A Finite-Element-Analysis-Based Feasibility Study for Optimizing Pantograph Performance Using Aluminum Metal Matrix Composites

Ilunga, Masengo; Agarwal, Abhishek

doi:10.3390/pr12030445

Cited by 4 publications

References 23 publications

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Crashworthiness Evaluation of Electric Vehicle Battery Packs Using Honeycomb Structures and Explicit Dynamic Analysis

Agarwal,

Cavicchioli Batista,

Tashi

2024

E3S Web Conf.

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The battery pack system is crucial to safeguard battery units during any collision. The crashworthiness of battery packs could be improved with the incorporation of honeycomb structures. The objective of the current study is to evaluate the structural characteristics of battery encasing using ANSYS explicit dynamic analysis. The modal analysis is conducted to determine the natural frequency, mode shape, and peak displacement values. The CAD model of the battery pack is developed in Creo parametric design software. The use of a honeycomb structure enabled the reduction of the effect of impact on battery units. At the time of the collision, the honeycomb structure would absorb maximum crash impact and would save the battery unit cells from major damage. The natural frequency of a battery pack with a honeycomb structure has a higher first, 2nd, and 3rd natural frequency. At the time of impact and without any honeycomb structure, the internal energy of the battery unit is 1021.8mJ while with the honeycomb lattice structure, it is 0.80376mJ. The results have shown that with the incorporation of a honeycomb structure, there is a substantial reduction in the internal energy of the cell with the incorporation of the lattice structure.

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Crashworthiness Evaluation of Electric Vehicle Battery Packs Using Honeycomb Structures and Explicit Dynamic Analysis

Agarwal,

Cavicchioli Batista,

Tashi

2024

E3S Web Conf.

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Numerical Analysis of Solar Collector Absorber Tubes with C- shaped Roughness for Enhanced Heat Transfer

Agarwal

2024

E3S Web of Conf.

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Solar collector absorber tubes perform a significant function in solar power devices that concentrate the solar energy into a single cylindrical absorber tube. Characteristically, this type of tube is covered with a smooth surface. The purpose of this study is to simulate the convectional behaviour of these absorber tubes with the help of numerical calculation methods like Computational Fluid Dynamics (CFD). The collector tube CAD model has been made using the Creo design software and the ANSYS CFX software is used for the CFD simulations corresponding to the three mass_flow rates (0.005Kg/s, 0.010Kg/s, and 0.015Kg/s). The heat transfer is improved by tweaking the absorber tube with a C-shaped corrugated roughness profile. The choice of the Shear Stress Transport turbulence (SSTT) model for analysis is justified by its capability to accurately predict both laminar and turbulent flows, which is why it is considered to be suitable for the absorber tube with a cross-sectional shape. Findings demonstrated that the use of C-shaped artificial roughness led to a substantial rise in convective heat transfer, for 6.016% of the thermal conductivity was taken into account. The SST turbulence model verifies its efficacy by predicting the fluid flow patterns across the absorber tubes. This study forms the basis for developing new mechanical efficiency metrics for solar collector absorber tubes, which is significant for solar energy technology development.

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Material study and weight optimization of universal joints through finite element analysis

Agarwal,

Batista,

Gurung

et al. 2024

AIP Conference Proceedings

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A Finite-Element-Analysis-Based Feasibility Study for Optimizing Pantograph Performance Using Aluminum Metal Matrix Composites

Cited by 4 publications

References 23 publications

Crashworthiness Evaluation of Electric Vehicle Battery Packs Using Honeycomb Structures and Explicit Dynamic Analysis

Crashworthiness Evaluation of Electric Vehicle Battery Packs Using Honeycomb Structures and Explicit Dynamic Analysis

Numerical Analysis of Solar Collector Absorber Tubes with C- shaped Roughness for Enhanced Heat Transfer

Material study and weight optimization of universal joints through finite element analysis

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