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一种用于低压直流的光伏阵列串联集成简单高效功率处理架构
A Simple and Efficient Power Processing Architecture With Series Integration of PV Array for LVDC
| 作者 | Ali Faisal Murtaza · Talal Alharbi |
| 期刊 | IEEE Transactions on Industrial Informatics |
| 出版日期 | 2025年6月 |
| 技术分类 | 光伏发电技术 |
| 技术标签 | 储能系统 |
| 相关度评分 | ★★★★★ 5.0 / 5.0 |
| 关键词 | 功率处理架构 太阳能光伏阵列 低压直流系统 DC - DC转换器 效率 |
语言:
中文摘要
本文提出了一种简单有效的功率处理架构,其中针对低压直流(LVDC)系统引入了太阳能光伏(PV)阵列的串联集成。在低压直流系统中,有两到三个电压等级(±375 V和48 V)的母线可用。这为所提出的架构的形成奠定了基础,在该架构中,直流 - 直流转换器的并联集成以及48 V和375 V电压等级之间光伏阵列的串联集成成为可能。这确保了通过直流 - 直流转换器进行的功率处理显著减少,减少幅度相当于375 - $V_{pv}$,从而提高了光伏电站的效率。此外,所提出的架构还具有以下优点。其一,不影响最大功率点跟踪;其二,由于仅处理光伏阵列部分功率,因此可以安装小尺寸的转换器;其三,由于转换器的最佳布局,其电子开关承受的电压应力较低。对所提出的架构进行了设计、分析,并与传统架构进行了比较。通过仿真研究,证实了所提出架构的运行情况及其高效率。最后,开发了实验样机,通过实际结果验证了所提出架构的响应特性。
English Abstract
In this article, a simple and effective power processing architecture has been proposed, in which the series integration of solar photovoltaic (PV) array is introduced for low voltage direct current (LVDC) systems. In LVDC systems, bus bars of two or three voltage levels ( 375 and 48 V) are available. This paves the way for the formation of proposed architecture, where the parallel integration of DC-DC converter and series integration of PV array between 48 and 375 V levels become possible. This ensures that power processing through DC-DC converter is significantly reduced by a margin equivalent to 375 - V_pv , which increases the efficiency of the PV plant. Further, the proposed architecture offers following advantages. First, there is no compromise on maximum power point tracking, second, since only fraction of PV array’s power is processed, a converter of small size can be installed, and third, the electronic switches of converter are subject to low voltage stress because of its optimum placement. The proposed architecture is designed, analyzed, and compared with conventional architecture. Through simulation studies, the operation of proposed architecture and its high efficiency have been confirmed. Finally, the experimental prototype has been developed to verify the response of proposed architecture through practical results.
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SunView 深度解读
从阳光电源的业务视角来看,这篇论文提出的LVDC系统串联光伏阵列架构具有显著的技术价值和应用潜力。该方案通过在48V和375V电压等级之间实现光伏阵列串联集成与DC-DC变换器并联集成,有效降低了功率电子器件的处理容量,这与我司一直追求的高效率、低成本解决方案理念高度契合。
从产品创新角度,该架构的核心优势在于仅需处理部分光伏功率(375-Vpv),可大幅降低变换器容量和成本,同时减少开关器件的电压应力。这为我司开发新一代分布式光伏系统和户用储能产品提供了新思路,特别是在数据中心、通信基站等LVDC应用场景中,可显著提升系统综合效率并降低LCOE。该方案在保证MPPT性能不受影响的前提下实现效率提升,符合我司"安全、高效、经济"的产品设计原则。
技术挑战方面需要关注三点:一是多电压等级母线的协调控制策略,需要开发先进的功率管理算法;二是串联光伏阵列的故障保护机制,需确保单组件故障不影响整体系统;三是该架构在国内应用需要评估与现有电网标准的兼容性。
从市场机遇看,随着数据中心、5G基站等LVDC负载的快速增长,以及分布式光伏+储能系统的普及,该技术可为我司拓展新兴市场提供差异化竞争优势。建议将此技术纳入研发路线图,开展针对性的样机验证和场景适配研究,特别关注与我司现有储能变流器产品线的协同整合可能性。