可再生能源普及率高的输电网中发电的分布式控制

Krishnamurthy Dvijotham, S. Backhaus, M. Chertkov
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引用次数: 6

摘要

电网频率与标称频率的偏差是发电与负荷之间全局不平衡的一个指标。两种类型的控制,分布式比例控制和集中积分控制,目前用于保持频率偏差小。虽然发电负荷不平衡可以非常局部,但这两种控制主要依赖于频率偏差作为其输入。控制的时间尺度要求每隔几秒将集中积分控制的输出传送到远处的发电机。我们重新考虑了这种控制/通信架构,并提出了一种利用参数化反馈策略的混合方法,该策略可以以完全分布式的方式实现,因为这些策略的输入是每个生成器的本地可观察值。利用负荷预测和代表未来可能情景的时间间歇发电的集合,我们执行集中式离线随机优化以选择特定于发电机的反馈参数。这些参数只需要在每个控制周期(在我们的模拟中为60分钟)向生成器传递一次。我们表明,将本地功率流作为反馈输入是至关重要的,并且可以将频率偏差减少十倍。我们在博纳维尔电力管理局(BPA)的详细传输模型上演示了我们的控制。我们的研究结果表明,一种智能的自动和分布式控制,依靠先进的离线和系统范围的计算,不经常与被控制的发电机通信,可能是一种可行的控制和通信架构解决方案。这种架构适用于由于时间间歇发电的增加而导致发电负荷不平衡预计会增加的未来情况。
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Distributed control of generation in a transmission grid with a high penetration of renewables
Deviations of grid frequency from the nominal frequency are an indicator of the global imbalance between generation and load. Two types of control, a distributed proportional control and a centralized integral control, are currently used to keep frequency deviations small. Although generation-load imbalance can be very localized, both controls primarily rely on frequency deviation as their input. The time scales of control require the outputs of the centralized integral control to be communicated to distant generators every few seconds. We reconsider this control/communication architecture and suggest a hybrid approach that utilizes parameterized feedback policies that can be implemented in a fully distributed manner because the inputs to these policies are local observables at each generator. Using an ensemble of forecasts of load and time-intermittent generation representative of possible future scenarios, we perform a centralized off-line stochastic optimization to select the generator-specific feedback parameters. These parameters need only be communicated to generators once per control period (60 minutes in our simulations). We show that inclusion of local power flows as feedback inputs is crucial and reduces frequency deviations by a factor of ten. We demonstrate our control on a detailed transmission model of the Bonneville Power Administration (BPA). Our findings suggest that a smart automatic and distributed control, relying on advanced off-line and system-wide computations communicated to controlled generators infrequently, may be a viable control and communication architecture solution. This architecture is suitable for a future situation when generation-load imbalances are expected to grow because of increased penetration of time-intermittent generation.
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