Fed Intermittent Composting of Food Waste from Minor Touring City, Using Reactors with Different Passive Ventilation
Abstract
The purpose of this study is to evaluate the influence of air on the decomposition of food waste from minor touring city of Thailand using composting bioreactors with different ventilation. The reactors were made from 200L PE plastic bioreactors. There were 5 different bioreactors, each with a different vent volume. (These were 0%, 2.3%, 3%, 4.3% and 5.7% of bioreactor volume or 0, 1, 2, 4 and 6 PVC pipes of diameter 1¼", respectively. Each reactor also had a drain. The material to be composted was food scraps ground to a size less than 1.5 cm and mixed with rice husk, ash and saw dust at a ratio of 6: 1: 1 to achieve a C / N ratio of 35: 1. The Intermittently-Fed Composting (FIC) method was used, adding 4.5 kilograms of materials per day until 85 kg was added in total. The experiment was also subdivided into 2 types: bioreactors with added microbes (added-PD2); and those without added microbes (non-PD2). The experiment had a 60-day biodegradation period. Measurements of temperature, moisture content, and pH were taken and compost samples were analyzed for their germination index (GI) and quality, compared with Thailand compost standards. The results showed that the optimum air volume for composting was 3% of bioreactor volume, or 2 pipes. The composting time was 19 days with the highest temperature of 57-58°C and the temperature was held constant for 33 days. The organic waste decomposition and curing took a total of 57 days, with a GI value between 79-81% and the quality of the resulting fertilizer complied with standards. The main minerals in the compost were N, P and K, which were 1.25% -1.32%, 0.69% -0.76% and 0.93% -1.88%, respectively. It is concluded that different ventilation ratios affect the results for the decomposition of organic matter, with optimal ventilation being 3.0% of bioreactor volume or 2 pipes. There was a statistically significant difference between the results for compost with and without the addition of PD2.
References
[2] Barrington, S., Choinière, D., Trigui, M. and Knight, W. 2003. Compost convective airflow under passive aeration. Bioresour.Technol., 86: 259–266.
[3] Biondo, A.E. and Bonaventura, L. 2016. Agricultural Resources Allocation and Environmental Sustainability. Journal of Environmental Management and Tourism, 5(2): 105-113.
[4] Fernandes, L., Zhan, W., Patni, N.K. and Jui, P.Y. 1994. Temperature distribution and variation in passively aerated static compost piles. Transactions of the ASAE, 48: 257–263.
[5] Haug, R. T. 1993. The Practical Handbook of Compost Engineering. Lewis Publishers. U.S.A.
[6] Karnchanawong, S. and Suriyanon, N. 2011. Household organic waste composting using bins with different types of passive aeration. Resources, Conservation and Recycling, 55(5): 548-553.
[7] Kulliya Sarichevin and Thanani Rungsisuriyachai. 2016. Composting from organic waste using aeration tank, Journal of Engineering RajamangalaThanyaburi, 1: 25-34.
[8] Mathur, S., Patni, N.K. and Levesque, M.P. 1990. Static pile passive aeration composting of manure slurries using peat as a bulking agent. Biological Wastes, 34 (4): 323–334.
[9] McGarry, M.G. and Strainforth, J. 1978. In: Compost fertilizer and biogas production for human and farm wastes in Peoples Republic of China. International Development Research Centre, Ottawa, Canada, pp. 7–13.
[10] National Bureau of Agricultural Commodity and Food Standard, Thai Agriculture Standard: TAS 9503-2005, Compost, Ministry of Agriculture and Cooperatives. ICS 65.080, ISBN 947-403-339.
[11] Ogunwande, G.A. and Osunade, J.A. 2011. Passive aeration composting of chicken litter: effects of aeration pipe orientation and perforation size on losses of compost elements. J Environ Manage, 92(1):85-91.
[12] Patni, N.K., Kannagara, T., Nielsen, G. and Dinel, H. 2001. Composting caged-layer manure in passively aerated and turned windrows. ASAE paper no. 012271. American Society of Agricultural Engineers, St. Joseph, Michigan, USA.
[13] Pollution Control Department. 2019. Pollution Situation Report of Thailand.S.Mongkol Printing, Ltd., Bangkok, Thailand.
[14] Premsuda Jiewnok. 2007. Relationship between types of nitrogen sources and the complete decomposition time of compost. Master's thesis Department of Environmental Science (Multidisciplinary), Graduate School Chulalongkorn University, Bangkok, Thailand.
[15] Sartaj, M., Fernandes, L. and Patni, N.K. 1997. Performance of forced, passive and natural aeration methods for composting manure slurries. Transactions of the ASAE, 40 (2), 457–463.
[16] Shimaoka, T., Matsufuji, Y. and Hanashima, M. 2000. Mechanism of Self-Stabilization of Semi-Aerobic Landfill. Proceedings of the 5th Annual Landfill Symposium, Solid Waste Association of North America, 171-186.
[17] Sutthasil, N., et al. 2018. The effectiveness of passive gas ventilation on methane emission reduction in a semi-aerobic test cell operated in the tropics. Waste Manag. (online)
[18] Thares Srisatit. Comprehensive community solid waste management. Supporting documents for seminars, Hotel Windsor Suites and Convention Bangkok, seminars on December 2, 2016. Date accessed: 23 April 2019. Available at: http://www.pcd.go.th/Info_serv/File/PPT20161130/20161130_19.pdf
[19] Yu, H. and Huang, G.H. 2009.Effect of sodium as a PH control amendment on the Compostingof food waste. Bioresour.Technol., 100: 2005–2011.
[20] Zhan, W., Fernandes, L. and Patni, N., 1992. Composting of poultry manure slurries. CSAE paper no. 92–515. Canadian Society of Agricultural Engineering, Saskatoon, Canada.
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