用于并网研究的DFIG的动态相量有限元建模

IF 7.9 Q1 ENGINEERING, ELECTRICAL & ELECTRONIC IEEE Open Journal of Industry Applications Pub Date : 2023-03-10 DOI:10.1109/OJIA.2023.3254669
Mohamed A. Almozayen;Andrew M. Knight
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引用次数: 0

摘要

电力系统和电机的共模拟研究一直是一个挑战。为了将仿真时间减少到一个合理的值,电力系统建模软件包中通常使用集中参数电机模型,以避免更精确的建模方法特别是有限元方法以较低的精度为代价带来沉重的计算负担。本文中提出的技术将电力系统仿真的动态相量建模技术与有限元相结合,以在并网时对双馈感应发电机进行精确建模。与传统的时域有限元建模相比,动态相量的利用使得能够采用大的模拟时间步长,从而显著减少模拟时间。给出了所提出的建模方法的数学基础,包括发电机的铁心饱和。作者开发了自定义的C++代码来执行新的动态相量有限元算法和传统的时域有限元算法,以比较它们的精度和数值性能。由于所提出的方法结合了时域和频域,因此可以实现对转子运动建模的独特能力。旋转可以通过像在常规时域求解器中那样物理地增加转子和气隙网格来表示,通过像在频域求解器中一样使用虚拟阻塞转子方法和所提出的组合上述两种方法的方法来数学地表示旋转。讨论了三种转子旋转建模方法,并对它们的仿真结果进行了比较,为不同建模目标选择合适的建模方法提供了指导。结果表明,所提出的动态相量有限元能够在显著减少的模拟时间下产生与传统时域求解器相当的结果。
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Dynamic Phasor Finite-Element Modeling of a DFIG for Grid Connection Studies
Cosimulation studies of electric power systems and electric machines have always been a challenge. In order to reduce the simulation time to a reasonable value, lumped-parameter electric machine models are commonly used in electric power system modeling software packages to avoid the heavy computational burden of more accurate modeling methods especially finite-element method (FEM) on the expense of less accuracy. The proposed technique in this article combines the dynamic phasor modeling technique for power system simulations with the FEM to accurately model the doubly fed induction generator while connected to the grid. The utilization of dynamic phasors enables adopting large simulation time steps resulting in a significant reduction in the simulation time compared to the conventional time-domain FEM modeling. The mathematical foundation of the proposed modeling method is presented including the generator's core saturation. Custom-written C++ codes have been developed by the authors to execute the new dynamic phasor FEM algorithm and the conventional time-domain FEM in order to fairly compare their accuracy and numerical performances. As the proposed method combines time and frequency domains, a unique capability of modeling the rotor movement can be achieved. The rotation can be represented by physically incrementing the rotor and airgap mesh as in regular time-domain solvers, by mathematically representing the rotation using the virtual blocked rotor method as in frequency-domain solvers, and the proposed method of combining the two aforementioned approaches. The three methods of modeling rotor rotation are discussed, and their simulation results are compared to give a guide to choose the proper method for the different modeling targets. The results show that the proposed dynamic phasor FEM is capable of producing comparable results to the traditional time-domain solver at a substantially reduced simulation time.
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