Lemaire Romain, Yuan Zhiguo, Bernet Nicolas, Marcos Marcelino, Yilmaz Gulsum, Keller Jürg
Advanced Water Management Centre, The University of Queensland, St. Lucia, Brisbane, QLD, 4072, Australia.
Biodegradation. 2009 Jun;20(3):339-50. doi: 10.1007/s10532-008-9225-z. Epub 2008 Oct 21.
A sequencing batch reactor (SBR) system is demonstrated to biologically remove nitrogen, phosphorus and chemical oxygen demand (COD) to very low levels from abattoir wastewater. Each 6 h cycle contained three anoxic/anaerobic and aerobic sub-cycles with wastewater fed at the beginning of each anoxic/anaerobic period. The step-feed strategy was applied to avoid high-level build-up of nitrate or nitrite during nitrification, and therefore to facilitate the creation of anaerobic conditions required for biological phosphorus removal. A high degree removal of total phosphorus (>98%), total nitrogen (>97%) and total COD (>95%) was consistently and reliably achieved after a 3-month start-up period. The concentrations of total phosphate and inorganic nitrogen in the effluent were consistently lower than 0.2 mg P l(-1) and 8 mg N l(-1), respectively. Fluorescence in situ hybridization revealed that the sludge was enriched in Accumulibacter spp. (20-40%), a known polyphosphate accumulating organism, whereas the known glycogen accumulating organisms were almost absent. The SBR received two streams of abattoir wastewater, namely the effluent from a full-scale anaerobic pond (75%) and the effluent from a lab-scale high-rate pre-fermentor (25%), both receiving raw abattoir wastewater as feed. The pond effluent contained approximately 250 mg N l(-1) total nitrogen and 40 mg P l(-1) of total phosphorus, but relatively low levels of soluble COD (around 500 mg l(-1)). The high-rate lab-scale pre-fermentor, operated at 37 degrees C and with a sludge retention time of 1 day, proved to be a cheap and effective method for providing supplementary volatile fatty acids allowing for high-degree of biological nutrient removal from abattoir wastewater.
序批式反应器(SBR)系统被证明可从屠宰场废水中生物去除氮、磷和化学需氧量(COD)至极低水平。每个6小时的周期包含三个缺氧/厌氧和好氧子周期,废水在每个缺氧/厌氧阶段开始时进料。采用分步进水策略以避免硝化过程中硝酸盐或亚硝酸盐的高水平积累,从而促进生物除磷所需的厌氧条件的形成。经过3个月的启动期后, consistently and reliably实现了总磷(>98%)、总氮(>97%)和总COD(>95%)的高度去除。出水的总磷酸盐和无机氮浓度分别始终低于0.2 mg P l(-1)和8 mg N l(-1)。荧光原位杂交显示,污泥中富集了聚磷菌属(20-40%),这是一种已知的聚磷积累生物,而几乎不存在已知的糖原积累生物。SBR接收两股屠宰场废水,即来自全尺寸厌氧池的出水(75%)和来自实验室规模高速率预发酵罐的出水(25%),两者均接收未经处理的屠宰场废水作为进料。池塘出水含有约250 mg N l(-1)的总氮和40 mg P l(-1)的总磷,但可溶性COD水平相对较低(约500 mg l(-1))。在37摄氏度下运行且污泥停留时间为1天的实验室规模高速率预发酵罐被证明是一种廉价且有效的方法,可提供补充挥发性脂肪酸,从而实现从屠宰场废水中高度去除生物营养物。