PERBAIKAN KUALITAS AIR BAKU OLEH ISOLAT BAKTERI NITRIFKASI INDIGENOUS MENGGUNAKAN MOVING BED BIOFILTER REACTOR (MBBR)

Jurnal Teknologi Industri Pertanian Pub Date : 2019-10-21 DOI:10.24961/j.tek.ind.pert.2019.29.2.183

Ramiza Dewaranie Lauda, Suprihatin, dan Titi Candra Sunarti

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Abstract

Bio-filtration technology is considered as one of prevention solutions for declining raw water quality. The research purpose was to identify biofilm growth formation as viability cell in acclimatization period that can be used for ammonia elimination by using various indigenous chemo-heterotroph bacteria isolated from bio-filter media specimen and moving bed bio-filter reactor performance. Reactor was configured within aerobic system comparing two biofilm–attached support–medium filters (i.e. drinking-water-bottle-PET-chips and PVC). Bacteria potency on ammonia removal in kinetics modeling was advance investigated. Kinetics determination was based on empirical approach in first order by using formula of C out = C in exp(-k.EBRT), where C out is ammonia concentration in outlet, C in is ammonia concentration in inlet, k is first-order reaction rate constant and Empty Bed Retention Time (EBRT) can be formulated about setting comparison the discharge ammonia load (Q) and volume reactor (V). Total thirteen potential biofilm bacterias were successfully isolated in 24–hours–incubation at 37 o C and by using Bergey’s method successfully identified prime biofilm isolates of Bacillus sp and Pseudomonas sp, then re-selected to determine one with the best ammonia removal ability. The ammonia removal kinetics constant of each reactor was obtained as followed: (1) k PET =0.421h -1 (ɳ = 62.47%-NH 3 ) and (2) k PVC = 0.412 h -1 (ɳ = 58.80%-NH 3 ). Keywords:ammonia removal, biofilm viability, bio-filtration, raw water, polyethylene terephthalate chips

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使用生物滤清器(MBBR)移动生物滤清器对原始水质量的改进

生物过滤技术被认为是原水水质下降的防治方案之一。研究目的是利用从生物滤料中分离的各种原生化学异养菌和移动床生物滤料反应器的性能，确定生物膜生长形成为适应期的生存细胞，可用于氨氮的消除。在好氧系统中配置反应器，比较两种附着生物膜的支持介质过滤器(即饮用水瓶- pet芯片和PVC)。在动力学模型中进一步研究了细菌对氨的去除效果。动力学测定采用一阶经验法，采用公式C out = C in exp(-k.EBRT)，其中C out为出口氨浓度，C in为进口氨浓度，k为一级反应速率常数，空床停留时间(EBRT)可用于设定比较排放氨负荷(Q)和体积反应器(V)。在37℃条件下培养24小时，共成功分离出13种潜在的生物膜细菌，并通过Bergey方法成功鉴定出芽孢杆菌sp和假单胞菌sp的主要生物膜分离株，然后重新筛选出具有最佳氨去除能力的菌株。各反应器脱氨动力学常数分别为:(1)k PET =0.421h -1 (% = 62.47%- nh3)和(2)k PVC = 0.412 h -1 (% = 58.80%- nh3)。关键词:氨去除，生物膜活力，生物过滤，原水，聚对苯二甲酸乙二醇酯芯片

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Jurnal Teknologi Industri Pertanian

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