Vibration Engineering Peer Reviewed Articles & Insights

Influence of dynamic behavior of excavator steel structure on correction of human vibrations: operator cabin case study

Journal of Vibroengineering

Recent advancements of signal processing and artificial intelligence in the fault detection of rolling element bearings: a review

A rolling element bearing is a common component in household and industrial machines. Even a minor fault in this section has a negative impact on the machinery's overall operation. As a result, the industry suffers significant financial losses, and this damage can potentially result in catastrophic failures. Therefore, even a little fault in the rolling element bearings must be recognized and remedied as soon as possible. Many ways for detecting REB defects have been created in recent years, and new methods are being introduced on a daily basis. This article will provide a summary of such methods, with a focus on vibration analysis techniques. The newest advancements in this field will be recognizable to readers of this article. Anyone interested in defect diagnostics of rolling element bearings can utilize this material.

June 26, 2022

Applied Mathematics

Ground vibration propagation and attenuation of vibrating compaction

Research Article

When a high-power vibrating roller compact the subgrade, the vibration wave will quickly propagate along the surface of the subgrade and generate hazards to surrounding environment and structure. To study the vibration propagation rules of the roller, the vibration acceleration of the high-power vibrating roller was measured on the surface of the rock subgrade, coarse-grained soil subgrade and fine-grained soil subgrade. The respective relations between vibration acceleration and the distance from a vibration source in the vertical, horizontal radial and horizontal circumferential direction have been discovered. The research results show that the vibration peak frequency generated by the vibrating roller on the subgrade approximates vibration frequency. The vibration effective influence distance varies from 10m to14m, and the horizontal radial vibration is greater than that of vertical and horizontal circumferential direction. The vibration of the rock subgrade attenuates the most slowly and propagates the most remotely.

August 15, 2019

Vibration Engineering

Bearing fault diagnosis based on improved VMD and DCNN

Research Article

Vibration signal produced by rolling element bearings has obvious non-stationary and nonlinear characteristics, and it’s necessary to preprocess the original signals to obtain better diagnostic results. This paper proposes an improved variational mode decomposition (IVMD) and deep convolutional neural network (DCNN) method to realize the intelligent fault diagnosis of rolling element bearings. Firstly, to solve the problem that the number of decomposed modes of variational mode decomposition (VMD) needs to be preset, an IVMD method is proposed, where the mode number can be determined adaptively according to the curve of the instantaneous frequency mean of mode functions. With this method, the vibration signal can be decomposed into a series of modal components containing bearing fault characteristic information. Then, DCNN is employed to fuse these multi-scale modal components, which can automatically learn fault features and establish bearing fault diagnosis model to realize intelligent fault diagnosis eventually. Experimental analysis and comparison results verify that the proposed method can effectively enhance the bearing fault features and improve the diagnosis accuracy.

August 15, 2020

Applied Mathematics

Vibration monitoring of CNC machinery using MEMS sensors

Research Article

Industry 4.0 relies on the adoption of digital technologies to gather data in real time and to analyse it, providing useful information to the manufacturing system. In this paper, what solutions modern production plants that are aspiring towards compliance with philosophy of the Industry 4.0 have to adopt, monitor and analyse the vibration data of the manufacturing systems using existing process and tool monitoring solutions. In addition, detailed explanation of vibration level reading in order to increase the protection of the production sources (machines, devices etc.) against human errors and malfunctions in terms of Total Quality Management (TQM) and Total Productive Maintenance (TPM) with the concept’s levels TPM1(operator level) and TPM2(periodic conditional reviews etc.) will be giving with a Montronix system’s integration on a CNC milling machine. Besides, optimization and monitoring function of production process will be demonstrated with related graphs and tables with values of different scenarios.

May 15, 2020

Vibration Engineering

Comprehensive platform for advancements in the field of vibration engineering

Journal Impact Factor (JIF)

0.9

CiteScore

1.9

APC

1050 EUR

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Most cited

Research article

May 15, 2020

By Alina Kim, Mikhail Doudkin, Alexandr Ermilov, Gennadiy Kustarev, Murat Sakimov, Marek Mlynczak

Most cited

Research article

September 30, 2019

By Shutao Zhao, Erxu Wang, Jiawei Hao

Most cited

Research article

March 31, 2020

By Grzegorz Żywica, Tomasz Z. Kaczmarczyk, Łukasz Breńkacz, Małgorzata Bogulicz, Artur Andrearczyk, Paweł Bagiński

Most cited

Research article

April 21, 2022

By Vitaliy Korendiy, Volodymyr Gursky, Oleksandr Kachur, Petro Dmyterko, Oleh Kotsiumbas, Oleksandr Havrylchenko

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Modal finite element analysis of PCBs and the role of material anisotropy

Most downloaded

Research Article

By Uday H. Kalyani, Mark Wylie

Printed Circuit Boards (PCBs) are epoxy resin-impregnated and cured sheets of counter woven glass fabric (e.g. FR4) laminated between thin sheets of Copper. The nature of the PCB is inherently anisotropic and inhomogeneous but previous modal FEMs of PCBs have assumed isotropic, anisotropic (transversely isotropic and orthotropic) material properties and shown good correlation with test data for specific scenarios [1-3]. This paper details part of a research program aimed at gaining a better understanding of accurately modeling PCB’s dynamic behavior. New investigations into the impact of material anisotropy and, in particular, the effect of material orthogonal plane definition (Ex and Ey) on eigenfrequencies is analysed. A modal FEM of a JEDEC PCB is created, verified, and validated using well established theories by Steinberg and empirical data by others [4, 5]. The relative contributions of Ex, Ey and Ez on PCB eigenfrequencies is examined using a parametric modal FEM, analysing the role of material isotropy verses anisotropy. The impact of transversely isotropic material properties is also analysed for a typical JEDEC PCB. This analysis details the mesh density required for accurately modeling the PCB eigenfrequencies. The results show that a 100 % increase in Ez has only a 0.2 % difference in the eigenfrequency where as a 100 % increase in Ey has a 1.2 % difference in the eigenfrequency. The effect of orthotropic plane definition (alternating Ex with Ey) on the JEDEC PCB amount to a 7.95 % delta in eigenfrequency.

June 29, 2020

Vibration Engineering

Dynamical processes in a multi-motor gear drive of heavy slabbing mill

Most downloaded

Research Article

By Pavlo V. Krot

A real case study is represented of abrupt failures in a new multi-motor gear drive of vertical rolls in the heavy slabbing mill. Modal analysis is conducted, and the lowest torsional vibration modes are verified by the data from an industrial plant. Conditions of parametric resonances due to variable stiffness of teeth are determined within the range of working speed. The branched gear drive is investigated by the non-linear dynamical model with backlashes. It is shown that instantaneous dynamic loads in driveline are strongly dependent on the difference in gap sizes and phase shift between two intermediate gears in the output gear wheel coupling. Deviation in electrical parameters by 0.5 % is considered as the additional cause of not equal load sharing of parallel motors. Results of this research allowed preventing further failures of the gearbox and optimizing slabbing mill control. The proposed approach can be used in other multi-motor machines.

December 31, 2019

Vibration Engineering

Underwater robotic arms are important devices that enables workers to carry out tasks remotely from a safe distance reducing or eliminating the risks that are involved with the task. The primary objective of the robotic manipulator is to perform maintenance and cleaning activities of the hull of a ship. However, the control of these devices underwater is quite complicated due to the numerous factors that make these systems unstable and non-linear. The aim of this study is to develop a multibody dynamic robotic manipulator model, integrated with a control strategy to optimize and obtain stable kinematics solutions. The hydrodynamic forces are integrated to the manipulator model considering buoyancy forces and surface drag forces. A basic algorithm is used to generate the joint angles using 7 geometrical parameters. The control of the manipulator was done to simply follow any path that represents the given coordinates. The P, I and D parameters are tuned individually to optimize the kinematic solution of the manipulator. 3-DOF articulated manipulator is the commonly used manipulator configuration. However, a 6-DOF manipulator configuration was selected in this study to allow for change in orientation using wrist motions.

Welcome to Extrica's hub for Vibration Engineering

A leading source for open access journals in the science and engineering realms. Here, you'll find comprehensive coverage of all things related to vibration engineering. Whatever your research or interest in vibration engineering, we provide extensive resources to support your exploration.

Understanding Vibration Engineering

Dive into the world of vibration engineering with an introduction to its core concepts. This field delves into the study of mechanical vibrations and their impact on various structures. Vibration in mechanical engineering is about understanding the oscillatory motions of mechanical systems from their equilibrium positions. Key principles in this area include free and forced vibrations, harmonic motion, damping, natural frequency, and resonance.

Practical Applications in Vibration Engineering

Vibration analysis is crucial across various industries. Applications range from structural health monitoring and aerospace engineering to machinery health, power generation, seismology, consumer electronics, medical imaging, entertainment, and earthquake engineering. These real-world uses underscore the field's significance.

Innovations in Vibration Mitigation

Discover the latest technological breakthroughs in vibration mitigation, enhancing the performance and longevity of various systems. Innovations aim at noise reduction, precision improvement, and increased comfort and safety. The field has evolved through passive and active vibration mitigation techniques, marking significant progress in vibration engineering.

Case Studies in Vibration Engineering

Learn from real-world scenarios where vibration engineering principles have been applied to resolve challenges. For instance, a case study at a hydroelectric dam highlights how addressing vibration issues, due to Rheingans influence, led to redesigning turbine blades, thereby solving the resonance problem.

Your Vibration Engineering Resource

With a solid understanding of vibration engineering's principles and advancements, professionals in this field can make significant contributions across various sectors. Staying updated with the latest developments is key to innovating and ensuring safety in vibration-related projects. Extrica provides the knowledge and tools necessary for tackling vibration challenges effectively.