Hasebe Yoshiaki, Meguro Hiroaki, Kanai Yuuki, Eguchi Masahiro, Osaka Toshifumi, Tsuneda Satoshi
Organo Corp. R&D Center, Nishioonuma 4-4-1, Minami-ku, Sagamihara 252-0332, Japan E-mail:
Department of Life Science and Medical Bioscience, Waseda Univ., Wakamatsu-cho 2-2, Shinjuku-ku, Tokyo 162-8480, Japan.
Water Sci Technol. 2017 Dec;76(11-12):3171-3180. doi: 10.2166/wst.2017.431.
Nitrifying granules have a high sedimentation property and an ability to maintain a large amount of nitrifying bacteria in a reaction tank. Our group has examined the formation process of nitrifying granules and achieved high-rate nitrification for an inorganic synthetic wastewater using these granules. In this research, a pilot-scale test plant with an 850-liter reaction tank was assembled in a semiconductor manufacturing factory in order to conduct a continuous water conduction test using real electronics industry wastewater. The aim was to observe the formation of nitrifying granules and determine the maximum ammonia removal rate. The average granule diameter formed during the experiment was 780 μm and the maximum ammonia removal rate was observed to be 1.5 kgN·m·day at 20 °C, which is 2.5-5 times faster than traditional activated sludge methods. A fluorescence in situ hybridization analysis showed that β-proteobacterial ammonia oxidizing bacteria and the Nitrospira-like nitrite-oxidizing bacteria dominate the bacteria population in the granules, and their strong aggregation capacity might confer some benefits to the formation of these nitrifying granules.
硝化颗粒具有很高的沉降性能,并且能够在反应池中维持大量的硝化细菌。我们团队已经研究了硝化颗粒的形成过程,并利用这些颗粒实现了对无机合成废水的高速硝化。在本研究中,为了使用实际电子工业废水进行连续通水试验,在一家半导体制造工厂组装了一个带有850升反应池的中试规模试验装置。目的是观察硝化颗粒的形成,并确定最大氨去除率。实验过程中形成的颗粒平均直径为780μm,在20℃时观察到的最大氨去除率为1.5 kgN·m·天,这比传统活性污泥法快2.5至5倍。荧光原位杂交分析表明,β-变形菌纲氨氧化细菌和类硝化螺菌属亚硝酸盐氧化细菌在颗粒中的细菌群落中占主导地位,它们强大的聚集能力可能对这些硝化颗粒的形成有一定益处。
