Semi-Active Dynamic Vibration Absorber Using Active Electromagnetic Force.- Chapter 35. Development of a Vibration Isolator Using Air Suspensions with Slit Restrictions.- Chapter 36. Development of a Tuning Algorithm for a Dynamic Vibration Absorber with a Variable Stiffness Property.- Chapter 37. Design Approach of Laminated Rubber Bearings for Seismic Isolation of Plant Equipment.- Chapter 38. Sound Transmission of Beam Stiffened Thick Plates.- Chapter 39. On the Feasibility of Transformer Insulation Aging Detection with Vibration Measurements.- Chapter 40. Study on Equivalent Effective Distance of Point Sound Source in Substation.- Chapter 41. Transformer Acoustic Equivalent Model in Engineering Application.- Chapter 42. Simulation Study on Noise Reduction Effect of Substation Noise Barrier.- Chapter 43. Research on Sound Power Prediction Methods of the Transformer Noise .- Chapter 44. Fault Recognition of Induction Motor Based on Convolutional Neural Network Using Stator Current Signal.- Chapter 45. A Numerical Study on Active Noise Radiation Control Systems Between two Parallel Reflecting Surfaces.- Chapter 46. Characterization of Active Microcantilevers Using Laser Doppler Vibrometry.- Chapter 47. Experimental Investigation on Generation Mechanism of Friction Vibration in Toner Fixing Device.- Chapter 48. Using a Laser Doppler Vibrometer to Estimate Sound Pressure in Air.- Chapter 49. Experimental and Numerical Modal Analysis of an Axial Compressor Blisk.- Chapter 50. Effectiveness of Using Damping as a Parameter to Detect Impact Damages in GFRP Plates.- Chapter 51. Debonding Growth Monitoring Through Ultrasonic Guided Waves Field Imaging .- Chapter 52. Nonlinear Ultrasonic Guided Waves for Damage Detection.

About the Author :
Dr. Sebastian Oberst, University of Technology Sydney, Centre for Audio, Acoustics and Vibration, Faculty of Engineering and IT; - Dr. Oberst works as Senior Lecturer at the newly founded Centre for Audio, Acoustics and Vibration (CAAV) and is Chief Investigator on several prestigious Australian Research Council grants. In 2017 he received the highly esteemed Junior Research Prize awarded by the European Association of Structural Dynamics (EASD) in the category "Development of Methodologies for Structural Dynamics". This prize follows the JSPS Award (2016) nominated by the Australian Academy of Science and an Australia Award/Endeavour Postdoctoral Research Fellowship (Australian Government, 2015) to work at the Imperial College London/Rolls-Royce Vibration University Technology Centre. Dr. Oberst led a DFG Priority Program (SPP1897) project in Applied and Theoretical Mechanics at the Technical University Munich; prior to this he worked as Research Associate then Space Engineer (Mechanical Antenna Design, Buccaneer Risk Mitigation Mission) at the UNSW Canberra from 2011 to 2016. Dr. Oberst received his Ph.D in Mechanical Engineering from The University of New South Wales in 2011 on his research on friction-induced instabilities and specialised since then in nonlinear dynamics of friction processes, as well as nonlinear time series analysis and signal processing, as applied to biotremology and micro-vibrational communication of insects. Dr. Benjamin Halkon, University of Technology Sydney, Centre for Audio, Acoustics and Vibration, Faculty of Engineering and IT; - Dr. Benjamin Halkon is an experimentally-focuseddynamicist specialising in the development and industrially relevant application of non-contact measurements techniques and technologies primarily for the determination of structural vibration characteristics. Dr.Halkon joined UTS as a Senior Lecturer in the Faculty of Engineering &IT in 2017 and has been a core member of the Centre for Audio, Acoustics and Vibration therefrom. He has held the position of Deputy Head of School (Teaching & Learning) in the School of Mechanical and Mechatronic Engineering since early 2018 and has established, and is Academic Lead for, the LDV Lab at UTS Tech Lab – a unique facility within the region. Dr.Halkon has secured and completed many industry- and government-funded research projects and has supervised several post-doctoral and Ph.D (HDR) researchers and many UG/PG student projects in support of these. He has authored over 50 peer-reviewed articles and has contributed to policy change through his research and he is an Engineering Council accredited chartered mechanical engineer (CEng) and a Fellow of the Institution of Mechanical Engineers (FIMechE), a Fellow of the Institution of Engineers Australia (FIEAust) and chartered professional engineer (CPEng) and a Member of the Australian Acoustical Society (MAAS). Dr.Jinchen Ji, University of Technology Sydney, School of Mechatronic and Mechanical Engineering, Faculty of Engineering and IT; -Dr.Jinchen Ji is a leading research scientist in the general areas of dynamics, vibration, and control, with over 110 journal publications. He has high-level expertise in dynamic modelling, vibration control, coordination control, synchronization and consensus control, noise control, condition monitoring, signal analysis, fault diagnosis, fatigue analysis, performance evaluation and energy consumption, and their applications to key problems in wind power industry, mining industry, manufacturing industry, agricultural industry and defense industry. He has been involved in a wide range of research projects which were financially supported by various government funding agencies and industry partners, in the fields of dynamic modelling, vibration analysis, vibration control, fatigue analysis, stability analysis, FEM analysis, and robotic systems. Dr. Ji is an Associate Editor for two top international journals, namely, International Journal of Bifurcation and Chaos, and Journal of Vibration and Control. He is also an assessor and external reviewer for Australian Research Council ARC grant applications, Hong Kong RGC grant applications, and European Grant applications. He has been invited to be a session chair in many international conferences. He has also been invited to be a reviewer for over thirty international journals. Dr. Terry Brown, University of Technology Sydney, School of Mechatronic and Mechanical Engineering, Faculty of Engineering and IT; - Dr. Terry Brown is a teaching focussed academic with a wide technical background and with interests and expertise in several areas. Dr. Brown joined UTS as an Associate Lecturer in 1995 and is now Senior Lecturer and Program Coordinator for Mechanical Engineering in the School of Mechanical and Mechatronic Engineering in the Faculty of Engineering and IT. He has taught in over 15 different subjects, made major contributions to establishing new courses and curriculum redevelopment and has received awards for his contribution to, and excellence in, teaching and learning. He has secured and completed, on his own and in partnership with others, several industry and government funded research and consultancy projects. These have been primarily in the areas of structural simulation and analysis and experimental verification and validation. Dr. Brown has also published widely, including in engineering education, biomechanics and vibration.