Thermochemical characterization of Nigerian Jatropha curcas fruit and seed residues for biofuel production

T. E. Odetoye , T. J. Afolabi , M. S. Abu Bakar , J. O. Titiloye

Energy, Ecology and Environment ›› 2018, Vol. 3 ›› Issue (6) : 330 -337.

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Energy, Ecology and Environment ›› 2018, Vol. 3 ›› Issue (6) : 330 -337. DOI: 10.1007/s40974-018-0104-0
Original Article

Thermochemical characterization of Nigerian Jatropha curcas fruit and seed residues for biofuel production

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Abstract

This study investigates the thermochemical properties of the separate components of jatropha biomass residues of Nigerian origin towards bio-oil production. The biomass residues (Jatropha curcas fruit shells and seed coat) were obtained from their mature jatropha fruits and subjected to physico-chemical characterization (structural composition analysis, thermogravimetric analysis, proximate and ultimate analyses). The structural compositions (extractives, hemicellulose, cellulose and lignin contents) of jatropha fruit shell and jatropha seed coat were 3%, 34.0%, 40.0% and 12.7%, and 42.3%, 32.5%, 10.5% and 5.7%, respectively. The thermogravimetric analysis showed that the ash contents of jatropha seed coat and jatropha fruit shell were 0.8% and 15.4%, respectively. The carbon contents were 48.3% and 41.5%, while measured calorific values were 20.06 MJ/kg and 17.14 MJ/kg for jatropha seed coat and fruit shell, respectively. The carbon, hydrogen, nitrogen and sulphur contents were found comparable with those in the literature. This study indicated that the thermochemical properties of the Nigerian Jatropha fruit and seeds residues were comparable with literature values and residues were found suitable for bio-oil production.

Keywords

Jatropha / Wastes / Residues / Thermogravimetric analysis / Biofuel / Nigeria

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T. E. Odetoye, T. J. Afolabi, M. S. Abu Bakar, J. O. Titiloye. Thermochemical characterization of Nigerian Jatropha curcas fruit and seed residues for biofuel production. Energy, Ecology and Environment, 2018, 3(6): 330-337 DOI:10.1007/s40974-018-0104-0

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References

Publishing order | Descend order by publishing year | Descend order by cited within
[1]

Adinurani GP, Hendroko RS, Wahono SK, Nindita A, Mairziwan M, Sasmito A, Nugroho YA, Liwang T. The performance of Jatropha curcas Linn. capsule husk as feedstocks biogas in one phase anaerobic digestion. Procedia Chem, 2015, 14: 316-325

[2]

Ajala OE, Aberuagba F, Odetoye TE, Ajala AM. Biodiesel: sustainable energy replacement to petroleum- based diesel fuel—a review. ChemBioEng Rev, 2015, 2(3): 145-156

[3]

Aransiola EF, Daramola MO, Ojumu TV, Aremu MO, Layokun SK, Solomon BO. Nigerian Jatropha curcas oil seeds: prospect for biodiesel production in Nigeria. Int J Renew Energy Res, 2012, 2(2): 317-325
[4]

ASTM (2000) Standard test method for gross calorific value of coal and coke. ASTM International D2015
[5]

ASTM (2003) Standard test method for compositional analysis by thermogravimetry. ASTM International E1131-03
[6]

Aysu T, Durak H, Güner S, Bengü A, Esim N. Bio-oil production via catalytic pyrolysis of Anchusa azurea: effects of operating conditions on product yields and chromatographic characterization. Biores Technol, 2016, 205: 7-14

[7]

British Standard BS EN 14774-3:2009 E (2009) Solid biofuels—determination of moisture content-oven dry method-part 3: moisture in general analysis sample
[8]

British Standard BS EN 14775:2009 E (2010) Solid biofuels—determination of ash content
[9]

Channiwala SA, Parikh PP. A unified correlation for estimating HHV of solid, liquid and gaseous fuels. Fuel, 2002, 81: 1051-1063

[10]

Chaudhary DR, Chikara J, Ghosh A. Carbon and nitrogen mineralization potential of biofuel crop (Jatropha curcas L.) residues in soil. J Soil Sci Plant Nutr, 2015, 14(1): 15-30
[11]

Gani A, Naruse I. Effect of cellulose and lignin content on pyrolysis and combustion characteristics for several types of biomass. Renew Energy, 2007, 32: 649-661

[12]

Garcia R, Pizarro C, Lavin AG, Bueno JL. Characterization of Spanish biomass waste for energy use. Biores Technol, 2012, 103: 249-258

[13]

Greenhalf CE, Nowakowski DJ, Bridgwater AV, Titiloye J, Yates N, Richie A, Shield I. Thermochemical characterisation of straws and high yielding perennial grasses. Ind Crop Prod, 2012, 36: 449-459

[14]

Jingura RM, Musademba D, Matengaifa R. An evaluation of utility of Jatropha curcas L. as a source of multiple energy carriers. Int J Eng Sci Tech, 2010, 27(2): 115-122
[15]

Kratzeisen M, Müller J. Energy from seed shells of Jatropha curcas. Landtechnik (Energy Prod), 2009, 64(6): 391-393
[16]

Lateef FA, Jere P, Yusuf D. Harnessing biofuel and economic potentials of Jatropha curcas for sustainable development in Nigeria: a review. Int J Renew Energy Technol Res, 2014, 3(1): 1-25
[17]

Manurung R, Wever DAZ, Wildschut J, Venderbosch RH, Hidayat H, van Dam JEG, Broekhuis EJ, Leijenhorst AA, Heeresa HJ. Valorisation of Jatropha curcas L. plant parts: nut shell conversion to fast pyrolysis oil. Food Bioprod Process, 2009, 87: 187-196

[18]

Murata K, Somwongsa P, Larkiattaworn S, Liu Y, Inaba M, Takahara I. Analyses of liquid products from catalytic pyrolysis of jatropha seed cakes. Energy Fuels, 2011, 25: 5429-5437

[19]

Murata K, Inaba M, Takahara I, Liu Y. Catalytic fast pyrolysis of jatropha wastes. J Anal Appl Pyrol, 2012, 94: 75-82

[20]

Odetoye TE, Ogunniyi DS, Olatunji GA. Improving Jatropha curcas Linnaeus oil alkyd drying properties. Prog Org Coat, 2012, 73: 374-381

[21]

Okeola FO, Odebunmi EO, Ameen OM. The conversion of the fruit pericarp and seed coat of Jatropha curcas to activated charcoal. Adv Biotechnol Chem Processes, 2011, 1: 17-21
[22]

Omar R, Idris A, Yunus R, Khalid K, Isma MI. Characterization of empty fruit bunch for microwave-assisted pyrolysis. Fuel, 2011, 90: 1536-1544

[23]

Parawira W. Biodiesel production from Jatropha curcas: a review. Sci Res Essays, 2010, 5(14): 1796-1808
[24]

Singh RN, Vyas DK, Srivastava NS, Narra M. SPERI experience on holistic approach to utilize all parts of Jatropha curcas fruit for energy. Renew Energy, 2008, 33: 1868-1873

[25]

Sinthupinyo P, Hayashi T, Habaki H, Egashara R. An efficient utilization of inedible fruit for fossil substitution. Chem Eng Trans, 2009, 18: 623-628
[26]

Sricharoenchaikul V, Atong D. Thermal decomposition study on Jatropha curcas L. waste using TGA and fixed bed reactor. J Anal Appl Pyrol, 2009, 85: 155-162

[27]

Thanapimmetha A, Luadsongkrama A, Titapiwatanakun B, Srinophakun P. Value added waste of Jatropha curcas residue: optimization of protease production in solid state fermentation by Taguchi DOE methodology. Ind Crops Prod, 2012, 37: 1-5

[28]

Titiloye JO, Abu Bakar MS, Odetoye TE. Thermochemical characterisation of agricultural wastes from West Africa. Ind Crops Prod, 2013, 47: 199-203

[29]

Tongpoothorn W, Sriuttha M, Homchan P, Chanthai S, Ruangviriyachai C. Preparation of activated carbon derived from Jatropha curcas fruit shell by simple thermo-chemical activation and characterization of their physico-chemical properties. Chem Eng Res Des, 2011, 89: 335-340

[30]

Van-Soest PJ, Robertson HB, Lewis BA. Method of dietary fiber and non-starch polysaccharides determination in relation to animal material. J Dairy Sci, 1991, 74: 3583-3591

[31]

Wever DZ, Heeres HJ, Broekhuis AA. Characterization of physic nut (Jatropha curcas L.) shells. Biomass Bioenerg, 2012, 37: 177-187

Funding

European Bioenergy Research Institute

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