Model-Data-Driven Approach for Achieving Decoupled Power Flow and Its Application in Asymmetric Bipolar DC Distribution Networks

IF 4.2 2区工程技术 Q2 ENGINEERING, ELECTRICAL & ELECTRONIC

IEEE Transactions on Industry Applications Pub Date : 2025-01-15 DOI:10.1109/TIA.2025.3529803

Yiyao Zhou;Qianggang Wang;Chao Lei;Jianquan Liao;Tao Huang;Yuan Chi;Niancheng Zhou

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引用次数: 0

Abstract

Bipolar DC distribution networks (Bi-DCDNs) offer a promising alternative to medium and low voltage distribution networks by enhancing both the loadability and the access capability of renewable energy sources. However, coupled power flow in asymmetric Bi-DCDNs poses challenges for system-level optimal operation problems. Hence, this paper proposes a model-date-driven decoupling framework and employs it to construct the static voltage stability region (SVSR), a representative operational challenge in asymmetric Bi-DCDNs. More specifically, the model-driven approach defines the decoupling coefficient and derives its analytical expression through branch flow analysis. The expression denotes a parametric equation governing pole voltage, functioning as a posteriori indicator of the state of Bi-DCDNs. This equation manifests as a highly nonlinear expression, which can be further determined through a data-driven approach. Various operational scenarios of Bi-DCDNs are simulated using Monte Carlo sampling, without making assumptions about the distribution of loads. The distribution of the decoupling coefficient is derived from power flow calculations, with the decoupling coefficient determined as the expected value within an acceptable confidence interval. Subsequently, the optimal power flow problem for decoupled Bi-DCDNs is formulated, serving as the basis for constructing the SVSR of Bi-DCDNs. The numerical results indicate that the proposed decoupling framework achieves both computational efficiency and accuracy. Furthermore, it exhibits advantageous applications for asymmetric operational Bi-DCDNs.

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模型数据驱动的潮流解耦方法及其在非对称双极直流配电网中的应用

双极直流配电网（Bi-DCDN）通过提高可再生能源的可负载性和接入能力，为中低压配电网提供了一种前景广阔的替代方案。然而，不对称双极直流配电网中的耦合功率流给系统级优化运行问题带来了挑战。因此，本文提出了一个模型日期驱动的解耦框架，并将其用于构建静态电压稳定区域 (SVSR)，这是非对称 Bi-DCDN 中具有代表性的运行难题。更具体地说，模型驱动方法定义了去耦系数，并通过支流分析推导出其分析表达式。该表达式表示一个控制极点电压的参数方程，可作为 Bi-DCDN 状态的后验指标。该方程表现为高度非线性表达，可通过数据驱动方法进一步确定。在不假设负载分布的情况下，使用蒙特卡洛采样模拟了 Bi-DCDN 的各种运行情况。解耦系数的分布来自功率流计算，解耦系数被确定为可接受置信区间内的预期值。随后，提出了解耦 Bi-DCDN 的最优功率流问题，作为构建 Bi-DCDN SVSR 的基础。数值结果表明，所提出的解耦框架实现了计算效率和准确性。此外，它还在非对称运行的 Bi-DCDN 中展现出优势应用。

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

IEEE Transactions on Industry Applications 工程技术-工程：电子与电气

CiteScore

9.90

自引率

9.10%

发文量

747

审稿时长

3.3 months

期刊介绍： The scope of the IEEE Transactions on Industry Applications includes all scope items of the IEEE Industry Applications Society, that is, the advancement of the theory and practice of electrical and electronic engineering in the development, design, manufacture, and application of electrical systems, apparatus, devices, and controls to the processes and equipment of industry and commerce; the promotion of safe, reliable, and economic installations; industry leadership in energy conservation and environmental, health, and safety issues; the creation of voluntary engineering standards and recommended practices; and the professional development of its membership.