基于知识提炼的综合能源系统组件建模与更新方法

IF 9.6 Q1 COMPUTER SCIENCE, ARTIFICIAL INTELLIGENCE
Xueru Lin , Wei Zhong , Xiaojie Lin , Yi Zhou , Long Jiang , Liuliu Du-Ikonen , Long Huang
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引用次数: 0

摘要

在实现碳中和的背景下,传统能源生产正在向综合能源系统(IES)过渡,在供需双方都存在多种不确定性的情况下,基于模型的调度是关键所在。人工智能算法的发展解决了与模型精度相关的问题。然而,在高比例可再生能源集成的条件下,组件负荷调整需要更高的灵活性,因此组件的数学模型必须适应不断变化的运行条件。因此,运行条件变化的识别和模型的快速更新是亟待解决的问题。本研究提出了一种基于知识提炼的 IES 组件建模和更新方法。该建模方法的核心是模型的轻量化,通过知识蒸馏法实现,采用师生模式压缩复杂的神经网络模型。模型更新的触发是通过主成分分析实现的。研究还分析了模型更新延迟导致的模型误差对 IES 整体调度的影响。案例研究针对 IES 的关键部件,包括燃煤锅炉和涡轮机。结果表明,使用所提出的方法,模型更新的时间消耗减少了 76.67%。在变化条件下,与两种传统模型相比,该方法的平均偏差分别减少了 12.61 % 和 3.49 %,从而提高了模型的适应性。进一步分析了更新组件模型的必要性,因为组件模型中 1.00 % 的均方误差可能导致 0.075 MW 的功率偏差。该方法为 IES 数据建模和更新提供了实时、适应性强的支持。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Component modeling and updating method of integrated energy systems based on knowledge distillation

Component modeling and updating method of integrated energy systems based on knowledge distillation

Amid the backdrop of carbon neutrality, traditional energy production is transitioning towards integrated energy systems (IES), where model-based scheduling is key in scenarios with multiple uncertainties on both supply and demand sides. The development of artificial intelligence algorithms, has resolved issues related to model accuracy. However, under conditions of high proportion renewable energy integration, component load adjustments require increased flexibility, so the mathematical model of the component must adapt to constantly changing operating conditions. Therefore, the identification of operating condition changes and rapid model updating are pressing issues. This study proposes a modeling and updating method for IES components based on knowledge distillation. The core of this modeling method is the light weighting of the model, which is achieved through a knowledge distillation method, using a teacher-student mode to compress complex neural network models. The triggering of model updates is achieved through principal component analysis. The study also analyzes the impact of model errors caused by delayed model updates on the overall scheduling of IES. Case studies are conducted on critical components in IES, including coal-fired boilers and turbines. The results show that the time consumption for model updating is reduced by 76.67 % using the proposed method. Under changing conditions, compared with two traditional models, the average deviation of this method is reduced by 12.61 % and 3.49 %, respectively, thereby improving the model's adaptability. The necessity of updating the component model is further analyzed, as a 1.00 % mean squared error in the component model may lead to a power deviation of 0.075 MW. This method provides real-time, adaptable support for IES data modeling and updates.

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来源期刊
Energy and AI
Energy and AI Engineering-Engineering (miscellaneous)
CiteScore
16.50
自引率
0.00%
发文量
64
审稿时长
56 days
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