A Smart High-Voltage Cell Detecting and Equalizing Circuit for LiFePO4 Batteries in Electric Vehicles

Moghaddam, Ali Farzan; Bossche, Alex Van den

doi:10.3390/app9245391

Cited by 5 publications

(3 citation statements)

References 28 publications

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“…Passive and active balancing strategies can be distinguished. If a battery cell is replaced but does not have the same charge as the others, the battery will not be destroyed, but it will take more time to equalize, as stated by the authors in [45]. To finish out the monitoring infrastructure, a new Bluetooth-based smart-monitoring system and a mobile application built with "MIT app inventor 2" track the voltage levels of individual cells.…”

Section: International Journal Of Energy Researchmentioning

confidence: 99%

Switched-Resistor Passive Balancing of Li-Ion Battery Pack and Estimation of Power Limits for Battery Management System

Kumar

Rao

Singh

et al. 2023

International Journal of Energy Research

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The battery pack performance and expected lifespan are crucial in electric vehicle applications. Balancing the charge on a battery pack connected in series and parallel is crucial due to manufacturing discrepancies and distinct performance of each cell in a standard battery pack. In this paper, a switched-resistor passive balancing-based method is proposed for balancing cells in a battery management system (BMS). The value of the available voltage at the battery cell terminals is balanced using resistors in an electrical circuit, and the excess voltage is eliminated. The cell balancing outcome demonstrates that the electrical circuit can maintain an even voltage across each cell. The procedure of balancing involves individually adjusting each cell’s level of charge. Passive balancing releases energy as heat by draining charge from cells that have too much charge. A passive cell balancer is a cost-effective solution and easy to install, but due to thermal loss from a resistor, it has a low energy efficiency for cell balancing and necessitates a lengthy balancing process. This passive cell balancer is an effective and reliable method for low-power devices and portable applications such as electrical vehicles. The power limits during charging and discharging are estimated using the bisection method.

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Section: International Journal Of Energy Researchmentioning

confidence: 99%

Switched-Resistor Passive Balancing of Li-Ion Battery Pack and Estimation of Power Limits for Battery Management System

Kumar

Rao

Singh

et al. 2023

International Journal of Energy Research

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“…Leakage current is mainly caused by the electronic equipment of the battery monitoring system, which requires a permanent connection to the battery and contributes significantly to the discharge losses. [ 21,22 ] Considering that the individual cells in the battery pack have different leakage current levels, the leakage current of every single cell is set to be randomly and evenly distributed between 10 and 12 mA, as shown in Figure 5d. The current flowing through the battery cell can be calculated by the equation

{I}_c = I + {I}_{leak}

, where

{I}_{leak}

is the leakage current of the single cell.…”

Section: Factors Modelingmentioning

confidence: 99%

Simulation of Factor on SOC Inconsistency within a Series‐Connected Lithium‐Ion Battery Pack

Zhang

Yang

Chi

2022

Advcd Theory and Sims

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This paper outlines a new simulation approach to study the effect of factors on the state of charge (SOC) consistency of Li‐ion battery packs. The proposed method is based on a system model and the Monte Carlo method. The system model includes 100 serial connected equivalent circuit models and their respective parameters. This paper divides the internal and external factors into two categories: independent factors such as internal resistance, capacity, Coulombic efficiency, leakage current, and comprehensive factors related to temperature. The Monte Carlo method simulates the differences and distribution of independent factors among cells. Temperature‐dependent factors are modeled with empirical formulas. Simulation results show that the main factors affecting SOC consistency are differences in battery temperature, leakage current, and Coulombic efficiency. Meanwhile, slight differences in capacity and internal resistance have little effect on SOC inconsistency. Furthermore, this paper demonstrates the effectiveness of the system model.

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“…They can be integrated into an electronic device, such as a microwave, which has all the components of the power supply inside the unit, or can be external, such as for notebooks and smartphones [2]. They can be part of external units for electric vehicles (EVs), or EV chargers [3,4], an they can be modulated, e.g., in a desktop computer power supply [5]. This type of power supply has a wide range of voltage outputs, can be remotely controlled, and its form factor allows it to be easily replaced [6,7].…”

Section: Introductionmentioning

confidence: 99%

Low-Cost/High-Precision Smart Power Supply for Data Loggers

et al. 2022

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This paper presents a low-cost/high-precision smart power supply for application on data loggers. The microprocessor unit is the brain of the system and manages the events and was optimized to provide electrical energy to the electronic devices under normal operation and under the presence of disruptive events. The measurements showed that when switching either from battery to AC or from AC to battery, neither caused the shutdown of the power supply nor affected the behavior of the power supply. The power supply was able to charge 80% of the battery on a fast recharge of 1 h and the remaining 20% on a slow recharge of 2 h. The current allocated to the battery did not affect the operation of the power supply. The tests also showed that the power supply was able to transmit relevant information about its operation to external computers through a serial connection. This information includes the voltages at the battery and at the output of the voltage regulators, the voltage level of the AC network, the level of the battery charge and if it was being recharged, the current being drained, the internal temperatures at two locations (one measured on the resistor that limits battery charge and another measured on the output diode of the regulators), and whether the cooling system is being used. The total cost of this smart power supply is less than $150, demonstrating good potential for its popularization.

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A Smart High-Voltage Cell Detecting and Equalizing Circuit for LiFePO4 Batteries in Electric Vehicles

Cited by 5 publications

References 28 publications

Switched-Resistor Passive Balancing of Li-Ion Battery Pack and Estimation of Power Limits for Battery Management System

Switched-Resistor Passive Balancing of Li-Ion Battery Pack and Estimation of Power Limits for Battery Management System

Simulation of Factor on SOC Inconsistency within a Series‐Connected Lithium‐Ion Battery Pack

Low-Cost/High-Precision Smart Power Supply for Data Loggers

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