Fundamental Studies on Dynamic Membrane Bioreactor-Based Processes for Wastewater Treatment in Cold Regions

寒冷地区动态膜生物反应器废水处理基础研究

• 批准号: RGPIN-2020-06004
• 负责人: Xue, Jinkai
• 金额: $ 1.89万
• 依托单位: University of Regina
• 依托单位国家: 加拿大
• 项目类别: Discovery Grants Program - Individual
• 财政年份: 2020
• 资助国家: 加拿大
• 起止时间: 2020-01-01 至 2021-12-31
• 项目状态: 已结题
• 来源: https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=718150
• 关键词: Fundamental; Studies; Dynamic; Membrane; Bioreactor

As a low-cost derivative of the membrane bioreactor (MBR) technology, dynamic membrane bioreactors (DMBRs) are attracting strong interest in the recent decades, in which a dynamic membrane (DM) is obtained through forming a cake layer on large-pore supporting mesh that is made of cheap materials, e.g., nylon. Compared with conventional MBRs, DMBRs have advantages, including inexpensive membrane modules, easier operation, lower energy demand, higher flux, more manageable fouling, and reduced chemical cleaning. Thus, DMBRs have been studied for municipal and industrial wastewater treatment. The advantages of the DMBR technology make it promising for wastewater treatment and reuse in remote communities, such as those in First Nations reserves and others without adequate wastewater treatment facilities. However, the fluctuating permeate quality of DMBRs remains challenging when the DMs are fouled after long-term operation, which impedes large-scale application of the technology. In Canada, there is another unfavorable factor for DMBRs: low temperature. To date, impacts of low temperature (e.g., 1 15°C) on DMBRs have rarely been studied. Hence, DMBRs' performance and resilience in cold regions are still unknown. Since temperature is one of the most influential factors for microbial activities, it is necessary to explore the potential of DMBRs at low temperature. The research program is to holistically and fundamentally study DMBRs at low temperature. Specifically, I am looking to examine DMBRs' psychrophilic performance and resilience, to identify the determinant operating factors, to optimize the treatment performance, and understand the mechanisms that govern DMBRs (e.g., DM formation and fouling). Long-term-wise, I am looking forward to developing multi-barrier approach-based DMBR systems by integrating other processes in a DMBR system. For example, hybridization of activated sludge and biofilm is a reliable and promising approach at low temperature. Moreover, training highly qualified personnel (HQP) is another cornerstone of my research. By training individuals from various backgrounds/identities (e.g., gender, nationality, and skill-set), I will do my best to create a good mix of personnel in my research program to promote equity, diversity, and inclusion. To the best of my knowledge, this is a pioneer attempt. The research will cast deeper insights into the physical, chemical, and biological processes occurring in DMBRs at low temperature. In addition, it would shed light on biodegradation of emerging pollutants in DMBRs under cold conditions. Overall, I am looking forward to developing sustainable wastewater treatment and reuse strategies for underprivileged communities in cold regions. Through developing sustainable technologies and training HQP, my research program will help guard the environment and public health in remote communities scattered across Canada and other countries.

动态膜生物反应器（DMBR）是膜生物反应器（MBR）技术的一种低成本衍生技术，是近年来研究的热点。动态膜生物反应器通过在大孔支撑网上形成滤饼层来获得动态膜（DM），尼龙。与传统的膜生物反应器相比，DMBR具有优势，包括廉价的膜组件、更容易操作、更低的能源需求、更高的通量、更易于管理的污垢和减少的化学清洁。因此，人们研究了DMBRs用于市政和工业废水处理。 DMBR技术的优势使其有望在偏远社区进行废水处理和再利用，例如第一民族保留地和其他没有足够废水处理设施的社区。然而，DMBR的渗透物质量波动仍然具有挑战性，当DMs在长期运行后被污染时，这阻碍了该技术的大规模应用。在加拿大，还有一个对DMBR不利的因素：低温。到目前为止，低温的影响（例如，115 °C）对DMBR的影响很少被研究。因此，DMBR在寒冷地区的性能和弹性仍然是未知的。由于温度是影响微生物活性的最重要因素之一，因此有必要探索低温下DMBR的潜力。 本课题的研究目标是对低温下的DMBR进行整体性和基础性的研究。具体来说，我希望检查DMBR的嗜冷性能和弹性，以确定决定性的操作因素，以优化处理性能，并了解管理DMBR的机制（例如，DM形成和结垢）。从长远来看，我期待着通过在DMBR系统中集成其他过程来开发基于多屏障方法的DMBR系统。例如，活性污泥和生物膜的杂交是在低温下可靠且有前途的方法。此外，培养高素质人才（HQP）是我研究的另一个基石。通过培训来自不同背景/身份的个人（例如，性别，国籍和技能组合），我将尽我所能在我的研究计划中创造良好的人员组合，以促进公平，多样性和包容性。 据我所知，这是一个先驱性的尝试。该研究将更深入地了解低温下DMBR中发生的物理，化学和生物过程。此外，它将揭示在寒冷条件下DMBR中新兴污染物的生物降解。总的来说，我期待着为寒冷地区的贫困社区制定可持续的废水处理和再利用战略。通过开发可持续技术和培训HQP，我的研究计划将有助于保护加拿大和其他国家偏远社区的环境和公共卫生。