Optimization of Conditions for Wastewater Treatment and Kinetics Establishment by Yeast

Chen Song; Jiang Ping Li; Yi Xin Sun; Hai Long; Wei Wu

doi:10.4028/www.scientific.net/AMR.726-731.2441

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HomeAdvanced Materials ResearchAdvanced Materials Research Vols. 726-731Optimization of Conditions for Wastewater...

Optimization of Conditions for Wastewater Treatment and Kinetics Establishment by Yeast

Abstract:

Yeast SP1 was selected from the three strains to remove chemical oxygen demand (COD) in wastewater from refining part of N, 2, 3-trimethyl-2-isopropyl butanamide (WS-23). The effects of some factors on the degradation for wastewater from refining part of WS-23 were investigated and the optimum conditions for biological water treatment by yeast SP1 were obtained through orthogonal experiments. The results indicate that this wastewater can be treated directly by yeast without any pre-treatment and the best conditions are as follows: inoculum is 10% (v/v), reaction temperature at 30 °C for 48 h. Under these conditions, the total COD removal efficiency can reach 87.11%. In addition, according to Monod model, the kinetics parameters were obtained from the experiments by determining influent COD (S₀), effluent COD (S_e), biomass (X) and the kinetics of COD removal was established, furthermore, the difference of experimental and calculated values was within 1 hour by testing.

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Periodical:

Advanced Materials Research (Volumes 726-731)

Pages:

2441-2448

DOI:

https://doi.org/10.4028/www.scientific.net/AMR.726-731.2441

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Online since:

August 2013

Authors:

Chen Song, Jiang Ping Li, Yi Xin Sun, Hai Long, Wei Wu

Keywords:

Chemical Oxygen Demand (COD), Kinetic, Wastewater from Refining Part of WS-23, Yeast SP1

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References

[1] Baoguo Sun, in: Edible perfumer surgery, edited by Chemical Industry Publications, Beijing, 2010. (In Chinese)

Google Scholar

[2] Jianyu Liu, Xiaojun Wang, in: Environmental Science & Technology, Vol. 23 (2009), pp.141-143. (In Chinese)

Google Scholar

[3] Fuxiang Li, Weijin Gong, Yunji Yin, in: Technology of Water Treatment, Vol. 36 (2010), pp.129-131. (In Chinese)

Google Scholar

[4] Huizhan Zhang, Ruisheng Niu, Hefang Hong, in: Technology of Water Treatment, Vol.37(2011), pp.129-131. (In Chinese)

Google Scholar

[5] Qingxiang Yang, Zhenjie Jia, Feng Pan, et al, in: Techniques and Equipment for Environmental Pollution Control, Vol. 6 (2005), pp.1-5. (in Chinese)

Google Scholar

[6] Fengmin Song, in: Environmental Science & Technology, Vol. 35 (2012), pp.71-75, 115. (in Chinese)

Google Scholar

[7] Kazuhito Moriya, Haruyuki Iefuji, Hitoshi Shimoi et al, in: Journal of Fermentation and Bioengineering, Vol. 69 (1990), pp.138-140.

Google Scholar

[8] K. Chigusa, T. Hasegawa, N. Yamamoto et al, in: Water Science and Technology, Vol. 34 (1996), pp.51-58.

Google Scholar

[9] Qingxiang Yang, Min Yang, Shujun Zhang, et al, in: Process Biochemistry, Vol. 40 (2005), pp.2483-2488.

Google Scholar

[10] Takashi Watanabe, Kazuo Masaki, Kazuhiro Iwashita, et al, in: Bioresource Technology, Vol. 100 (2009), pp.1781-1785.

Google Scholar

[11] Yongqiang Zhu, Feiyan Xue, Xu Xing, et al, in: Chinese Journal of Bioprocess Engineering, Vol. 8 (2010), pp.17-20. (In Chinese)

Google Scholar

[12] Shaokui Zheng, Min Yang, Fang Liu, in: China Environmental Science, Vol. 4 (2001), pp.347-350. (In Chinese)

Google Scholar

[13] Lin Xiao, Liuyan Yang, Peng Chen, et al, in: Environmental Science & Technology, Vol. 6 (2005), pp.37-39. (In Chinese)

Google Scholar

[14] Hongmei Li, in: Technology of Water Treatment, Vol. 36 (2010), pp.50-53. (In Chinese)

Google Scholar

[15] Ping Zhang, in: Biodegradation characteristics of yeast and kinetic analysis of substrate Biodegradation by sequencing bath reaction in cassava alcohol wastewater treatment, Master degree. Guangxi University, 2008. (In Chinese)

Google Scholar

[16] Yuanxiang Fang, Govind Rakesh, in: Chinese Journal of Chemical Engineering, Vol. 16 (2008), pp.277-286.

Google Scholar

[17] Holger Dette, Viatcheslav B. Melas, Andrey Pepelyshev, et al, in: Journal of Theoretical Biology, Vol. 234 (2005), pp.537-550.

Google Scholar