Nature-inspired cellular structure design for electric vehicle battery compartment: Application to crashworthiness
| Author | Mudassir, Mohammed |
| Author | Tarlochan, Faris |
| Author | Mansour, Mahmoud A. |
| Available date | 2023-01-26T07:03:29Z |
| Publication Date | 2020 |
| Publication Name | Applied Sciences (Switzerland) |
| Resource | Scopus |
| Abstract | This paper discusses the potential of using lightweight nature-inspired cellular structured designs as energy absorbers in crashworthiness applications for electric vehicles (EV). As EVs are becoming popular with their increased battery capacity, these lightweight cellular structures have regained research interest as they may increase mileage by reducing vehicle mass in addition to protecting the battery during collisions. In this paper, a novel lightweight cellular structure for EV battery protection and crashworthiness is designed and simulated. In designing the cellular structure, four different ways of applying the shell thickness have been considered that affects the collapse behavior and the crashworthiness. A numerical study was conducted on 45 samples with varying length, shell thicknesses, and thickness application methods. Four types of shell thickness application methods were investigated: Uniform thickness, strut-wall thickness, gradient thickness, and alternate thickness. Force-displacement curves, energy absorption, specific energy absorption, and collapse behaviors are some of the metrics used for evaluating the crashworthiness of the structures. Shell thickness is found to affect both the collapse behavior and energy absorption capabilities. Energy absorption results are similar to other studies on designed cellular structures. The highest performing cellular structure is reported to have a specific energy absorption of 35kJ/kg, which is comparable to cellular structures reported in the literature. 2020 by the authors. Licensee MDPI, Basel, Switzerland. |
| Sponsor | Author Contributions: For this research article, M.Mu. (Mudassir) was the main author responsible for the original draft. He was also responsible for the analysis along with M.Ma. (Mansour). F.T. contributed to the and editing. F.T. was also responsible for the funding acquisition and supervision of the project. All authors have conceptualization and review and editing. F.T. was also responsible for the funding acquisition and supervision read and agreed to the published version of the manuscript. of the project. All authors have read and agreed to the published version of the manuscript. Funding: This research was funded by the Qatar National Research Funding, grant number UREP17-151-2-044. TFhuensdtiantegm: Tehnitss rmesaedaerchhe rweians afurensdoelde lbyyththeereQspatoanrs Nibailtiitoynoafl tRheeseaaurtchho rFsu.nding, grant number UREP17-151-2-044. The statements made herein are solely the responsibility of the authors. Acknowledgments: The Qatar National Library is acknowledged for supporting part of the publication fee. The authors acknowledge the facilities, and the scientific and technical assistance, of the staff within the College of Engineering, Qatar University. authors acknowledge the facilities, and the scientific and technical assistance, of the staff within the College of Conflicts of Interest: The authors declare no conflict of interest. |
| Language | en |
| Publisher | MDPI AG |
| Subject | Battery compartment crashworthiness Electric vehicle Energy absorption Lightweight cellular materials Passive safety Protective devices |
| Type | Article |
| Issue Number | 13 |
| Volume Number | 10 |
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Mechanical & Industrial Engineering [1270 items ]
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