最优开环控制从正常到主动短路操作的快速过渡

2021 23rd European Conference on Power Electronics and Applications (EPE'21 ECCE Europe) Pub Date : 2021-09-06 DOI:10.23919/epe21ecceeurope50061.2021.9570445

Philipp Wagner, Michèle Hirsch, G. Götting, H. Reuss

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引用次数: 0

摘要

一种快速过渡到安全状态的新方法，即基于最优控制的有源短路(ASC)，可以防止直流链路电压和相电流超过临界极限。在切换到ASC之前，该方法假设逆变器和永磁同步电机仍在工作，将永磁同步电机(PSM)控制到稳态短路工作点。为了设计最优控制模式，有两种优化问题公式是有用的。通过找到最优的直流电压模式，可以最小化临界直流电压超调。如果不必考虑直流链路电压，则可以使用简化的时间最优dq-电压模式。仿真结果和实验结果表明，该方法在基本速度和弱场面积上都得到了验证;并将其与硬asc和软asc等传统方法进行比较。

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Optimal open loop control for a fast transition from normal to active-short-circuit operation

A novel approach for a fast transition to the safe state i.e. active-short-circuit (ASC) based on optimal control prevents the dc-link voltage and the phase currents from exceeding critical limits. Before switching to the ASC, the novel approach controls the permanent-magnet synchronous machine (PSM) to the steady-state short-circuit operational point by assuming the inverter and PSM are still functioning. To design an optimal control pattern, two optimization problem formulations are useful. By finding the dc-link optimal voltage pattern, a critical dc-link voltage overshoot can be minimized. A simplified time-optimal dq-voltage pattern can be used if the dc-link voltage does not have to be taken into account. Simulation results as well as experimental results demonstrate the new approach both in base-speed and field-weakening-area; and compare it to conventional methods like Hard-ASC and Soft-ASC.

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来源期刊

2021 23rd European Conference on Power Electronics and Applications (EPE'21 ECCE Europe)

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