Optimization of Hexagonal Structure for Enhancing Heat Transfer in Storage System

Raźny, Natalia; Dmitruk, Anna; Nemś, Artur; Nemś, Magdalena; Naplocha, K.

doi:10.3390/ma16031207

Cited by 2 publications

(1 citation statement)

References 29 publications

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“…Temperature sensors are placed throughout the module in both cases for real-time monitoring. Both designs enhance thermal management, with the honeycomb-like structure offering efficient heat transfer due to its hexagonal grid configuration, while the common module structure provides simplicity and ease of maintenance as shown in (figure 2(c)) [50].…”

Section: Arctactural Design Of Battery Modulesmentioning

confidence: 99%

Investigations of phase change materials in battery thermal management systems for electric vehicles: a review

Dolla,

Fetene

2024

Mater. Res. Express

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Taking advantage of electric vehicles' low pollution, the world is changing its face to electric vehicle (EV) production. As EVs rely heavily on specialized batteries, it's important to manage them safely and properly to prevent thermal runaway. High ambient temperatures and varied charging/discharging rates increases battery temperature. To address these challenges, Battery Thermal Management System (BTMS) come into play. This work focuses on passive cooling in BTMS, which is one of two categories of BTMS, with the other being active cooling using liquid-air systems. Passive BTMS has gained prominence in research due to its cost-effectiveness, reliability, and energy efficiency, as it avoids the need for additional components like pumps/fans. This article specifically discusses recent experimental studies regarding phase change material (PCM)-based thermal management techniques for battery packs. It explores methods for enhancing thermal conductivity in PCMs and identifies methodologies for BTMS experiments using PCMs. Also recommends the importance of optimization techniques like machine learning, temperature sensors, and state-of-charge management, to ensure accuracy and uniform temperature distribution across the pack. While paraffin wax has been a popular choice in experimental studies for its capacity to absorb and release heat during phase transitions, as a matter of its low thermal conductivity (0.2 to 0.3 Wk-1m-1) limits reaction in rapid charging/discharging of batteries. So integration with highly thermally conductive additives is recommended. Additives such as heat pipes offer superior thermal conductivity compared to expanded graphite (5 to 200 Wk-1m-1). As a result, the integration of heat pipes further reduces the temperature of battery by 28.9% in addition to the reduction of 33.6% by pure PCMs in time of high charge/discharge rates (5C to 8C). So high-conductivity additives correlate directly with improved thermal performance and are essential for maintaining optimal battery temperatures and overall reliability in EV battery packs.

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Section: Arctactural Design Of Battery Modulesmentioning

confidence: 99%