Ravikant Nanwatkar,
Sonali Sabale,
Deepak Watvisave,
Vishwajit Gaike,
- Research Scholer, STES’s NBNSTIC, Ambegaon, SPPU, Pune, India
- Research Scholar, Department of Mechanical Engineering, NBNSTIC, Ambegaon, Savitribai Phule Pune University, Pune, India
- Research Guide, Department of Mechanical Engineering, MKSSS’s Cummin’s College of Engineering, SPPU, Pune, India
- Assistant Professor, Department of Mechanical Engineering, STES’s NBNSTIC, Ambegaon, Pune, India
Abstract
The creation of sophisticated simulation models has been made necessary by the need for reliable and effective battery packs in energy storage systems and electric vehicles. This study focuses on the simulation and analysis of battery packs using a multi-scale multi-domain battery model. The model enables a thorough knowledge of battery pack behavior across a range of operating situations by integrating the electricity, thermal, and mechanical domains. Multi-scale modeling bridges the micro-level electrochemical processes with macro-level pack performance, enabling the prediction of key parameters such as temperature distribution, state of charge (SOC), and degradation patterns. A robust simulation framework is developed to evaluate the impact of environmental factors, dynamic load conditions, and thermal management strategies on battery pack efficiency and lifespan. The results demonstrate significant improvements in accuracy over conventional single-domain models, particularly in predicting thermal runaway scenarios and ensuring optimal energy utilization. This research highlights the potential of multi-scale multi-domain modeling as a critical tool for designing next-generation battery packs with enhanced performance, safety, and durability. The findings serve as a valuable resource for engineers and researchers in optimizing battery systems for electric vehicles and renewable energy applications. The goal of future development was to incorporate immediate information for analytical storage and improved system consistency.
Keywords: Simulation, battery packs, multi-scale multi-domain model, temperature distribution, state of charge, electric vehicles
[This article belongs to International Journal of Electro-Mechanics and Material Behaviour ]
Ravikant Nanwatkar, Sonali Sabale, Deepak Watvisave, Vishwajit Gaike. Simulation and Analysis of Battery Pack Using the Multi-Scale Multi-Domain Battery Model. International Journal of Electro-Mechanics and Material Behaviour. 2024; 02(02):31-46.
Ravikant Nanwatkar, Sonali Sabale, Deepak Watvisave, Vishwajit Gaike. Simulation and Analysis of Battery Pack Using the Multi-Scale Multi-Domain Battery Model. International Journal of Electro-Mechanics and Material Behaviour. 2024; 02(02):31-46. Available from: https://journals.stmjournals.com/ijemb/article=2024/view=191855
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| Volume | 02 |
| Issue | 02 |
| Received | 15/12/2024 |
| Accepted | 16/11/2024 |
| Published | 31/12/2024 |
| Publication Time | 16 Days |
