Feasibility study of gasification of oil palm fronds

Authors

  • S.A. Sulaiman Department of Mechanical Engineering, Universiti Teknologi PETRONAS, 36210 Bandar Seri Iskandar, Perak, Malaysia
  • S. Balamohan Reliability and Integrity Engineering Department, PETRONAS Carigali Sdn. Bhd, Miri, Sarawak, Malaysia
  • M.N.Z. Moni Department of Mechanical Engineering, Universiti Teknologi PETRONAS, 36210 Bandar Seri Iskandar, Perak, Malaysia
  • S.M. Atnaw Faculty of Engineering Technology, Universiti Malaysia Pahang, Lebuhraya Tun Razak, 26300 Pahang, Malaysia
  • A.O. Mohamed Faurecia Emission Control Technologies, 2301 Commerce Center Dr, Franklin, Ohio 45005, USA

DOI:

https://doi.org/10.15282/jmes.9.2015.20.0168

Keywords:

Gasification; biomass; solid fuel; syngas; combustion; energy

Abstract

Considering the large and consistent supply, oil palm fronds could be a promising source of biomass energy through gasification. There is very scarce information on the characteristics of oil palm fronds, which is vital in deciding if such biomass is technically suitable for gasification. In the present work, the feasibility of oil palm fronds for biomass gasification is studied. The study is conducted experimentally via standard tests to determine their thermochemical characteristics. Ultimate analysis is conducted to determine the contents of carbon, nitrogen, hydrogen and sulphide in oil palm fronds. Proximate analysis is performed to identify the burning characteristics of the biomass. The energy content in the fronds is determined by using a bomb calorie meter and is around 18 MJ/kg. The ignitability of the fronds is also studied experimentally to assess the ease to start-up combustion of the fronds. The characteristics of the flame of the resulting syngas from gasification of oil palm fronds are qualitatively studied. Simulated syngas composition study reveals potentials of 22% CO, 1.3% H2, 18.5% CO2 and traces of CH4. The study is extended to computer simulation to predict composition of the syngas. It is found from this work that oil palm fronds are feasible for gasification and has a good potential as a renewable energy source.

References

MPOB (Malaysian Palm Oil Board). Malaysian Palm oil industry performance 2008. Global Oils and Fats Business Magazine. 2009;6:1-4.

Griffin WM, Michalek J, Matthews HS, Hassan MNA. Availability of biomass residues for co-firing in Peninsular Malaysia: Implications for cost and GHG emissions in the electricity sector. Energies. 2014;7:804-23.

Wan Zahari M, Sato J, Furuichi S, Azizan A, Yunus M. Commercial processing of oil palm fronds feed in Malaysia. Forages and feed resources in commercial livestock production systems 8th Meeting of the Regional Working Group on Grazing and Feed Resources for Southeast Asia, Kuala Lumpur, Malaysia; 2003.

p. 59-65.

Chan K, Watson I, Lim K. Use of oil palm waste material for increased production. Planter. 1981;57:14-37.

Konda R, Sulaiman SA, Ariwahjoedi B. Syngas production from gasification of oil palm fronds with an updraft gasifier. Journal of Applied Sciences. 2012;12:2555.

Hassan OA, Ishida M, Shukri IM, Tajuddin ZA. Oil-palm fronds as a roughage feed source for ruminants in Malaysia: ASPAC, Food and Fertilizer Technology Center; 1996.

MEC. Electricity supply industry in Malaysia: Performance and statistical information 2014. Putrajaya: Malaysia Energy Commission; 2015.

Alam SS, Omar NA, Ahmad MSB, Siddiquei H, Nor SM. Renewable Energy in Malaysia: Strategies and Development. Environmental Management and Sustainable Development. 2013;2:51.

de Chazournes LB. Kyoto Protocol to the United Nations Framework Convention on Climate Change. UN’s Audiovisual Library of International Law (http://untreaty un org/cod/avl/ha/kpccc/kpccc html). 1998.

Muda N, Boosroh M. Gasification of coal-petcoke blends in a pilot scale gasification plant. International Journal of Automotive and Mechanical Engineering. 2013;8:1457-66.

Gaqa S, Mamphweli S, Katwire D, Meyer E. The properties and suitability of various biomass/coal blends for co-gasification purposes. Journal of Sustainable Bioenergy Systems. 2014; 4:175-82.

Lahijani P, Zainal ZA, Mohamed AR, Mohammadi M. Co-gasification of tire and biomass for enhancement of tire-char reactivity in CO2 gasification process. Bioresource Technology. 2013;138:124-30.

Brar J, Singh K, Wang J, Kumar S. Cogasification of coal and biomass: a review. International Journal of Forestry Research. 2012; Article ID 363058, 1-10.

Hagos FY, Aziz ARA, Sulaiman SA. Trends of syngas as a fuel in internal combustion engines. Advances in Mechanical Engineering. 2014;6:401587.

Hagos FY, Aziz ARA, Sulaiman SA. Study of syngas combustion parameters effect on internal combustion engine. Asian Journal of Scientific Research. 2013;6:187.

Bridgwater A. Thermal processing of biomass for fuels and chemicals. Renewable Bioenergy-Technologies, Risks and Rewards. 2003;3:33-61.

Hassan M, Yacob S. Biomass utilization in Malaysia: Current status of conversion biomass into bioproducts. University Putra Malaysia, Malaysia; 2005.

Jain A. Design parameters for a rice husk throatless gasifier reactor. International Commission of Agricultural Engineering, USA; 2006.

Kobayashi N, Tanaka M, Piao G, Kobayashi J, Hatano S, Itaya Y, et al. High temperature air-blown woody biomass gasification model for the estimation of an entrained down-flow gasifier. Waste Management. 2009;29:245-51.

Chong CN, Idrus AZ. Biomass energy potential in Malaysia. Asean Journal on Science and Technology for Development. 1998;5:15-27.

Biaginia E, Barontiniab F, Tognottiab L. Gasification of agricultural residues in a demonstrative plant. Chemical Engineering. 2014;37.

Begum S, Rasul MG, Akbar D, Ramzan N. Performance analysis of an integrated fixed bed gasifier model for different biomass feedstocks. Energies. 2013;6:6508- 24.

Thorson O, Wennberg O. Suitable drying processes and their integration with the gasification and DME-synthesis process. S.E.P. Scandinavian Energy Project AB, Report No. CHRISGAS August 2006 WP6 D43; 2006.

Kumar A, Jones DD, Hanna MA. Thermochemical biomass gasification: a review of the current status of the technology. Energies. 2009;2:556-81.

Lange S, Pellegrini L. Sustainable combined production of hydrogen and energy from biomass in Malaysia. Chemical Engineering Transaction. 2013;32:607-12.

Shafie S, Mahlia T, Masjuki H, Ahmad-Yazid A. A review on electricity generation based on biomass residue in Malaysia. Renewable and Sustainable Energy Reviews. 2012;16:5879-89.

Nasrin A, Ma A, Chow M, Hamdan H, Choo Y. Blending of palm biomass and coal: an alternative fuel for power generation in Malaysia. Oil Palm Industry Economic Journal. 2006;6:31-6.

Abas R, Kamaruddin M, Nordin A, Simeh M. A study on the Malaysian oil palm biomass sector—supply and perception of palm oil millers. Oil Palm Industry Economic Journal. 2011;11:28-41.

Abdullah SS, Yusup S. Method for screening of Malaysian biomass based on aggregated matrix for hydrogen production through gasification. Journal of Applied Sciences(Faisalabad). 2010;10:3301-6.

Sulaiman SA, Karim MF, Nazmi M, Moni Z, Atnaw SM. On gasification of different tropical plant-based biomass materials. Asian Journal of Scientific Research. 2013;6(2): 245-53.

Moni M, Sulaiman SA. Downdraft gasification of oil palm frond: effects of temperature and operation time. Asian Journal of Scientific Research. 2012; 12: 2574-9.

Sulaiman SA, Razali NHM, Konda RE, Atnaw SM, Moni MNZ. On Diversification of feedstock in gasification of oil palm fronds. Journal of Mechanical Engineering and Sciences. 2014; 6:907-15.

Sulaiman S, Atnaw SM, Moni M. Experimental study on temperature profile of fixed-bed gasification of oil-palm fronds. International Journal of Technology. 2012;3:35-44.

Moni M, Sulaiman S. Method of processing oil palm frond into biomass fuel for downdraft gasification. 3rd ICPER. Kuala Lumpur, Malaysia; 2012.

Guangul FM. Gasification of oil palm fronds with preheated inlet air: Universiti Teknologi Petronas; 2013.

Atnaw SM, Sulaiman SA, Yusup S. A simulation study of downdraft gasification of oil-palm fronds using ASPEN PLUS. Journal of Applied Sciences. 2011;11:1913-20.

Atnaw SM, Sulaiman SA, Yusup S. Downdraft gasification of oil-palm fronds. Trends in Applied Sciences Research. 2011;6:1006.

Moni MNZ, Sulaiman SA. Downdraft Gasification of Oil Palm Frond: Lambert Academic Publishing; 2012.

Standard A. ASTM standards-D3176-89 standard practice for ultimate analysis of coal and coke. Annual book of ASTM standards, Section. 2002;5.

Standard A. ASTM E1131-03 Standard test method for compositional analysis by thermogravimetry. West Conshohocken, PA: American Society for Testing and Materials; 2004.

Standard A. A standard test method for gross calorific value of coal and coke. ASTM D5865. 2007.

Fock F, Thomsen KP, Houbak N, Henriksen UB. Modelling a biomass gasification system by means of EES. SIMS 2000. 2000:179-86.

Atnaw SM, Sulaiman SA. Modeling and simulation study of downdraft gasifier using oil-palm fronds. 3rd International Conference on Energy and Environment; 2009. p. 284-9.

Zeeshan M, Arbab MN. Waste Heat Recovery and its Utilization for Electric Power Generation in Cement Industry. International Journal of Engineering and Technology. 2015;15.

McKendry P. Energy production from biomass (part 3): gasification technologies. Bioresource Technology. 2002;83:55-63.

Turns SR. An introduction to combustion: McGraw-hill New York; 1996.

Ganan J, Abdulla AA-K, Correa EC, Macías-García A. Energetic exploitation of vine shoot by gasification processes: a preliminary study. Fuel Processing Technology. 2006;87:891-7.

Madhiyanon T, Lapirattanakun A, Sathitruangsak P, Soponronnarit S. A novel cyclonic fluidized-bed combustor (ψ-FBC): Combustion and thermal efficiency, temperature distributions, combustion intensity, and emission of pollutants. Combustion and Flame. 2006;146:232-45.

Shuangning X, Weiming Y, Li B. Flash pyrolysis of agricultural residues using a plasma heated laminar entrained flow reactor. Biomass and Bioenergy. 2005;29:135-41.

Reed TB, Jantzen D. Generator Gas, The Swedish experience from 1939-1945. Solar Energy Research Institute, Colorado, USA; 1979.

Gomes MdLI, Osório E, Vilela ACF. Thermal analysis evaluation of the reactivity of coal mixtures for injection in the blast furnace. Materials Research. 2006;9:91- 5.

Moni M, Sulaiman SA. A preliminary study on synthesis gas produced by gasification of oil palm fronds. International Conference of Plant and Equipment Reliability Kuala Lumpur, Malaysia, 2010.

Hoglund C. Agricultural residues as fuel for producer gas generation. The Beijer Institute, Stockholm, Sweden; 1981.

Skov NA, Paperworth M. The pegasus unit. Pegasus Pub, Inc, Olympia, Washington, Mercury Press, Tacoma, Washington;1974.

Mahgoub BK, Sulaiman S, Abdul Karim Z. Performance study of imitated syngas in a dual-fuel compression ignition diesel engine. International Journal of Automotive and Mechanical Engineering. 2015;11: 2282-93.

Mahgoub B, Sulaiman S, Karim Z, Hagos F. Experimental study on the effect of varying syngas composition on the emissions of dual fuel CI engine operating at various engine speeds. IOP Conference Series: Materials Science and Engineering: IOP Publishing; 2015. p. 012006.

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Published

2015-12-31

How to Cite

[1]
S. . Sulaiman, S. Balamohan, M.N.Z. Moni, S.M. Atnaw, and A.O. Mohamed, “Feasibility study of gasification of oil palm fronds”, J. Mech. Eng. Sci., vol. 9, pp. 1744–1757, Dec. 2015.

Issue

Vol. 9 (2015): December 2015

Section

Review

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