Treatment of fermented fish production wastewater by constructed wetland system in Thailand

Many agro-industries in Thailand discharge untreated wastewater with high organic content causing severe environmental problems. The objectives of this study were to provide a wastewater treatment system for a fermented fish production factory and to demonstrate the constructed wetland technology as...

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Main Authors: Suwasa Kantawanichkul, Seni Karnchanawong, Ren Jing Shuh
Format: Journal
Published: 2018
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http://cmuir.cmu.ac.th/jspui/handle/6653943832/48882
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Institution: Chiang Mai University
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spelling th-cmuir.6653943832-488822018-08-16T02:18:19Z Treatment of fermented fish production wastewater by constructed wetland system in Thailand Suwasa Kantawanichkul Seni Karnchanawong Ren Jing Shuh Biochemistry, Genetics and Molecular Biology Chemistry Materials Science Mathematics Physics and Astronomy Many agro-industries in Thailand discharge untreated wastewater with high organic content causing severe environmental problems. The objectives of this study were to provide a wastewater treatment system for a fermented fish production factory and to demonstrate the constructed wetland technology as an on-site solution for the treatment of wastewater which is economical, and not complicated to operate or maintain. The wastewater from fermented fish production contains BOD, COD, TKN, grease and oil at approximately 6,200, 9,770, 540 and 660 mg/L, respectively. Pre-treatment by a grease trap and an anaerobic process is required prior to two constructed wetland beds connected in series. The first bed is a subsurface horizontal flow bed (180 m2) filled with stone (1-2 inch) and planted with Umbrella sedge (Cyperus flabelliformis Rottb ). The second bed is a free water surface bed (140 m2) planted with Canna (Canna hybrida). The designed capacity of the treatment system is 10 m3/d though presently the maximum volume of wastewater received daily is only 5-7 m3. The factory operates around 5 days per week and 4 hours per day on average depending on the amount of fish processed. A grease trap and a UASB reactor reduce grease and oil, BOD and COD efficiently but only 50% for TKN was eventually reduced in the two wetland beds. The overall removal efficiencies of the system were over 97% for COD, BOD, SS and grease and oil and was around 70% for TKN and NH4 +-N. Wastewater from the free water surface bed was reused for gardening. 2018-08-16T02:06:13Z 2018-08-16T02:06:13Z 2009-05-01 Journal 01252526 2-s2.0-67650706272 https://www.scopus.com/inward/record.uri?partnerID=HzOxMe3b&scp=67650706272&origin=inward http://cmuir.cmu.ac.th/jspui/handle/6653943832/48882
institution Chiang Mai University
building Chiang Mai University Library
country Thailand
collection CMU Intellectual Repository
topic Biochemistry, Genetics and Molecular Biology
Chemistry
Materials Science
Mathematics
Physics and Astronomy
spellingShingle Biochemistry, Genetics and Molecular Biology
Chemistry
Materials Science
Mathematics
Physics and Astronomy
Suwasa Kantawanichkul
Seni Karnchanawong
Ren Jing Shuh
Treatment of fermented fish production wastewater by constructed wetland system in Thailand
description Many agro-industries in Thailand discharge untreated wastewater with high organic content causing severe environmental problems. The objectives of this study were to provide a wastewater treatment system for a fermented fish production factory and to demonstrate the constructed wetland technology as an on-site solution for the treatment of wastewater which is economical, and not complicated to operate or maintain. The wastewater from fermented fish production contains BOD, COD, TKN, grease and oil at approximately 6,200, 9,770, 540 and 660 mg/L, respectively. Pre-treatment by a grease trap and an anaerobic process is required prior to two constructed wetland beds connected in series. The first bed is a subsurface horizontal flow bed (180 m2) filled with stone (1-2 inch) and planted with Umbrella sedge (Cyperus flabelliformis Rottb ). The second bed is a free water surface bed (140 m2) planted with Canna (Canna hybrida). The designed capacity of the treatment system is 10 m3/d though presently the maximum volume of wastewater received daily is only 5-7 m3. The factory operates around 5 days per week and 4 hours per day on average depending on the amount of fish processed. A grease trap and a UASB reactor reduce grease and oil, BOD and COD efficiently but only 50% for TKN was eventually reduced in the two wetland beds. The overall removal efficiencies of the system were over 97% for COD, BOD, SS and grease and oil and was around 70% for TKN and NH4 +-N. Wastewater from the free water surface bed was reused for gardening.
format Journal
author Suwasa Kantawanichkul
Seni Karnchanawong
Ren Jing Shuh
author_facet Suwasa Kantawanichkul
Seni Karnchanawong
Ren Jing Shuh
author_sort Suwasa Kantawanichkul
title Treatment of fermented fish production wastewater by constructed wetland system in Thailand
title_short Treatment of fermented fish production wastewater by constructed wetland system in Thailand
title_full Treatment of fermented fish production wastewater by constructed wetland system in Thailand
title_fullStr Treatment of fermented fish production wastewater by constructed wetland system in Thailand
title_full_unstemmed Treatment of fermented fish production wastewater by constructed wetland system in Thailand
title_sort treatment of fermented fish production wastewater by constructed wetland system in thailand
publishDate 2018
url https://www.scopus.com/inward/record.uri?partnerID=HzOxMe3b&scp=67650706272&origin=inward
http://cmuir.cmu.ac.th/jspui/handle/6653943832/48882
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