3.2.3. Performance of the A/O/DMBRA

3.2.3. Performance of the A/O/DMBR
As shown in Figs. 7–9, though the fluctuating of the concentrations of COD, NH4+–N and TN in the influent were as high as 150–1300mg/L, 150.4–230mg/L and 198.5–285.5mg/L, respectively, as the temperature was 20–30 ◦C, the system accomplished a COD removal efficiency of above 91.5%. However, the removal efficiency of TN and NH4+–N were influenced by the ratio of COD/TN in the influent, both of which could be improved by increasing the ratio of COD/TN, and could reach 60.2% and 90.3%, respectively, when the COD/TN was above 4.4. Interestingly, the increasing of COD/TN ratio not only improved the TN removal, but also accelerated the nitrification rate, which was impenetrable and on contrary to the theory of the nitrification. It is known that high ratio of COD/TN means the richness of organic substrates in the system, where heterotrophic bacteria can grow quickly and occupies most of oxygen and nutrition. Thus, as a kind of autotrophic bacteria, the activity of nitrifiers is restrained, resulting in a low nitrification rate. However, in the test, the improvement of COD/TN ratio brought the increase of the removal rates for both of NH4+–N and TN. The reason might be as follows. In the system, the ratio of COD/TN was always very low, and the concentration of organic nutrition was not the main parameter influencing the growth of nitrifiers, but was the key index controlling the denitrification. The enhanced denitrification with higher ratio of COD/TN could remove the adverse effects of NOX−–N with high concentration on the growth of nitrifiers. However, if the environment was short of nutrition with high concentration of NOX−–N, the concentration of NOX−–N would become higher and higher by accumulating and inhibiting both of denitrification and nitrification in the aerobic and anaerobic zone greatly at last.