The present battery technology employed in electric vehicles (EVs) faces several critical challenges. Firstly, the limited operation range of EVs remains a major concern for potential users, as it affects their ability to travel long distances without the need for frequent recharging. Additionally, long charging times are inconvenient for users and can hinder the widespread adoption of EVs. Alongside these limitations, the possibility of battery faults such as thermal runaway, can lead to safety risks including fires or explosions.
These factors, including technical concerns about battery health and safety, the need for frequent recharging, and long charging times, could discourage potential users from adopting EVs. Furthermore, EV batteries experience degradation over time, resulting in decreased performance and battery lifespan reduction. It leads to an increase in maintenance and accident risk for EV owners.
As a promising solution to these issues, the IoB is a networked system that utilizes the principles of the Internet-of-Things (IoT) to gather data from EV batteries. This data is subsequently transmitted to a cloud server, where it is utilized for battery state estimation, predictive analytics, and fault diagnosis. In contrast to traditional battery management systems (BMS), IoB leverages advanced technologies like IoT, cloud computing, and machine learning to provide intelligent battery management.
The IoB can be defined as an integrated system that uses the IoT and cloud computing technology to monitor and manage batteries. IoB systems can collect data from batteries in real-time, such as voltage, current, temperature, and other parameters. This data can be used to analyze battery health and performance, identify potential faults, and optimize battery usage. IoB systems can also be used to remotely control batteries. This can help to improve battery efficiency and extend battery life.
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The IoB comprises three main components, battery systems, IoT gateway, and cloud platform, and two additional components, i.e. BMS and wireless module, which are integrated inside the battery systems. Firstly, battery systems form the foundational layer of the IoB architecture, particularly within the context of EVs. Secondly, the wireless module is a critical component of the IoB system for EVs. Thirdly, the IoT gateway serves as a bridge between the wireless module and the cloud platform, ensuring safe and efficient transmission of data. Finally, the cloud platform provides a centralized hub for storing, processing, and analyzing battery data collected from various EVs.
Machine learning is a powerful tool that can be used to improve the efficiency and effectiveness of IoB systems. By analyzing data and learning from patterns, machine learning can help IoB systems make more informed decisions about battery management, charging, usage, and vehicle management. This can lead to improved battery performance, increased range, and reduced costs for EV owners. Machine learning approaches can be broadly classified into three maincategories: supervised learning, unsupervised learning, and reinforcement learning.
The IoB present numerous promising opportunities, particularly for the EV industry. This digital technology promise benefits such as ongoing battery health checks, improved energy management, state estimation, prediction, and faultdiagnosis, significantly transforming the landscape of EV technology.
However, implementing the IoB in EVs presents a number of challenges. The innovative integration of IoT technologies within the BMS of EVs presents a wide range of challenging issues that need to be thoroughly addressed for the technology to achieve a reliable state and widespread use. One of the most prominent concerns in the IoB domain is the security of battery data. Another significant challenge lies in the compatibility between different systems. Lastly, the large-scale application of IoB in EVs comes with its own set of technical complexities.
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In the future, more research and development will be needed to fully realize the potential of the IoB and optimize battery use in EVs. Future efforts should focus on addressing the challenges, such as data security and system compatibility. Additionally, research should explore the potential role of artificial intelligence and machine learning in enhancing the efficiency and effectiveness of IoB systems. The IoB has the potential to transform the EV industry, but realizing this potential will depend on addressing these challenges and seizing the opportunities it offers.
