Design and Implementation of a Digital Control System for Lead Acid Battery Charging

Q2 Computer Science

International Journal of Electrical and Electronic Engineering and Telecommunications Pub Date : 2023-02-14 DOI:10.11648/j.jeee.20231101.13

Marie Danielle Fendji, Franck Mbah Kimbong, Ioannis Tsipouridis, P. Tsafack

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引用次数: 0

Abstract

: Ensuring a long battery life and satisfactory performance requires accurate charging cycles. There are three phases to the charge cycle - Constant Current Charge, Constant Voltage Charge, and Float Charge. It is usual that lead acid battery users complain about fast degrading performance because most the low cost commercially available lead Acid Battery chargers provides only single-stage charging phase which is that of constant-voltage charging phase. To ensure long service life and good performance, it is of paramount importance that all charging modes are respected. This said it is clear that the battery charger should have a certain degree of controllability over voltage and current quantities through-out the charging process. In this paper, we designed and built a lead acid battery charger to use in conjunction with a synchronous buck converter topology. After implementing and testing the system, we obtained good results in both the quantitative and qualitative analysis of the implemented system tested, a 12 V-7000mAh battery. With the help of a MCU-based digital control system containing two different control transfer functions - constant current Feedback Control and Constant Voltage Feedback Control monitoring the charging process proved possible without any overshoot. The prototype showed us an efficiency rating of 86.60%, the maximum error level was recorded at 0.05V, and there were no problems related to overshoot or transient response when testing our prototype which worked flawlessly.

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铅酸蓄电池充电数字控制系统的设计与实现

:准确的充电周期才能保证电池的使用寿命和良好的性能。充电周期有三个阶段——恒流充电、恒压充电和浮充。铅酸电池用户经常抱怨性能快速下降，因为大多数低成本的市售铅酸电池充电器只提供单级充电阶段，即恒压充电阶段。为了确保长使用寿命和良好的性能，尊重所有充电模式是至关重要的。这就是说，很明显，电池充电器应该在整个充电过程中具有一定程度的可控性过电压和电流量。在本文中，我们设计并构建了一个与同步降压转换器拓扑结构结合使用的铅酸电池充电器。经过系统的实施和测试，我们对所实施的系统测试，一个12 V-7000mAh的电池进行了定量和定性分析，取得了良好的结果。借助基于单片机的数字控制系统，该系统包含两种不同的控制传递函数-恒流反馈控制和恒压反馈控制，监测充电过程被证明是可能的，没有任何超调。样机显示我们的效率等级为86.60%，最大误差水平记录为0.05V，并且在测试我们的样机时没有出现与超调或瞬态响应相关的问题，工作完美无缺。

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来源期刊

International Journal of Electrical and Electronic Engineering and Telecommunications Engineering-Electrical and Electronic Engineering

CiteScore

5.90

自引率

0.00%

发文量

期刊介绍： International Journal of Electrical and Electronic Engineering & Telecommunications. IJEETC is a scholarly peer-reviewed international scientific journal published quarterly, focusing on theories, systems, methods, algorithms and applications in electrical and electronic engineering & telecommunications. It provide a high profile, leading edge forum for academic researchers, industrial professionals, engineers, consultants, managers, educators and policy makers working in the field to contribute and disseminate innovative new work on Electrical and Electronic Engineering & Telecommunications. All papers will be blind reviewed and accepted papers will be published quarterly, which is available online (open access) and in printed version.