Energy flexibility quantification of a tropical net-zero office building using physically consistent neural network-based model predictive control

IF 13 Q1 ENERGY & FUELS
Wei Liang , Han Li , Sicheng Zhan , Adrian Chong , Tianzhen Hong
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Abstract

Building energy flexibility plays a critical role in demand-side management for reducing utility costs for building owners and sustainable, reliable, and smart grids. Realizing building energy flexibility in tropical regions requires solar photovoltaics and energy storage systems. However, quantifying the energy flexibility of buildings utilizing such technologies in tropical regions has yet to be explored, and a robust control sequence is needed for this scenario. Hence, this work presents a case study to evaluate the building energy flexibility controls and operations of a net-zero energy office building in Singapore. The case study utilizes a data-driven energy flexibility quantification workflow and employs a novel data-driven model predictive control (MPC) framework based on the physically consistent neural network (PCNN) model to optimize the building energy flexibility. To the best of our knowledge, this is the first instance that PCNN is applied to a mathematical MPC setting, and the stability of the system is formally proved. Three scenarios are evaluated and compared: the default regulated flat tariff, a real-time pricing mechanism, and an on-site battery energy storage system (BESS). Our findings indicate that incorporating real-time pricing into the MPC framework could be more beneficial to leverage building energy flexibility for control decisions than the flat-rate approach. Moreover, adding BESS to the on-site PV generation improved the building self-sufficiency and the PV self-consumption by 17% and 20%, respectively. This integration also addresses model mismatch issues within the MPC framework, thus ensuring a more reliable local energy supply. Future research can leverage the proposed PCNN-MPC framework for different data-driven energy flexibility quantification types.

利用基于物理一致性神经网络的模型预测控制,量化热带净零能耗办公楼的能源灵活性
建筑能源灵活性在需求侧管理中发挥着至关重要的作用,可降低建筑业主的公用事业成本,实现可持续、可靠和智能电网。在热带地区实现建筑能源灵活性需要太阳能光伏发电和储能系统。然而,在热带地区利用此类技术对建筑物的能源灵活性进行量化的工作尚有待探索,而且在这种情况下还需要一个稳健的控制程序。因此,这项工作提出了一个案例研究,以评估新加坡一栋净零能耗办公楼的建筑能源灵活性控制和运行情况。案例研究利用数据驱动的能源灵活性量化工作流程,并采用基于物理一致神经网络(PCNN)模型的新型数据驱动模型预测控制(MPC)框架来优化建筑能源灵活性。据我们所知,这是首次将 PCNN 应用于数学 MPC 设置,并正式证明了系统的稳定性。我们对三种方案进行了评估和比较:默认的规范统一电价、实时定价机制和现场电池储能系统(BESS)。我们的研究结果表明,与统一费率方法相比,将实时定价纳入 MPC 框架更有利于在控制决策中利用建筑物的能源灵活性。此外,将 BESS 添加到现场光伏发电中,可将建筑自给率和光伏自耗电量分别提高 17% 和 20%。这种集成还解决了 MPC 框架内的模型不匹配问题,从而确保了更可靠的本地能源供应。未来的研究可以利用所提出的 PCNN-MPC 框架,进行不同类型的数据驱动型能源灵活性量化。
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
Advances in Applied Energy
Advances in Applied Energy Energy-General Energy
CiteScore
23.90
自引率
0.00%
发文量
36
审稿时长
21 days
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