Due to its calorific value, wastes could be treated into Refuse Derived Fuel (RDF) through several processes. In order to get higher calorific value, moisture content in the wastes could be removed by utilizing the heat generated from decomposition of organic fraction by microorganism (biodrying process). The study aims to treat solid wastes generated from canteens in Ganesha Campus of Institut Teknologi Bandung into RDF through biodrying process. Through standard sampling procedure, total waste generated from 59 canteens was 228 kg/day and organic fraction became the dominant (74%). There were 3 biodrying piles prepared, namely aeration, windrow, and control pile. Temperature in all piles increased in first and second weeks, then it gradually decreased and the average temperature were between 23-48 ^oC. The heat generated during the process could be remove water content and the optimum time 17-22 days could reach 20-30% of moisture content. The highest calorific value could be obtained from aerated pile (14.98 MJ/kg). By considering several parameters, the best RDF were produced from aerated pile. The parameters which still did not comply with the international standard of RDF were ash content, fixed carbon, and organic carbon. The quality of RDF was affected significantly by the composition of the feed. Though it could not meet with all parameters as an international standard of RDF, the product could be used as co-fuel to substitute coal or other fossil fuels for industrial activities. By knowing that the wastes could be converted into valuable product, the local municipality may shift the conventional paradigm of the waste management which is only collect-haul-dispose into a new paradigm by prioritizing waste recycle.

solid waste; canteen; refuse derived fuel; pile; biodrying process; moisture content; calorific value

Adani, F., Baido, D., Calcaterra, E., Genevini, P. L. 2002. The Influence of Biomass Temperature on Biostabilization-Biodrying of Municipal Solid Waste. Bioresource Technology. 83(1): 173-179.

Chaerul, M. 2020. Performance of Bioplant for Municipal Solid Waste at Jatinangor Campus of Institut Teknologi Bandung. E3S Web of Conferences. 148: 02009 (2020).

Chaerul, M., Wardhani, A. K. 2020. Refuse Derived Fuel (RDF) dari Sampah Perkotaan dengan Porses Biodrying: Review. Jurnal Presipitasi. 17(1): 62-74.

Elnaas, A., Belherazem, A., Müller, W., Nassour, A., Nelles, M. 2015. Biodrying for Mechanical Biological Treatment of mixed municipal solid waste and potential for RDF production. Proceeding 3rd International Conference on Sustainable Solid Waste Management. Tinos Island, Greece. 2-4 July 2015.

European Commision. 2003. Refuse Derived Fuel, Current Practice and Perspectives: Final Report.

Frei, K. M., Cameron, D., Start, P. R. 2004. Novel Drying Process Using Forced Aeration Through A Porous Biomass Matrix. Dry Technology. 22(5):1191-1215.

Handayani, P. A., Nurjanah, E., Rengga, D.P. 2015. Pemanfaatan Limbah Sekam Padi menjadi Silika Gel. Jurnal Bahan Alam Terbarukan. 4(2): 55-59.

Handayani, P. A., Wijayanti, H. 2015. Pembuatan Film Plastik Biodegrable dari Limbah Biji Durian (Durio Zibenthinus Murr). Jurnal Bahan Alam Terbarukan. 4(1): 21-26.

Huilinir, C., Villegas, M. 2014. Biodrying of Pulp and Paper Secondary Sludge Kinetics of Volatile Solids Biodegradation. Bioresource Technology. 157(1): 206-213.

Megawati, Machsunah, E. L. 2016. Ekstraksi Pektin dari Kulit Pisang Kepok (Musa paradisiaca) menggunakan HCl sebagai Edible Film. Jurnal Bahan Alam Terbarukan. 5(1): 14-21.

Nguyen, T. T. X., Tomberlin, J. F., Vanlaerhoven, S. 2015. Ability of Black Soldier Fly (Diptera Stratiomydiae) Larvae to Recycle Food Waste. Environmental Entomology. 44(2): 406-410.

Rada, E. C., Ragazzi, M. 2014. Selective Collection as a Pretreatment for Indirect Solid Recovered Fuel Generation. Waste Management. 34(2): 291-197.

Rusianto, T., Yuniwati, M., Wibowo, H. 2019. Effect Carrageenan to Biodegradable Plastic from Tubers. Jurnal Bahan Alam Terbarukan. 8(2): 148-155.

Sadaka, S., Van Devender, K., Costello, T., Sharara, M. 2011. Partial Composting for Biodrying Organic Materials (FSA1055-PD-4-11N). University of Arkansas: Arkansas.

Shao, L. M., Ma, Z. H., Zhang, H., Zhang, D. Q., He, P. J. 2010. Bio-drying and Size Sorting of Municipal Solid Waste with High Water Content for Improving Energy Recovery. Waste Management. 30(7): 1165-1170.

Sugni, M., Calcaterra, E., Adani, F. 2005. Biostabilization-Biodrying of Municipal Solid Waste by Inverting Air-Flow. Bioresource Technology. 96(12): 1331-1337.

Tom, A. P., Pawels, R., Haridas, A. 2016. Biodrying Process: A Sustainable Technology for Treatment of Municipal Solid Waste with High Moisture Content. Waste Management. 49(1): 64-72.

Velis, C. A., Longhurst, P. J., Drew, G. H., Smith, R., Pollard, S. J. T. 2009. Biodrying for Mechanical-Biological Treatment of Waste: A Review of Process Science and Engineering. Bioresource Technology. 100(11): 2747-2761.

Zhang, D. Q., He, P. J., Jin, T. F., Shao, L. M. 2008. Bio-Drying of Municipal Solid Waste with High Moisture Content by Aeration Procedures Regulation and Inoculation. Bioresource Technology. 99(18): 8796-8802.