NSF-BSF: Collaborative Research: Solids and reactive transport processes in sewer systems of the future: modeling and experimental investigation

NSF-BSF：合作研究：未来下水道系统中的固体和反应性输送过程：建模和实验研究

• 批准号: 2134747
• 负责人: Ahmed Abokifa
• 金额: $ 20.83万
• 依托单位: University of Illinois at Chicago
• 依托单位国家: 美国
• 项目类别: Standard Grant
• 财政年份: 2024
• 资助国家: 美国
• 起止时间: 2024-01-01 至 2026-12-31
• 项目状态: 未结题
• 来源: https://www.nsf.gov/awardsearch/showAward?AWD_ID=2134747&HistoricalAwards=false
• 关键词: NSF; BSF; Collaborative; Research; Solids

In the United States, there are approximately 16,000 sanitary sewer systems serving more than 190 million people through over 740,000 miles of public sewers. Sanitary sewers are underground pipes designed to deliver sewage water from residential, commercial, and industrial buildings to the city sewage treatment plants. This wastewater contains solid waste such as human excreta, soiled water from sinks, showers, and toilets, and other waste. Sanitary sewers are critical to the communities that they serve for managing and disposing of wastewater in a safe manner. Two major problems affecting these sanitary sewer systems are blockages and the formation of hydrogen sulfide, a highly toxic and corrosive gas. Sewer blockages can result in overflow of untreated contaminated wastewater into individual properties, local communities, and the environment. Sewer blockages can also lead to bad smells and the release of harmful gases, such as hydrogen sulfide, which is dangerous to human health. The goal of this NSF-BSF project is to investigate the characteristics of the solid waste that enters sewers, the factors that affect how it moves and accumulates, and the formation of hydrogen sulfide and other harmful substances in sewer systems. To advance this goal, the Principal Investigators (PIs) will use a combination of laboratory and field experiments, as well as computer modeling, to predict how solid waste and harmful substances travel in sewers. The PIs also propose to develop software tools to help track and model these processes, considering different sources of uncertainty. The successful completion of this project will benefit society through the generation of new data and models to improve the fundamental understanding of how solids move in sewers and identify vulnerabilities and potential problems that may arise from future changes in wastewater characteristics. Additional benefits to society will be achieved through student education and training including the mentoring of one undergraduate and one graduate student at the university of Texas, Austin and one graduate student at the University of Illinois at Chicago.Sewer blockages and the formation of hydrogen sulfide, a highly toxic and corrosive gas, are two critical issues that compromise the integrity of sanitary sewers and have severe economic, environmental, and public health impacts. The increased adoption of sustainable water technologies is forecasted to significantly alter the quantity and quality of the wastewater discharged into sewer systems, leading to unintended negative implications. Water demand reductions are expected to increase the deposition of solids and alter the solid-liquid biochemical processes within the sewer system, exacerbating sewer blockages and hydrogen sulfide formation. The overarching goal of this NSF-BSF project is to investigate the dynamic characteristics of domestic solids discharged to sewers, the factors that affect the transport, deposition, and accumulation of these solids, and the formation and transformation of hydrogen sulfide and other key biochemical species in sewer systems. The specific objectives of the research are to 1) conduct lab and field experiments to characterize the physical aspects of gross solids transport, deposition, and transformation in sewers; 2) develop open-source software tools to model solid-liquid biochemical interactions, enable tracking the fate and transport of key biochemical species in sewer systems, and quantify and propagate different sources of uncertainty; and 3) create a computational framework for identifying potential breakpoints due to future changes in the characteristics of wastewater discharges under various decentralized water technologies, population shifts, and changes in infiltration/inflow patterns due to climate change. The successful completion of this project will bridge the fundamental knowledge gaps in solids transport and solid-liquid biochemical processes in sewer systems and will enable identifying vulnerabilities under future uncertain long- and short-term shifts in wastewater characteristics.This award reflects NSF's statutory mission and has been deemed worthy of support through evaluation using the Foundation's intellectual merit and broader impacts review criteria.

在美国，大约有16，000个下水道系统，通过超过740，000英里的公共下水道为超过1.9亿人提供服务。生活污水管道是一种地下管道，用于将住宅、商业和工业建筑的污水输送到城市污水处理厂。这些废水包含固体废物，如人类排泄物，来自水槽，淋浴和厕所的污水以及其他废物。卫生下水道对于它们所服务的社区以安全的方式管理和处置废水至关重要。影响这些卫生下水道系统的两个主要问题是堵塞和硫化氢的形成，硫化氢是一种剧毒和腐蚀性气体。下水道堵塞可能导致未经处理的污染废水溢流到个人财产，当地社区和环境中。下水道堵塞也会导致难闻的气味和有害气体的释放，如硫化氢，这对人类健康是危险的。这个NSF-BSF项目的目标是调查进入下水道的固体废物的特征，影响其移动和积累的因素，以及下水道系统中硫化氢和其他有害物质的形成。为了推进这一目标，首席研究员将结合实验室和现场实验以及计算机建模，预测固体废物和有害物质如何在下水道中传播。PI还建议开发软件工具，以帮助跟踪和模拟这些过程，考虑不同的不确定性来源。该项目的成功完成将通过生成新的数据和模型来改善对固体如何在下水道中移动的基本理解，并确定未来废水特性变化可能产生的脆弱性和潜在问题，从而使社会受益。通过学生教育和培训，包括指导德克萨斯大学奥斯汀分校的一名本科生和一名研究生以及伊利诺伊大学芝加哥分校的一名研究生，将为社会带来额外的好处。下水道堵塞和硫化氢（一种剧毒和腐蚀性气体）的形成是两个关键问题，它们损害了卫生下水道的完整性，并具有严重的经济、环境，和公共卫生影响。预计越来越多地采用可持续的水技术将大大改变排入下水道系统的废水的数量和质量，导致意想不到的负面影响。预计水需求的减少将增加固体的沉积，改变下水道系统内的固液生化过程，加剧下水道堵塞和硫化氢的形成。这个NSF-BSF项目的总体目标是调查排放到下水道的生活固体的动态特性，影响这些固体的运输，沉积和积累的因素，以及下水道系统中硫化氢和其他关键生化物种的形成和转化。该研究的具体目标是：1）进行实验室和现场实验，以表征污水中总固体运输，沉积和转化的物理方面; 2）开发开源软件工具，以模拟固液生化相互作用，能够跟踪污水系统中关键生化物种的命运和运输，并量化和传播不同来源的不确定性;以及3）创建一个计算框架，用于确定由于各种分散式水技术下废水排放特性的未来变化、人口转移以及由于气候变化导致的渗透/流入模式的变化而导致的潜在断点。该项目的成功完成将弥补污水系统中固体运输和固液生化过程的基本知识差距，并将能够在未来不确定的长期和短期废水特性变化下识别脆弱性。该奖项反映了NSF的法定使命，并被认为值得通过使用基金会的智力价值和更广泛的影响审查标准进行评估来支持。