PENGARUH PENAMBAHAN KANTONG PLASTIK TERHADAP KARAKTERISTIK SEKAM PADI
Abstract
This research is done by the addition of plastic bag (PB) to the characteristics of rice husk (RH) as fuel inpower plant. Testing of rice husk characteristics was done by adding plastic bag material in rice husk material about10% and 30%. Further proximate and ultimate analysis and Thermografimetrik test at temperature from 30 - 800â°C,10â°C / min heating rate range, nitrogen flow rate about 50 ml / min. The dehydration process takes place at atemperature of 40 - 100â°C, while for thermal degradation processes occurs at a temperature of 200 - 340â°C, 400-500â°C,and 580 - 670â°C. The activation energy and heating values of R9P1 and R7P3 increased significantly with the additionof PB about 10% and 30%. It was concluded that the addition of PB and RH in the co-pyrolysis process showed betterimprovement in the characteristics of rice husk fuel compared to the original state.References
Directorate of Energy and Minerals Resources, Alignment of National Energy Policy (KEN) with the General
Plan National Energy (RUEN), Policy paper. 2012.
Directorate of Energy and Minerals Resources (2012). "Alignment of National Energy Policy (KEN) with the
General Plan National Energy (RUEN)." Policy paper.
Anshar, M., Ani, F. N., and Kader, A. S., Potential surplus of rice straw as a source of energy for rural
communities in Indonesia, Applied Mechanics and Materials, Trans Tech Publications, Switzerland. 695 (2015)
-810.
Anshar, M., Ani, F. N., and Kader, A. S., The potential energy of plastic solid waste as alternative fuel for power
plants in indonesia, Applied Mechanics and Materials, Trans Tech Publications, Switzerland. 699 (2015) 595-600.
C-Tech Innovation Ltd., Thermal methods of municipal waste treatment, Programme on Sustainable Resource
Use. 2003.
Rozainee, M., Ngo, S. P., Salema, A. A., and Tan, K. G., Fluidized bed combustion of rice husk to produce
amorphous siliceous ash, Energy for Sustainable Development. 12 (2008) 33-42.
Said, M. M., John, G. R., and Mhilu, C. F., Thermal characteristics and kinetics of rice husk for pyrolysis process,
International Journal of Renewable Energy Research. 4 (2014) 1-4.
Shen, D. K., Gua, S., Luo, K. H., Bridgwater, A. V., and Fang, M. X., Kinetic study on thermal decomposition of
woods in oxidative environment, Fuel. 88 (2009) 1024–1030.
Chattopadhyay, J., Kim, C., Kim, R., and Pak, D., Thermogravimetric characteristics and kinetic study of biomass
co-pyrolysis with plastics, Korean J. Chem. Eng. 25 (2008) 1047-1053.
Gai, C., Dong, Y., and Zhang, T., The kinetic analysis of the pyrolysis of agricultural residue under non-isothermal
conditions, Bioresource Technology. 127 (2013 ) 298–305.
Yuan, S., Dai, Z.-h., Zhou, Z.-j., Chen, X.-l., Yu, G.-s., and Wang, F. C., Rapid co-pyrolysis of rice straw and a
bituminous coal in a high-frequency furnace and gasification of the residual char, Bioresource Technology. 109
(2012 ) 188–197.
Xie, Z., and Ma, X., The thermal behaviour of the co-combustion between paper sludge and rice straw,
Bioresource Technology. 146 (2013 ) 611–618.
Chen, D., Zheng, Y., and Zhu, X., In-depth investigation on the pyrolysis kinetics of raw biomass. Part I: Kinetic
analysis for the drying and devolatilization stages, Bioresource Technology. 131(2013) 40–46.
Huang, Y. F., Kuan, W. H., Lo, S. L., and Lin, C. F., Total recovery of resources and energy from rice straw using
microwave-induced pyrolysis, Bioresource Technology. 99 (2008) 8252–8258.
Calvo, L. F., Otero, M., Jenkins, B. M., Mora´n, A., and Garcı´a, A. I., Heating process characteristics and kinetics
of rice straw in different atmospheres, Fuel Processing Technology. 85 (2004) 279– 291.
Sait, H. H., Hussain, A., Salema, A. A., and Ani, F. N., Pyrolysis and combustion kinetics of date palm biomass
using thermogravimetric analysis, Bioresource Technology. 118 (2012) 382–389.
Maiti, S., Dey, S., Purakayastha, S., and Ghosh, B., Physical and thermochemical characterization of rice husk char
as a potential biomass energy source, Bioresource Technology. 97 (2006) 2065–2070.
Kumar, S., and Singh, R. K., Pyrolysis kinetics of waste high-density polyethylene using thermogravimetric
analysis, International Journal of ChemTech Research. 6 (2014) 131-137.
Adrados, A., de Marco, I., Caballero, B. M., López, A., Laresgoiti, M. F., and Torres, A., Pyrolysis of plastic
packaging waste: A comparison of plastic residuals from material recovery facilities with simulated plastic waste,
Waste Management. 32 (2012) 826-832.
Gómez-Siurana, A., Marcilla, A., Beltran, M., Martinez, Berenguer, D., GarcÃa-MartÃneza, R., and Hernández-
Selva, T., Study of the oxidative pyrolysis of tobacco–sorbitol–saccharose mixtures in the presence of MCM-41,
Thermochimica Acta. 530 (2012) 87– 94.
Yokoyama, S., The Asian Biomass Handbook , A guide for biomass production and utilization the Japan Institute
of Energy. (2008).
Zhou, H., Long, Y., Meng, A., Li, Q., and Zhang, Y., The pyrolysis simulation of five biomass species by hemicellulose,
cellulose and lignin based on thermogravimetric curves, Thermochimica Acta. 566 (2013) 36-43.
Chin, B. L. F., Yusup, S., Shoaibi, A. A., Kannan, P., Srinivasakannan, C., and Sulaiman, S. A., Kinetic studies of
co-pyrolysis of rubber seed shell with high density polyethylene, Energy Conversion and Management. 87 (2014)
–753.
