North Carolina Water Utility Builds Resilience with Distributed Energy Resources

IF 1.1 4区 管理学 Q4 MANAGEMENT
Kate Anderson, James Grymes, A. Newman, A. Warren
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引用次数: 3

Abstract

As the frequency and duration of grid outages increase, backup power systems are becoming more important for ensuring that critical infrastructure continues to provide essential services. Most facilities rely on diesel generators, which may be ineffective during long outages owing to limited fuel supplies and high generator failure rates. Distributed energy resources such as solar, storage, and combined-heat-and-power systems, coupled with on-site biofuel production, offer an alternative source of on-site generation that can provide both cost savings and resilience (i.e., the ability to respond to catastrophic events with longer-term consequences). A mixed-integer linear program minimizes costs and maximizes resilience at a wastewater treatment plant in Wilmington, North Carolina. We find that the plant can reduce life-cycle energy costs by 3.1% through the installation of a hybrid combined-heat-and-power, photovoltaic, and storage system. When paired with existing diesel generators, this system can sustain full load for seven days while saving $664,000 over 25 years and reducing diesel fuel use by 48% compared with the diesel-only solution. This analysis informed a decision by the Cape Fear Public Utility Authority to allocate funds for the implementation of a combined-heat-and-power system at the wastewater treatment plant in fiscal year 2023. The benefits of deploying hybrid combined-heat-and-power technologies and the utilization of on-site biofuel production extend, on a national scale, to thousands of wastewater treatment facilities and other types of critical infrastructure.
北卡罗来纳州水务公司利用分布式能源建立弹性
随着电网中断的频率和持续时间的增加,备用电源系统对于确保关键基础设施继续提供基本服务变得越来越重要。大多数设施依赖柴油发电机,由于燃料供应有限和发电机故障率高,柴油发电机在长时间停电时可能无效。分布式能源,如太阳能、储能和热电联产系统,加上现场生物燃料生产,提供了现场发电的替代来源,既可以节省成本,又可以提供弹性(即对具有长期后果的灾难性事件作出反应的能力)。在北卡罗来纳州威尔明顿的一家污水处理厂,一个混合整数线性方案使成本最小化,并使恢复能力最大化。我们发现,通过安装热电联产、光伏和存储系统,工厂可以将生命周期的能源成本降低3.1%。当与现有的柴油发电机配套使用时,该系统可以满负荷运行7天,同时在25年内节省66.4万美元,与仅使用柴油的解决方案相比,柴油的使用量减少了48%。这一分析为开普菲尔公用事业管理局的一项决定提供了依据,该决定决定在2023财年为废水处理厂的热电联产系统的实施拨款。在全国范围内,热电联产技术和现场生物燃料生产的优势扩展到成千上万的废水处理设施和其他类型的关键基础设施。
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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21.40%
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51
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