A multifunctional rooftop unit for direct air capture†‡

IF 3.5 Q3 ENGINEERING, ENVIRONMENTAL
Keju An, Jamieson Brechtl, Stephen Kowalski, Cheng-Min Yang, Michelle K. Kidder, Costas Tsouris, Christopher Janke, Meghan Lamm, Katie Copenhaver, Josh Thompson, Tugba Turnaoglu, Brian Fricke, Kai Li, Xin Sun and Kashif Nawaz
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Abstract

Direct air capture (DAC), which captures CO2 from ambient air, is a critical technology to reduce greenhouse gases in the atmosphere in order to avoid climate disasters. Due to the relatively low concentration of CO2 (400 ppm), a large amount of air needs to be moved through DAC devices, which requires lots of energy. Currently, DAC technologies are deployed mainly in centralized systems and require extensive infrastructure and initial capital cost. A potential solution is to utilize existing infrastructure for DAC. In this study, we propose a distributed DAC system that utilizes existing commercial rooftop heating and air conditioning (HVAC) units to capture CO2 from the air. There are approximately 15 million such units already installed on commercial buildings in the United States, and they move a large amount of air every day. Adding DAC functionality to these units will significantly reduce the cost of infrastructure and operation. A modular approach was used to introduce DAC into a rooftop unit. Modules filled with triethylenetetramine-functionalized polyacrylonitrile sheets were developed and installed on the condenser coil side of the rooftop unit. The rooftop unit with DAC functions effectively captured CO2 from the air, and the addition of the DAC modules had little effect on the unit's original functionality. A preliminary techno-economic analysis was also conducted, and the results potentially suggest that utilizing existing commercial rooftop units for carbon capture is a feasible approach to reducing greenhouse gases.

Abstract Image

直接捕获空气的多功能屋顶装置
直接空气捕集(DAC)可以捕集环境空气中的二氧化碳,是减少大气中温室气体以避免气候灾难的关键技术。由于二氧化碳的浓度相对较低(400 ppm),大量空气需要通过 DAC 设备,这就需要大量能源。目前,DAC 技术主要部署在集中式系统中,需要大量基础设施和初始资本成本。一个潜在的解决方案是利用现有的基础设施来实现 DAC。在这项研究中,我们提出了一种分布式 DAC 系统,利用现有的商业屋顶供暖和空调(HVAC)装置来捕获空气中的二氧化碳。美国的商业建筑上已经安装了大约 1500 万台此类设备,它们每天输送大量的空气。为这些设备增加 DAC 功能将大大降低基础设施和运营成本。我们采用模块化方法将 DAC 引入屋顶设备。我们开发了填充三乙烯四胺功能化聚丙烯腈片材的模块,并将其安装在屋顶机组的冷凝器盘管一侧。具有 DAC 功能的屋顶机组有效地捕获了空气中的二氧化碳,而且增加 DAC 模块对机组的原有功能几乎没有影响。此外,还进行了初步的技术经济分析,结果可能表明,利用现有商业屋顶机组进行碳捕集是减少温室气体的可行方法。
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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CiteScore
1.90
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0.00%
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