DEVELOPMENT OF NIPA (Nypa fruticans) SAP CLOSED COLLECTION VESSEL
Abstract
The ultimate goal of the present study was to develop a secure, safe, and hygienic nipa sap collection system for bioethanol production, with the aim of preserving its physico-chemical properties such as physical appearance, pH and sugar brix by reducing the rate of fermentation while attached to the peduncle. The developed collection system was evaluated in terms of the physical and chemical properties of nipa sap collected and ethanol yield in comparison to the traditional and existing collection system used by the nipa community which utilizes bamboo shingle as their collector. Physical appearance of the sap collected using the designed collection system had no foreign materials after harvesting while the traditional collection system had shown traces of insect infestation. The sap that was produced for both of the designed and traditional collection system was milky-white and yellowish-white in color respectively. There was a significant difference in terms of pH concentration of the sap collected using the designed collection system compared to the sap collected using the traditional system overtime. Sugar brix of nipa sap collected using designed collection system is significantly higher than the sap collected using traditional system. A total ethanol yield of 32.25% and 75.54% was obtained for the designed and traditional collection system respectively. Cost Analysis revealed that the designed collection system was found to be cheaper (PhP 11.93) than the traditional collection system (PhP. 20.00). The developed closed collection system can preserved the chemical properties of the nipa sap and could prevent acceleration of fermentation and the deterioration of its potential to yield more ethanol.
Keywords
Full Text:
PDFReferences
Agrupis, SC, Birginias, MC, Cocson, AR, & Abenes, FB. 2015. Potential of Nipa (Nypa fruticans) as Feedstock for Village-Scale Bioethanol Production. Mariano Marcos State University, City of Batac, Ilocos Norte. 2015 In- House Review. ILAARDEC.
Chen H, Miao M, & Ding X. 2011. Chemical Treatments of Bamboo to Modify Its Moisture Absorption and Adhesion to Vinyl Ester Resin in Humid Environment. 1533-1542.
Hamilton, LS & Murphy, DH. 1988. Use and management of nipa palm (Nypa fruticans, Arecaceae): A review. Econ Bot.; 42(2): 206-13.
Hidayat IW. 2015. Natural production potency of nipa (Nypa fruticans) sap as production commodity for bioethanol. Pros Sem NasMasyBiodivIndon. 1(1): 109-13. http://dx.doi.org/10.13057/psnmbi/m010118
(MMSU) Mariano Marcos State University. (2018, February 06). Retrieved December 30, 2018, from www.mmsu.edu.ph/news/solon-ask- mmsu-to-help-minimize- importation-of-fuel-oils
Matsui N, Okimori Y, Takahashi F, Matsumura K, & Bamroongrugsa N. 2014. Nipa (Nypa fruticans Wurmb) Sap Collection in Southern Thailand. http://dx.doi.org/10.5539/enrr.v4n4p 75
Matsui N, Bamroongrugsa N, Morimune K, Miyasaka H, & Okimori Y. 2011. Nipa palm: A potential alternative source for bioethanol. Research Paper 14th Mangrove National Seminar [Thai], 319-324.
Radi NA. 2013. Physico-Chemical and Microbiological Changes during Fermentation and Storage of Nipa Sap (Nypa fruticans Wurmb). Master Thesis, Universiti Putra, Malaysia.
Sailer MF. 2005. Modelling the Moisture Induce Risk of Decay for Treated and Untreated Wood above Ground, Saxion University of Applied Sciences. https://doi.org/10.1515/HF.2000.019
Saka S, Nguyen DV, Harifara, & Rabemanolontso A. 2016. Sap from Various Palms as Renewable Energy Source for Bioethanol Production. 355-373.
Tamunaidu, P, Matsui, N, Okimori, Y, & Saka, S. 2013. Nipa (Nipa fruticans) sap as a potential feedstock for ethanol production. Biomass and Bioenergy, 52,96-102. http://hdl.handle.net/2433/174338
Tsuji K, Ghazalli MNF, Nordin Z, Khaidizar
MI, Dulloo ME, & Sebastian LS. 2011. Biological and Ethnobotanical Characteristics of Nipa Palm (Nypa fructicans Wurmb.): A Review. Sains Malays 40 (12): 1407-1412.
Refbacks
- There are currently no refbacks.