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ISSN : 2233-4165(Print)
ISSN : 2233-5382(Online)
Journal of Industrial Distribution & Business Vol.9 No.12 pp.23-29
DOI : http://dx.doi.org/10.13106/ijidb.2018.vol9.no12.23.

A Study on Cost-effective Treatment of Wastewater and Odor Reduction for Southeast Asian Market Entry

Min-Jae Jung*,Yong-Do Kim**,Lee-Seung Kwon***,Woo-Sic Lee****,Woo-Taeg Kwon*****
* 1st Author. Master’s degree completion, Department of Environmental Health & Safety, Eulji University, Korea. Tel: +82-31-740-7230. E-mail: idrjqnrdl@naver.com
** 2nd Author. Senior Researcher, Department of Environmental Health & Safety, Eulji University, Korea. Tel: +82-31-740-7230. E-mail: youngdo31@naver.com
*** 3rd Author. Professor, Department of Health Care Management, Catholic Kwandong University, Korea. Tel: +82-33-649-7589. E-mail: leokwon1@cku.ac.kr
**** 4th Author. Professor, Department of Chemical & Biological Engineering, Gachon University, Korea. Tel: +82-31-750-5594. E-mail: leews@gachon.ac.kr
***** Corresponding Author. Professor, Department of Environmental Health & Safety, Eulji University, Korea. Tel: +82-31-740-7230. E-mail: awtkw@eulji.ac.kr
October 31, 2018. November 30, 2018. September 18, 2018

Abstract

Purpose - The purpose of this study is to apply a cost effective ultrasonic odor reduction method that generated micro-bubbles using ejector to the Southeast Asian wastewater market.
Research design, data, and methodology - A leather maker located in Ansan-city, Gyunggi-do, South Korea was sampled from the collection tank to select experimental materials. Experimental setup consisted of circulating water tank-air ejector-ultrasonic device, and circulating wastewater. Sample analysis was performed by CODcr, T-N, T-P, and turbidity by the National Environmental Science Institute.
Results - Experimental results show that it is most effective in removing odors when the frequency range of ultrasonic wave is 60∼80 Khz and the output is 200 W. It showed that the concentration of complex odor dropped from a maximum of 14,422 times to a minimum of 120 times. Also, analysis of ammonia and hydrogen sulfide in specific odor substances has shown that they were reduced from 1.5 ppm to 0.4 ppm and from 0.6 ppm to 0.1 ppm, respectively.
Conclusions - It is possible to shorten more than 12 hours in the treatment of micro-organisms. It can be seen that the processing time of odor after ultrasonic treatment in the pre-treatment facility is reduced by 25% when compared to the resultant micro-organisms after the chemical treatment, that is, the time of the bio-treatment of micro-organisms. Based on the results, it was confirmed that the pre-treatment method using the ultrasonic and the air ejector device of the experiment shows the effect of reducing the water pollutants and odor more effectively in a relatively short time than the conventional advanced oxidation method.

JEL Classifications: M3, H8, I11.

초록


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    Reference

    1. Cha, H. S. (2009). Present State and Future Prospect for Microbubble Technology. Bulletin of food technology, 22(3), 544-552.
    2. Gal, W. M., Kwon, K. T., Lee, W. S., Choi, E. M., Kwon, L. S., Seong, S. H., & Kwon, W. T. (2018). A Study on Improvement of Distribution Facility in Wholesale Agricultural Products Market. Journal of Distribution Science, 16(2), 53-65.
    3. Handforth, S. L., & Tilley, J. N. (1934). Catalysts for Oxidation of Ammonia to Oxides of Nitrogen. Industrial & Engineering Chemistry, 26(12), 1287-1292. https://doi.org/10.1021/ie50300a016
    4. Jang, J. K., Yu, J. J., Kang, S. W., Kim, T. Y., Yee P., Sung, J. H., & Kim, Y. H. (2017). Simultaneous Removal of Organic Pollutants, Nitrogen, and Phosphorus from Livestock Wastewater by Microbubble- Oxygen in a Single Reactor. Journal of Korean Society of Environmental Engineers, 39, 599-606. DOI: 10.4491/KSEE.2017.39.11.599
    5. Kang, S. H., & Park, Y. C. (2017). Study on the Swirling Motion Effect of Ejector Performance. Journal of the Korea Academia-Industrial cooperation Society, 18(4), 544-549.
    6. Kim. H. J., Bae. Y. S., Oh. C. H., Kim. T. H., Kim. J. B., Ryu. H. R., & Kim. T. H. (2009). A Study on Management Improvement of Deodorization Equipment of Food Waste Treatment Facility. Korean Journal of Odor Research and Engineering, 8(1), 20-30.
    7. Kang, H., Lee S. H., Lee W. S., Kwon J. H., & Jung, K. J. (2012). Study on phosphorus removal in the secondary effluent by flotation using micro-bubble liquid film system. J. Korea Soc. Environ. Eng, 34(1), 42-48.
    8. Kwon, W. T., Lee, J. C., Kang, H. S., Kwon, L. S., Kim, H. G., & Gal, W. M. (2015). Odorant removing effect of a multi process –The combination of scrubber, UV, adsorption-. Journal of odor and indoor environment, 14(2), 85-92.
    9. Kwon, K. T., Lee, W. S., Kwon, L. S., Seong, S. H., Kim, Y. D., & Kwon, W. T. (2017). Entry into the Southeast Asian Energy Market from the Sales Promotion Viewpoint. Journal of Distribution Science, 15(10), 29-39.
    10. Kwon, W. T., Lee, J. C., Kang, H. S., Kwon, L. S., Kim, H. G., & Gal, W. M. (2015). Odorant removing effect of a multi process –The combination of scrubber, UV, adsorption-. Journal of odor and indoor environment, 14(2), 85-92.
    11. Lee, J. C., Kwon, L. S., Lee, W. Sic., & Kwon, W. T.(2016). A study on odor removal efficiency of wastewater treatment plant by multiple process, Journal of odor and indoor environment, 15(4), 385-391.
    12. Maeda, Y., Hosokawa, S., Baba, Y., Tomiyama, A., & Ito, Y. (2015). Generation mechanism of micro-bubbles in a pressurized dissolution method. Experimental Thermal and Fluid Science. 60. 10.1016/j.expthermflusci.2014.09.010.
    13. Michio, S., Akimaro, K., Hidetoshi, M., & Shinji, S.(2012). Micro-bubble generation rate and bubble dissolution rate into water by a simple multi-fluid mixer with orifice and porous tube. Experimental Thermal and Fluid Science, 41, 23-30. ISSN 0894-1777, https://doi.org/10.1016/j.expthermflusci.2012.03.002.
    14. Ministry of Environment(ME) (2007). ‘06 Analysis of complaints against odor & ’07 Management direction for odor(pp.5-6).
    15. National Environmental Science Institute. (2017). Water pollution process test standard, ES 04362.1c Total - ultraviolet, visible line spectroscopy. Ministry of Environment, 1-7.
    16. National Environmental Science Institute. (2017). Water pollution process test standard, ES 04315.3c COD, Titration method, Potassium dichromate method. Ministry of Environment, 1-7.
    17. National Environmental Science Institute. (2017). Water pollution process test standard, ES 04363.1b Total nitrogen-ultraviolet, visible-line spectroscopy-oxidation. Ministry of Environment, 1-6.
    18. Sadatomi, M., Kawahara, A., Matsuura, H., Shikatani, S. (2012). Micro-bubble generation rate and bubble dissolution rate into water by a simple multi-fluid mixer with orifice and porous tube, Experimental Thermal and Fluid Science, 41, 23-30.
    19. Tsuge, S. (2010). The latest technology on microbubbles and nanobubbles Ⅱ. CMC publishing, 140-167.
    20. Takehiko, N., & Ravi, N. (2016). Asian Water Development Outlook 2016 Strengthening Water Security In Asia and The Pacific. Asian Development Bank. ISBN 978-92-9257-543-4
    21. Terasaka, K., Hirabayashi, A., Nishino, T., Fujioka, S., & Kobayashi, D. (2011). Development of microbubble aerator for waste water treatment using aerobic activated sludge, Chemical Engineering Science, 66, 3172-3179.
    22. Tsuge, S. (2010). The latest technology on microbubbles and nanobubbles. CMC publishing, 140-167.
    23. Zhou, Y., Selvam, A., & Wong, J. (2014). Evaluation of humic substances during co-composting of food waste, sawdust and Chinese medicinal herbal residues. Bioresource Technology, 168, 229-234.