Journal of the Korean Society for Precision Engineering

Air- and Bone-conduction Effects in Vehicle Interior Noise and Vibration Evaluation: A 12-DOF Human Model-head Finite Element Study: Jongyeon Yoon, Daeun Jeong, Namkeun Kim; J. Korean Soc. Precis. Eng. 2025;42(9):713-721.
Published online September 1, 2025; DOI: https://doi.org/10.7736/JKSPE.025.085

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The rise of electric vehicles (EVs) has led to a reduction in engine noise, making suspension and road noise more noticeable. However, most assessments focus only on air-conducted (AC) pathways and overlook bone-conducted (BC) transmission. This study identifies key sources of vehicle noise and implements a finite-element simulation to replicate real-world driving conditions. A 12-degree-of-freedom (DOF) human body model quantifies how vibrations transmit from the vehicle structure to the head. Additionally, a detailed finite-element model of the human head evaluates basilar-membrane (BM) vibrations for both AC and BC inputs. The results indicate that BC dominates below 10 Hz, producing BM velocities up to 50 dB greater than AC. Above 10 Hz, AC prevails, showing a difference of approximately 40 dB. Notably, at frequencies of 33, 46, 67, and 80 Hz, the AC–BC difference narrows to below 10 dB, highlighting significant BC effects even at higher frequencies. These findings reveal that neglecting bone-conduction pathways can lead to an underestimation of occupant exposure to low-frequency vibrations. Therefore, comprehensive evaluations and control methods for vehicle noise should consider both AC and BC transmission mechanisms to accurately reflect human perception

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A Study on Structural Integrity Improvement of Cargo Drone through FE Simulation and Topology Optimization: 성종섭 , 시하영 , 강범수 , 구태완; J. Korean Soc. Precis. Eng. 2023;40(9):685-693.
Published online September 1, 2023; DOI: https://doi.org/10.7736/JKSPE.023.065

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This study deals with the structural integrity of a co-axial octocopter cargo drone. Most unstable states in progress of various flight missions of the cargo drone are considered to be derived from take-off and landing operations. In order to evaluate the structural integrity of these states, three-dimensional FE (finite element) simulation using whole frame assembled with structural members and components is performed, and then the effective stress level and deflection degree are investigated. Also, topology optimization is adopted to improve the locally concentrated stress and large deflection around front and rear sections of the motor-support side member. From topology optimization, it is ensured that the shape and location of plate support have to be modified for improving the stress level and the deflection degree. Based on the optimized and modified feature, FE simulation is re-performed. Consequently, it is confirmed that the effective stress and the deflection are reduced to about 26.67% and 19.15% around the side member, respectively.

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Utilization of topology optimization and generative design for drone frame optimization
Michał Kowalik, Michał Śliwiński, Mateusz Papis
Aircraft Engineering and Aerospace Technology.2025; 97(7): 813. CrossRef
A Study on the Design Optimization of Special-Purpose Multicopter Frames
Jong-Min Park, Seung-Chang Lee
Journal of the Korean Society of Manufacturing Process Engineers.2025; 24(12): 58. CrossRef

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Structural Reliability Evaluation for Brazed Joints of Fine Tube Heat Exchanger on an Aero Engine: Na Hyun Kim, Jong Rae Cho, Yong Jae Ra, Seul Bi Lee, Yoon Seok Choi; J. Korean Soc. Precis. Eng. 2018;35(8):783-789.
Published online August 1, 2018; DOI: https://doi.org/10.7736/KSPE.2018.35.8.783

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The worsening environmental pollution has increased the interest in developing eco-friendly technologies. The purpose of this study is to develop an aero-heat exchanger to reduce the emission of environmental pollutants. The operating conditions of an aircraft are extremely harsh, leading to challenges with the determination of appropriate materials and structures that can withstand the severe conditions. In addition, since the tubes brazed to the tube-sheet are structurally fragile, it is essential to assess the structural integrity of tubes. In this study, the overall structural integrity of the tubular heat exchanger under development was evaluated. An appraisal of the junctions between tubes and tube-sheet, which are the most critical parts, was conducted. A finite element (FE) analysis was employed for the assessment of structural integrity. FE analysis was used to evaluate the brazed joint of tubes using a model in which specific tubes were designed to withstand the high temperature of the tube-sheet. The evaluation was carried out compared with the fatigue strength of Inconel 625, the material constituting the heat exchanger.