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David Yoon

Bio: David Yoon is an academic researcher. The author has contributed to research in topics: Vibration fatigue & Failure mode and effects analysis. The author has an hindex of 1, co-authored 1 publications receiving 39 citations.

Papers
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Journal ArticleDOI
TL;DR: In this paper, the authors developed test specifications for components, which are applicable to predict fatigue life at the stage of initial product design, for the unit brackets by using a vibration fatigue technique.
Abstract: Unit brackets attached on a cross member and subjected to random loads often fail due to self-vibration. To prevent such failures, it is necessary to understand the fatigue failure mode and to evaluate the fatigue life using test or analysis techniques. The objective of this study is to develop test specifications for components, which are applicable to predict fatigue life at the stage of initial product design, for the unit brackets by using a vibration fatigue technique. For this objective, the necessity of a fatigue analysis considering resonant effect was reviewed. Also, a series of vibration fatigue analyses were carried out by changing the acceleration’s direction and magnitude. Then, a methodology was proposed to determine the optimum vibration fatigue test specification of the component, which gives an equivalent failure mode with the vehicle test condition.

52 citations


Cited by
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Journal ArticleDOI
TL;DR: In this article, the authors proposed a modal superposition method to calculate the dynamic stress of structural vibration fatigue under non-stationary state by considering the external multi-input loads of the structure.

38 citations

Journal ArticleDOI
TL;DR: In this article, the electromechanical attributes of 18650 NCA battery cells were evaluated using a multi-axis shaker table to determine if they are adversely affected by exposure to vibration commensurate with that experienced by electric vehicles.
Abstract: This paper presents new research to determine if the electromechanical attributes of Nickel Cobalt Aluminium Oxide (NCA) 18650 battery cells are adversely affected by exposure to vibration commensurate with that experienced by electric vehicles (EVs) through road induced excitation. This investigation applied vibration to a set of commercially available cells in six degrees of freedom (6-DOF) using a multi-axis shaker table. This method of mechanical testing is known to be more representative of the vibration experienced by automotive components, as 6 motions of vibration (X, Y, Z, roll, pitch and yaw) are applied simultaneously. Within the context of this study, cell characterisation within the electrical domain is performed via quantification of the cell’s impedance, the open-circuit potential and the cell’s energy capacity. Conversely, the mechanical properties of the cell are inferred through measurement of the cell’s natural frequency. Experimental results are presented that highlight that the electromechanical performances of the 18650 NCA cells do not, in the main, display statistically significant degradation when subject to vibration representative of a typical 10-year European vehicle life. However, a statistically significant increase in DC resistance of the cells was observed.

34 citations

Journal ArticleDOI
19 Jan 2016-Energies
TL;DR: In this article, the authors quantified both electrical and mechanical vibration-induced degradation through measuring changes in cell capacity, impedance and natural frequency, and evaluated the impact of the cell state of charge (SOC) and in-pack orientation.
Abstract: Electric vehicle (EV) manufacturers are employing cylindrical format cells in the construction of the vehicles’ battery systems. There is evidence to suggest that both the academic and industrial communities have evaluated cell degradation due to vibration and other forms of mechanical loading. The primary motivation is often the need to satisfy the minimum requirements for safety certification. However, there is limited research that quantifies the durability of the battery and in particular, how the cells will be affected by vibration that is representative of a typical automotive service life (e.g., 100,000 miles). This paper presents a study to determine the durability of commercially available 18,650 cells and quantifies both the electrical and mechanical vibration-induced degradation through measuring changes in cell capacity, impedance and natural frequency. The impact of the cell state of charge (SOC) and in-pack orientation is also evaluated. Experimental results are presented which clearly show that the performance of 18,650 cells can be affected by vibration profiles which are representative of a typical vehicle life. Consequently, it is recommended that EV manufacturers undertake vibration testing, as part of their technology selection and development activities to enhance the quality of EVs and to minimize the risk of in-service warranty claims.

33 citations

Journal ArticleDOI
07 Aug 2018
TL;DR: In this paper, a frequency-based approach predicted spring using acceleration signals that were collected from various road conditions was presented. But the results revealed that the harshest road condition was the rural road where the spring with fatigue life of 4.47 × 107 blocks to failure was obtained.
Abstract: This paper presents the evaluation of frequency-based approach predicted spring using acceleration signals that were collected from various road conditions. Random loadings in the forms of acceleration are nominal and more flexible for vehicle components fatigue assessment. In this analysis, the strain time history of the spring and acceleration signals of the suspension strut was measured from three different road conditions. The acceleration signals were then transformed into power spectra density (PSD). PSD cycle counter, like Lalanne, Dirlik, and narrow band approach, was applied to obtain equivalent load cycles. The stress response was obtained through having the equivalent load cycles with a spring modal frequency response function (FRF) and different stress criterion, like absolute maximum principal and critical plane approaches. Then, the stress response was used to predict the spring fatigue life using stress-life (S-N) approach. The results revealed that the harshest road condition was the rural road where the spring with fatigue life of 4.47 × 107 blocks to failure was obtained. The strain predicted fatigue life was used to validate the frequency-based predictions using a conservative approach. It was found that the Dirlik approach has shown the closest results to the strain life approach, which suggested that the Dirlik approach could be used for spring fatigue life prediction with the acceptable accuracy.

30 citations

Journal ArticleDOI
TL;DR: In this paper, a vibration fatigue analysis that considers changes in frequency response resulting from the cumulative fatigue damage to multi-point spot-welded joints in an automotive body was conducted.

29 citations