KnE Social Sciences
ISSN: 2518-668X
The latest conference proceedings on humanities, arts and social sciences.
Design and Construction of Microwave-Assisted Pyrolysis of Waste Coconut Shell for the Isolation of Pyroligneous Acid
Published date:Jul 03 2019
Journal Title: KnE Social Sciences
Issue title: UNNES International Conference on Research Innovation and Commercialization 2018
Pages:544–553
Authors:
Abstract:
As a country with a large amount of natural resources, Indonesia should be able to convert this material into more value added product. However, most of the natural resources were sold as a raw material. Process system engineering research center is one of the solution to overcome this problem by developing an integrated and systematic technology. Through this research center, output of the research can be scaled up for large scale production and also can be commercialized to increase the community welfare. One of natural resources which has not been optimally utilized is waste coconut shell (WCS). Indonesia is the largest coconut producer in the world with areal production of 3.88 ha and 3.2 million ton of coconut products. Several problems arefacedbycoconutagroindustry,i.e.thelackofcoconutbasedproductdiversification and also the large number of WCS. WCS is one of organic waste, however it is quite hard to be decomposed by the microorganism due to its hard texture. This problem may gave high potential in the environmental pollution. In this research, WCS is going to be used as a raw material for pyroligneous acid through pyrolysis process. Pyrolysis is a method that is usually used to convert a biomass waste sources into a valuable product through thermal decomposition process without the presence of oxygen. This process will produce solid (char), liquid (bio-oil, tar and pyroligneous acid) and gas. Pyroligneous acid is commonly obtained as a side product from the production of active carbon and to date it has not been utilized economically. In the other hand, pyroligneous acid can be used as an anti-oxidant, antimicrobial, antifungal, anti-biofilm and also as an anti inflammatory. This properties are available due to the presence of organic matter and phenolic compound in the pyroligneous acid. This characteristics showedthatpyroligneousacidishighlypotentialasrawmaterialindrugsandpharmacy industries. Pyrolysis process requires high temperature which has range between 500 – 600 ∘C. In this paper, it will be discussed a pyrolysis equipment design and productionofpyroligneousacidfromWCSbyusingmicrowave-assistedpyrolysis(MAP).
Keywords: Coconut Shel, Pyroligneous Acid, Pyrolysis, Microwave, Pharmacy
References:
[1] Ariffin, S. J., Yahayu, M., El-Enshasy, H., Malek, R. A., Aziz, A. A., Hashim, N. M. dan Zakaria, Z. A. 2017, Optimization of pyroligneous acid production from palm kernel shell and its potential antibacterial and antibiofilm activities, Indian Journal of Experimental Biology, 55 (7), 427-435
[2] Astuti, W., Sulistyaningsih, T., dan Maksiola, M., 2016, Chemically modified kapok sawdust as adsorbent of methyl violet dye from aqueous solution, Jurnal Teknologi (Science and Engineering) 78 (9), 35-42
[3] Astuti, W., Hermawan, R.A, Mukti, H., and Sugiyono, N.R., 2017, Preparation of activated carbon from mangrove propagule waste by H3PO4 activation for Pb2+ adsorption, AIP Conference Proceedings 1788 (1), 030082
[4] Bilehal, D and Kim, L.L.Y.H., 2012, Gas Chromatography–Mass Spectrometry Analysis and Chemical Composition of the Bamboo-Carbonized Liquid, Food Analytical Methods 5(5):109–112
[5] Fardhyanti, D.S. and Damayanti, A., 2017, Analysis of Bio-Oil Produced by Pyrolysis of Coconut Shell, Journal World Academy of Science, Engineering and Technology, International Journal of Chemical, Molecular, Nuclear, Materials and Metallurgical Engineering, 11(9), 636-639
[6] Ibrahim, D., Kassim, J., Lim, S.H., and Rusli, W., 2014, Evaluation of antibacterial effects of Rhizophora apiculata pyroligneous acid on pathogenic bacteria, Malaysian Journal of Microbiology, 10(3), 197-204
[7] Guillén, M.D. dan Manzanos, M.J., 2002, Study of the volatile composition of an aqueous oak smoke preparation. Food Chem., 79, 283–292.
[8] Guerrero, M., Ruiz, M.P., Alzueta, M.U., Bilbao, R., and Millera, 2005, A. Pyrolysis of eucalyptus at different heating rates: Studies of char characterization and oxidative reactivity. J. Anal. Appl. Pyrolysis, 74, 307–314.
[9] Hendaryati, D.D., dan Arianto, Y., 2016, 2015-2017 Kelapa, Direktorat Jendral Perkebunan Indonesia, Jakarta.
[10] Ma, C., Li, W., and Zu, Y., Yang, L., and Li, J., 2014, Antioxidant Properties of Pyroligneous Acid Obtained by Thermochemical Conversion of Schisandra chinensis Baill, Molecules 2014, 19, 20821-20838
[11] Handayani, P.A., Megawati, Sediawan, W.B., 2013, Extraction of P. cubeba Essential Oil by Microwave Assisted Hydrodistillation: Modeling and Process Optimization, Journal American Journal of Oil and Chemical Technologies, 1(10)
[12] Pimenta, A.S., Fasciotti, M., Monteiro, T.V.C., and Lima, K.M.G., 2018, Chemical Composition of Pyroligneous Acid Obtained from Eucalyptus GG100 Clone, Molecules 2018, 23, 426
[13] Pugersari, D., Syarief, A. dan Larasati, D., 2013, Eksperimen Pengembangan Produk Fungsional Bernilai Komersial Berbahan Baku Tempurung Kelapa Berusia Muda dengan Teknik Pelunakan, ITB J. Vis. Art & Des, 5(1), 74-91
[14] Troup, G.M. and Georgakis, C., 2013, Process systems engineering tools in the pharmaceutical industry, Computers and Chemical Engineering 51, 157– 171
statistics
703 Abstract Views
517 PDF Downloads
