Thermal Stability of Supercapacitor for Hybrid Energy Storage System in Lightweight Electric Vehicles: Simulation and Experiments

Mali, Vima; Tripathi, Brijesh

doi:10.35833/mpce.2020.000311

Cited by 11 publications

(3 citation statements)

References 34 publications

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“…Equivalent series resistance (ESR) is a measure of battery life cycles. The battery's ESR increases as the time required to fully charge and discharge the battery increases [179]. The battery's depth of discharge (DOD) is another crucial factor in reducing battery degeneration.…”

Section: Battery Degradationmentioning

confidence: 99%

A critical review on contemporary power electronics interface topologies to vehicle‐to‐grid technology: Prospects, challenges, and directions

Tasnim,

Riana,

Shams

et al. 2023

IET Power Electronics

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With the evolution of the smart grid concept, the production of electric vehicles (EVs) is predicted to rise because of environmental concerns, technological advancements, and improvements in EV management. Vehicle‐to‐grid (V2G) is an enabling, realistic, and affordable technology to cope with a large number of EVs, increase energy sustainability, provide economical solutions, satisfy user‐side consumers, and facilitate power flow to the grid. Power electronics (PE) converters, particularly bidirectional power converters, are promising interfaces for V2G infrastructure because they determine the characteristics and functionalities of V2G. Therefore, this study provides an extensive review of the characteristics, technological aspects, and visions of V2G infrastructure. This review helps to identify the current state, most recent developments, and problems related to bidirectional interface topologies and control strategies in V2G infrastructure. It further examines the classification of chargers or dischargers based on numerous factors, including limitations and impacts. Furthermore, the benefits, challenges with possible mitigation solutions, and future outlooks in the implementation of V2G technology are discussed. This review is planned to serve as a reference for existing work in V2G frameworks, PE interfacing topologies, and control strategies, and to also facilitate a guideline for future work that can be implemented to flourish V2G technology.

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Section: Battery Degradationmentioning

confidence: 99%

A critical review on contemporary power electronics interface topologies to vehicle‐to‐grid technology: Prospects, challenges, and directions

Tasnim,

Riana,

Shams

et al. 2023

IET Power Electronics

View full text Add to dashboard Cite

show abstract

“…When operated under high-temperature environments and frequent discharging and charging rates, a sharp increase in battery temperature can occur, potentially leading to thermal runaway. [4][5][6] Uneven temperature fields have been documented to ultimately yield batteries that exhibit disparate aging properties and internal resistance, thereby further compromising their capacity and lifetime. [7] Therefore, urgent and significant battery thermal management (BTM) solutions are required to ensure battery operation at the optimal temperature range with a small temperature difference.…”

Section: Introductionmentioning

confidence: 99%

Analysis of the Heat Transfer Design and Thermal Management Performance for Battery Modules Combined with Liquid‐ and Forced‐Air‐Cooling Methods

Yan,

Huizhao,

Jinqi

et al. 2023

Energy Tech

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Liquid‐cooling techniques are commonly employed for battery thermal management (BTM) in commercial vehicles and energy storage applications, typically incorporating a cooling plate positioned beneath the casing of the battery pack. However, this heat transfer structural design results in smaller temperature drop in the terminal batteries located distantly from the plate, leading to an increased temperature difference. The integration of supplementary media into BTM systems holds the potential to enhance thermal management performance, thereby offering a viable solution to this issue. Herein, a fan is incorporated into the liquid‐cooling system to induce air circulation and augment convective heat transfer onto the battery surface. In the findings, it is revealed that the implementation of a reverse airflow path beneath the cooling plate result in a temperature decreasing rate of 0.59 K min−1, indicating a notable enhancement of 23% compared to solely employing a liquid‐cooling configuration. In the results, it is demonstrated that 1) reducing the inlet temperature can effectively enhance the rate of temperature reduction and 2) increasing the fan speed can reduce the temperature difference and promote temperature uniformity. In conclusion, in this present study, comprehensive guidelines and references are provided for the future design of BTM.

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“…Unlike batteries, they have high power density, but less energy density. Low internal resistance and long life are the main advantages [7]- [9]. Thus, to attain substantial advantages in power and energy densities, a hybrid battery-UC storage system design is the most effective choice.…”

Section: Introductionmentioning

confidence: 99%

Battery-Ultracapacitor Hybrid Energy Storage System to Increase Battery Life Under Pulse Loads

et al. 2022

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This work presents a battery-ultracapacitor hybrid energy storage system (HESS) for pulsed loads (PL) in which ultracapacitors (UCs) run the pulse portion of the load while the battery powers the constant part of the load. Energy stored in UC depends upon the square of its voltage that's why an active parallel hybrid topology with two bidirectional converters (BDC) is employed here that assigns UC a separate BDC to control its voltage between an upper and lower limit as per-requisite. The other converter is connected between the battery and DC-link to provide a distinct control of the battery. A MATLAB/Simulink model is developed to minimize the factors affecting the battery life such as capacity rate (C-rate), depth of discharge (DoD), and temperature rise due to PL by controlling the operating modes of the BDCs in which voltage of the UC and state of charge (SoC) of the battery are control variables. A constant output voltage across the load is maintained through feedback control. A detailed comparative analysis, among battery-alone, UCalone, and battery-UC hybrid modes is performed which signifies that the proposed system is 55% lower in cost than its counterparts. The analysis shows that the proposed HESS reduces 50% capacity of a lead-acid battery, which is otherwise necessary to withstand the pulsating loads. Moreover, the performance of the HESS is also tested for electric vehicle (EV) load by hybridizing a high-voltage lithium-ion battery pack with a UC bank which confirms its suitability for EV applications.INDEX TERMS pulsed load, battery life improvement, ultracapacitors (UCs), bidirectional converter, hybrid energy storage system (HESS), and electric vehicles (EVs).

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Thermal Stability of Supercapacitor for Hybrid Energy Storage System in Lightweight Electric Vehicles: Simulation and Experiments

Cited by 11 publications

References 34 publications

A critical review on contemporary power electronics interface topologies to vehicle‐to‐grid technology: Prospects, challenges, and directions

A critical review on contemporary power electronics interface topologies to vehicle‐to‐grid technology: Prospects, challenges, and directions

Analysis of the Heat Transfer Design and Thermal Management Performance for Battery Modules Combined with Liquid‐ and Forced‐Air‐Cooling Methods

Battery-Ultracapacitor Hybrid Energy Storage System to Increase Battery Life Under Pulse Loads

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