Bidirectional DC-DC converter and improved electrical vehicle dynamic response control

IF 0.6 Q4 ENGINEERING, ELECTRICAL & ELECTRONIC

Recent Advances in Electrical & Electronic Engineering Pub Date : 2023-08-08 DOI:10.2174/2352096516666230808155657

S. P, A. K, M. K, Nissy Joseph, Roshan M

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引用次数: 0

Abstract

In automotive applications where bidirectional power flow is necessary to lighten the power system, dual active bridge (DAB) converters are frequently employed. Variations in the required output voltage, erratic input voltage, and shifting loads all have an impact on this converter. As a result, converter performance has to be improved. To increase efficiency, the current stress of the DC-DC converter must be optimised. This paper proposes a control scheme for the coupled inductor bidirectional DC-DC (CIB DC-DC) converter utilising both model predictive control (MPC) and a proportional-integral (PI) controller. The integration of these control techniques aims to enhance the performance and efficiency of the converter. The MPC algorithm is employed to predict the converter's future behaviour based on a dynamic model, taking into account system constraints and performance criteria. By optimising the control action over a finite time horizon, the MPC algorithm ensures an optimal response, considering the current state and anticipated changes. Additionally, a PI controller is incorporated to augment the control strategy. The proportional component of the PI controller enables a fast initial response to the error between the desired and actual converter outputs. The integral component eliminates steady-state errors and provides robustness against disturbances, resulting in improved overall system performance. The proposed control scheme is implemented and evaluated through simulations and experimental tests on a prototype converter. The results demonstrate the effectiveness of the combined MPC and PI controller approach. The coupled inductor bidirectional DC-DC (CIB DC-DC) converter using MPC can provide precise control of power flow between two voltage domains, enabling efficient bidirectional power transfer. The predictive capabilities of MPC allow it to adapt to varying load conditions and respond quickly to changes, ensuring stable operation and accurate regulation of voltage and current. Overall, the coupled inductor bidirectional DC-DC converter controlled using MPC over PI offers improved performance, efficiency, and flexibility compared to traditional control methods. MPC can handle the complex dynamics response and non-linear characteristics of the converter, making it suitable for bi-directional vehicle charging applications, where precise control and high efficiency can be achieved.

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双向DC-DC变换器与改进的电动汽车动态响应控制

在汽车应用中，双向功率流需要减轻电力系统，双有源桥(DAB)转换器经常被采用。所需输出电压的变化、不稳定的输入电压和移位的负载都对该变换器产生影响。因此，必须提高转换器的性能。为了提高效率，必须优化DC-DC变换器的电流应力。本文提出了一种利用模型预测控制(MPC)和比例积分(PI)控制器的耦合电感双向DC-DC (CIB)变换器的控制方案。这些控制技术的集成旨在提高变换器的性能和效率。在考虑系统约束和性能标准的基础上，采用MPC算法基于动态模型预测变换器的未来行为。通过在有限的时间范围内优化控制动作，MPC算法确保了考虑当前状态和预期变化的最佳响应。此外，还加入了PI控制器来增强控制策略。PI控制器的比例分量能够对期望和实际转换器输出之间的误差进行快速初始响应。积分组件消除了稳态误差，并提供了对干扰的鲁棒性，从而提高了系统的整体性能。通过样机的仿真和实验测试，对所提出的控制方案进行了实现和评价。结果表明，MPC和PI控制器相结合的控制方法是有效的。采用MPC的耦合电感双向DC-DC (CIB DC-DC)变换器可以精确控制两个电压域之间的功率流，实现高效的双向功率传输。MPC的预测能力使其能够适应不同的负载条件并快速响应变化，确保稳定运行和准确调节电压和电流。总体而言，与传统控制方法相比，使用MPC控制的耦合电感双向DC-DC转换器提供了更好的性能，效率和灵活性。MPC可以处理复杂的动态响应和转换器的非线性特性，使其适用于双向车辆充电应用，可以实现精确控制和高效率。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Recent Advances in Electrical & Electronic Engineering ENGINEERING, ELECTRICAL & ELECTRONIC-

CiteScore

1.70

自引率

16.70%

发文量

101

期刊介绍： Recent Advances in Electrical & Electronic Engineering publishes full-length/mini reviews and research articles, guest edited thematic issues on electrical and electronic engineering and applications. The journal also covers research in fast emerging applications of electrical power supply, electrical systems, power transmission, electromagnetism, motor control process and technologies involved and related to electrical and electronic engineering. The journal is essential reading for all researchers in electrical and electronic engineering science.