利用回溯时域调度模型探讨电网信号对数据中心运行的影响

IF 3 3区 计算机科学 Q2 COMPUTER SCIENCE, HARDWARE & ARCHITECTURE
Weiqi Zhang;Line Roald;Victor Zavala
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引用次数: 0

摘要

数据中心(DC)可以通过吸收可再生能源(如风能和太阳能)来帮助电网脱碳,因为它们能够跨空间和时间转移电力负载。然而,为了利用这种负荷转移灵活性,有必要了解电网信号(碳信号和市场价格/负荷分配)如何影响直流操作。这里出现的一个障碍是缺乏可计算的直流操作模型,该模型可以捕捉直流和电网接口处出现的目标、约束和信息流。为了解决这一差距,我们提出了一种后退时域资源管理模型(一种混合整数规划模型),该模型捕获DC调度器和网格之间的资源管理层,同时考虑逻辑约束、不同类型的目标以及对即将到来的工作简档和可用计算能力的预测。我们使用我们的模型基于Microsoft Azure和MISO的公共数据进行了广泛的案例研究。我们的研究表明,DC可以提供显著的时间负荷转移灵活性,从而减少碳排放和峰值需求费用。模型和案例研究作为易于使用的Julia代码共享。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Exploring the Impacts of Power Grid Signals on Data Center Operations Using a Receding-Horizon Scheduling Model
Data centers (DCs) can help decarbonize the power grid by helping absorb renewable power (e.g., wind and solar) due to their ability to shift power loads across space and time. However, to harness such load-shifting flexibility, it is necessary to understand how grid signals (carbon signals and market price/load allocations) affect DC operations. An obstacle that arises here is the lack of computationally-tractable DC operation models that can capture objectives, constraints, and information flows that arise at the interface of DCs and the power grid. To address this gap, we present a receding-horizon resource management model (a mixed-integer programming model) that captures the resource management layer between the DC scheduler and the grid while accounting for logical constraints, different types of objectives, and forecasts of incoming job profiles and of available computing capacity. We use our model to conduct extensive case studies based on public data from Microsoft Azure and MISO. Our studies show that DCs can provide significant temporal load-shifting flexibility that results in reduced carbon emissions and peak demand charges. Models and case studies are shared as easy-to-use Julia code.
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来源期刊
IEEE Transactions on Sustainable Computing
IEEE Transactions on Sustainable Computing Mathematics-Control and Optimization
CiteScore
7.70
自引率
2.60%
发文量
54
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