Microscopy and Molecular Methods to Advance Performance and Design of Hybrid Biofilm Technology

显微镜和分子方法可提高混合生物膜技术的性能和设计

• 批准号: RGPIN-2016-05222
• 负责人: Delatolla, Robert
• 金额: $ 1.75万
• 依托单位: University of Ottawa
• 依托单位国家: 加拿大
• 项目类别: Discovery Grants Program - Individual
• 财政年份: 2016
• 资助国家: 加拿大
• 起止时间: 2016-01-01 至 2017-12-31
• 项目状态: 已结题
• 来源: https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=615572
• 关键词: Microscopy; Molecular; Methods; Advance; Performance

The need to develop new technologies that meet the wastewater treatment challenges of today has led to the design of innovative hybrid wastewater treatment technologies. The hybrid moving bed biofilm reactor (MBBR) and biological aerated filter (BAF) technology has been conceived to combine the advantages of the MBBR with an upflow BAF technology into a single hybrid system. In particular, the hybrid MBBR-BAF has been conceived to separate the heterotrophic population that consumes the readily degradable influent carbon from the autotrophic, ammonia removal population. Further, the hybrid system has also been conceived to mitigate the adverse effects of excessive heterotrophic growth on BAF media. The scientific approach of this research program is to isolate the impact of critical operational and design parameters on not only the performance of the system but also on the characteristics of the biofilm and the microbial communities on the dual media of the MBBR-BAF hybrid technology. The proposed research program will use advanced microscopy and molecular methods to develop a thorough understanding of the biofilm and microbial population distribution in the MBBR-BAF technology and subsequently use this information to optimize the technology to meet the wastewater treatment needs of Canada. The research program is comprised of three phases: phase I will compare the system performance, biofilm characteristics and microbial communities of the hybrid MBBR-BAF and a conventional upflow BAF system across typical Canadian summer, winter and snow melt operational conditions; phase II will compare the system performance, biofilm characteristics and microbial communities of the hybrid MBBR-BAF and a conventional upflow BAF across various carbon, ammonia and solids loadings and velocity rise rates and subsequently optimize the design loading rates and velocity rise rates of the hybrid system; and phase III will investigate the effects of the percentage of MBBR carriers versus BAF media along with the effects of MBBR carrier mixing intensity on the performance, biofilm characteristics and microbial communities of the hybrid system and subsequently optimize the composition of media and MBBR carrier motion of the system. The anticipated impact of the research program is the optimization of a new wastewater treatment technology that is conceptualized to meet the current challenges facing wastewater treatment and the preservation of water quality in Canada and the world.

开发满足当今废水处理挑战的新技术的需求导致了创新混合废水处理技术的设计。混合移动床生物膜反应器（MBBR）和曝气生物滤池（BAF）技术被认为是将MBBR和上流式BAF技术的优点联合收割机结合成一个单一的混合系统。特别是，混合MBBR-BAF已被认为是从自养，氨去除人口的异养人口消耗容易降解的进水碳。此外，混合系统也被认为可以减轻BAF培养基上过度异养生长的不利影响。本研究计划的科学方法是隔离关键操作和设计参数的影响，不仅对系统的性能，而且对生物膜的特性和微生物群落的MBBR-BAF混合技术的双介质。 拟议的研究计划将使用先进的显微镜和分子方法来深入了解MBBR-BAF技术中的生物膜和微生物种群分布，并随后使用这些信息来优化该技术，以满足加拿大的废水处理需求。该研究计划由三个阶段组成：第一阶段将在典型的加拿大夏季、冬季和融雪操作条件下比较混合MBBR-BAF和传统上流BAF系统的系统性能、生物膜特征和微生物群落;第二阶段将比较混合MBBR-BAF和传统上流式BAF在不同碳源条件下的系统性能、生物膜特性和微生物群落，氨和固体负载以及速度上升速率，并随后优化混合系统的设计负载速率和速度上升速率;第三阶段将研究MBBR载体与BAF介质的百分比沿着以及MBBR载体混合强度对性能的影响，生物膜特性和微生物群落的混合系统，并随后优化的媒体和MBBR载体运动的系统的组成。该研究计划的预期影响是优化一种新的废水处理技术，该技术的概念化是为了满足加拿大和世界目前面临的废水处理和水质保护的挑战。