Grid-connected solar photovoltaic-fed brushless DC motor drive for water pumping system using colliding body optimization technique

IF 0.8 4区工程技术 Q4 ENGINEERING, ELECTRICAL & ELECTRONIC

Circuit World Pub Date : 2022-08-04 DOI:10.1108/cw-09-2021-0252

B. N. Kar, P. Samuel, J. K. Pradhan, A. Mallick

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引用次数: 0

Abstract

Purpose This paper aims to present an improvement to the power quality of the grid by using a colliding body optimization (CBO) based proportional-integral (PI) compensated design for a grid-connected solar photovoltaic-fed brushless DC motor (BLDC)-driven water pumping system with a bidirectional power flow control. The system with bidirectional power flow allows driving the pump at full proportions uninterruptedly irrespective of the weather conditions and feeding a grid when water pumping is not required. Design/methodology/approach Here, power quality issue is taken care of by the optimal generation of the duty cycle of the voltage source converter. The duty cycle is optimally generated by optimal selection of the gains of the current controller (i.e. PI), with the CBO technique resulting in a nearly unity power factor as well as lower total harmonic distortion (THD) of input current. In the CBO technique, the gains of the PI controller are considered as agents and collide with each other to obtain the best value. The system is simulated using MATLAB/Simulink and validated in real time with OPAL RT simulator, OP5700. Findings It was found that the power quality of grid using the CBO technique has improved much better than the particle swarm optimization and Zeigler–Nichols approach. The bidirectional flow of control of VSC allowed for optimum resource utilization and full capacity of water pumping whatever may be weather conditions. Originality/value Improved power quality of grid by optimally generation of the duty cycle for the proposed system. A unit vector tamplate generation technique is used for bidirectional power transfer.

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采用碰撞体优化技术的并网太阳能光伏馈电无刷直流电机驱动抽水系统

摘要本文采用基于碰撞体优化(CBO)的比例积分(PI)补偿设计，对具有双向潮流控制的并网太阳能光伏供电无刷直流电机(BLDC)驱动的抽水系统进行改进，以改善电网的电能质量。该系统具有双向功率流，无论天气状况如何，都可以不间断地以最大比例驱动泵，并在不需要抽水时为电网供电。设计/方法/途径在这里，电能质量问题是由电压源变换器的最优占空比产生来解决的。通过优化选择电流控制器(即PI)的增益来最佳地产生占空比，而CBO技术可以产生几乎一致的功率因数以及较低的输入电流总谐波失真(THD)。在CBO技术中，PI控制器的增益被视为代理，它们相互碰撞以获得最佳值。利用MATLAB/Simulink对系统进行了仿真，并利用OPAL RT仿真器OP5700对系统进行了实时验证。研究结果表明，采用CBO技术的电网电能质量比采用粒子群优化和Zeigler-Nichols方法的电网电能质量有明显的改善。VSC的双向流动控制允许最佳的资源利用和抽水的全部能力，无论可能是天气条件。独创性/价值通过优化系统的占空比来改善电网的电能质量。采用单位矢量模板生成技术实现双向功率传输。

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

Circuit World 工程技术-材料科学：综合

CiteScore

2.60

自引率

0.00%

发文量

审稿时长

>12 weeks

期刊介绍： Circuit World is a platform for state of the art, technical papers and editorials in the areas of electronics circuit, component, assembly, and product design, manufacture, test, and use, including quality, reliability and safety. The journal comprises the multidisciplinary study of the various theories, methodologies, technologies, processes and applications relating to todays and future electronics. Circuit World provides a comprehensive and authoritative information source for research, application and current awareness purposes. Circuit World covers a broad range of topics, including: • Circuit theory, design methodology, analysis and simulation • Digital, analog, microwave and optoelectronic integrated circuits • Semiconductors, passives, connectors and sensors • Electronic packaging of components, assemblies and products • PCB design technologies and processes (controlled impedance, high-speed PCBs, laminates and lamination, laser processes and drilling, moulded interconnect devices, multilayer boards, optical PCBs, single- and double-sided boards, soldering and solderable finishes) • Design for X (including manufacturability, quality, reliability, maintainability, sustainment, safety, reuse, disposal) • Internet of Things (IoT).