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Characterization of fuel briquettes made from a blend of rice husk and palm oil mill sludge

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Abstract

In this study, the physical and combustion properties of briquettes produced from a blend of palm oil mill sludge (POMS) and rice husk were investigated. The POMS was blended with rice husk in the ratios of 1:10, 1:5, 3:10, 2:5, 1:2, 3:5, 7:10, 4:5, 9:10, and 1:1. The result showed that the increased addition of palm oil mill sludge in rice husk sample significantly influenced (p < 0.05) the physical and combustion properties of the briquettes produced. The mean values recorded for the compressed and relaxed densities, durability rating, and the water resistance were all observed to increase while the relaxation ratio decreased. The moisture content, volatile matter, heating value, and the elemental composition of the rice husk-POMS briquette blend also increased while the fixed carbon and the ash content decreased. The 1:1 blending ratio presented the best quality within the range of the blending ratios considered. The physical properties of the briquette at the 1:1 blending ratio were compressed density (1044.93 kg/m3), relaxed density (498.55 kg/m3), relaxation ratio (2.10), durability rating (99.61 %), and water resistance (25.24 h). The combustion properties were moisture content (10.42 % w.b.), volatile matter (76.23 %), ash content (15.13 %), fixed carbon (8.64 %), heating value (21.68 MJ/kg), carbon (40.19 %), hydrogen (5.18 %), oxygen content (38.91 %), sulfur (0.39 wt%), and nitrogen (1.61 wt%).

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References

  1. Amoo OM, Fagbenle RL (2013) Renewable municipal solid waste pathways for energy generation and sustainable development in the Nigerian context. Int J Energy Environ Eng 4:42

    Article  Google Scholar 

  2. Szyszlak-Barglowicz J, Zajac G, Piekarski W (2012) Energy biomass characteristics of chosen plants. Int Agrophys 26:175–179

    Article  Google Scholar 

  3. Eddine BT, Salah MM (2012) Solid waste as renewable source of energy: current and future possibility in Algeria. Int J Energy Environ Eng 3(17):1–12

    Google Scholar 

  4. Awasthi M, Deepika KR (2013) Biochemical characterization of agricultural residues for utilization in gasification process: a necessity for rural sector. Spec Issue Int J Sustain Dev Green Econ 2(1–2):22–26

    Google Scholar 

  5. Adkins E, Chen J, Winiecki J, Koinei P, Modi V (2010) Testing institutional biomass cookstoves in rural Kenyan schools for the Millennium Villages Project. Energy Sustain Dev 14(3):186–193

    Article  Google Scholar 

  6. Obi, OF (2015) Evaluation of the physical properties of composite briquette of sawdust and palm kernel shell. Biomass Convers Biorefin 5(3):271–277

    Article  Google Scholar 

  7. Obi, OF (2015) Evaluation of the effect of palm oil mill sludge on the properties of sawdust briquette. Renew Sust Energ Rev 52:1749–1758

    Article  Google Scholar 

  8. Kaliyan N, Morey RV (2009) Factors affecting strength and durability of densified biomass products. Biomass Bioenergy 33(3):337–359

    Article  Google Scholar 

  9. Wakchaure GC, Indra M (2009) Effect of binders on the physical quality of some biomass briquettes. J Agr Eng 46(4):24–30

    Google Scholar 

  10. Suhartini S, Hidayat N, Wijaya S (2011) Physical properties characterization of fuel briquette made from spent bleaching earth. Biomass Bioenergy 35(10):4209–4214

    Article  Google Scholar 

  11. Akowuah JO, Kemausuor F, SJ M (2012) Physico-chemical characteristics and market potential of sawdust charcoal briquette. Int J Energy Environ Eng 3(20):1–6

    Google Scholar 

  12. Dasappa S, Sridhar HV, Sridhar G, Paul PJ (2011) Science and technology aspects of bio-residue gasification. Biomass Convers Biorefin 1(3):121–131

    Article  Google Scholar 

  13. Obidziñski S (2014) Pelletization of biomass waste with potato pulp content. Int Agrophys 28:85–91

    Article  Google Scholar 

  14. Mitchual SJ, Frimpong-Mensah K, Darkwa NA, Akowuah JO (2013) Briquettes from combination of maize cobs and Ceiba pentandra at room temperature and low compacting pressure without a binder. Int J Energy Environ Eng 4:38

    Article  Google Scholar 

  15. Raslavičius L (2012) Characterization of the woody cutting waste briquettes containing absorbed glycerol. Biomass Bioenergy 45:144–151

    Article  Google Scholar 

  16. Stelte W, Holm JK, Sanadi AR, Barsberg S, Ahrenfeldt J, Henriksen UB (2011) A study of bonding and failure mechanisms in fuel pellets from different biomass resources. Biomass Bioenergy 35:910–918

    Article  Google Scholar 

  17. Gil MV, Oulego P, Casal MD, Pevida C, Pis JJ, Rubiera F (2010) Mechanical durability and combustion characteristics of pellets from biomass blends. Bioresour Technol 101:8859–8867

    Article  Google Scholar 

  18. Kong L, Tian SH, He C, Du C, Tu YT, Xiong Y (2012) Effect of waste wrapping paper fiber as a “solid bridge” on physical characteristics of biomass pellets made from wood sawdust. Appl Energy 98:33–39

    Article  Google Scholar 

  19. Razuan R, Finney KN, Chen Q, Sharifi VN, Swithenbank J (2011) Pelletised fuel production from palm kernel cake. Fuel Process Technol 92:609–615

    Article  Google Scholar 

  20. Finney KN, Sharifi VN, Swithenbank J (2009) Fuel pelletisation with a binder: part I—identification of a suitable binder for spent mushroom compost-coal tailing pellets. Eneergy Fuel 23:3195–3202

    Article  Google Scholar 

  21. Mediavilla I, Fernández MJ, Esteban LS (2009) Optimization of pelletisation and combustion in a boiler of 17.5 kWth for vine shoots and industrial cork residue. Fuel Processing Technol 90:621–628

    Article  Google Scholar 

  22. Oladeji JT (2010) Fuel characterization of briquettes produced from corncob and rice husk resides. Pac J Sci Technol 11(1):101–106

    Google Scholar 

  23. Dhamodaran A, Afzal MT (2012) Compression and springback properties of hardwood and softwood pellets. Bioresources 7(3):4362–4376

  24. Adapa PK, Singh A, Schoenau GJ, Tabil LG (2006) Pelleting characteristics of fractionated alfalfa grinds – hardness models. International Journal of Powder Handling and Processing 18(5):294–299

  25. Mani S, Tabil LG, Sokhansanj S (2006) Effects of compressive force, particle size and moisture content on mechanical properties of biomass pellets from grasses. Biomass and Bioenergy 97:1420–1426

  26. Mythili R, Venkatachalam P (2013) Briquetting of agro-residues. Journal of Scientific and Industrial Research 72:58–61

  27. Sotannde OA, Oluyege AO, Abah GB (2010) Physical and combustion properties of charcoal briquettes from neem wood residues. Int. Agrophysics 24:189–194

  28. Obi OF, Akubuo CO, Okonkwo WI (2013) Development of an appropriate briquetting machine for use in rural communities. International Journal of Engineering and Advanced Technology 2(4):578–582

  29. Suparin C, Suwit S, Prattana K (2008) Development of fuel briquettes from biomass-lignite blends. Chiang Mai J Sci. 35(1):43–50

  30. Richards SR (1990) Physical testing of fuel briquettes. Fuel Processing Technology 25:89–100

  31. ASTM (2004) Standard E711-87: Standard test method for gross calorific value of refuse-derived fuel by the bomb calorimeter. West Conshohocken, PA, USA

  32. Jigisha P, Channiwala SA, Ghosal GK (2007) A correlation for calculating elemental composition from proximate analysis of biomass materials. Fuel 86:1710–1719

  33. Jindaporn J, Chadchawan P, Aurawan T, Songchai W (2005) Physical properties and combustion performance of briquettes produced from two pairs of biomass species. ENETT 49-137:27–29

  34. Olorunnisola A (2007) Production of fuel briquettes from waste paper and coconut husk admixtures. Agric Eng Int CIGR E J 9:1–11

  35. Bisana BB, NB L (2008) Utilization of cashew nut shell residue for charcoal briquettes and activated carbon production. FPRDI J 24(2):25–37

  36. Wilaipon P (2007) Physical characteristics of maize cob briquette under moderate die pressure. Am. J. Appl. Sci. 4:995–998

  37. Husain Z, Zainac Z, Abdullah Z (2002) Briquetting of palm fibre and shell from the processing of palm nuts to palm oil. Biomass Bioenergy 22:505–509

  38. Mitchual SJ, Frimpong-Mensah K, Darkwa NA (2013) Effect of species, particle size and compacting pressure on relaxed density and compressive strength of fuel briquettes. Int J Energy Environ Eng 4:30

  39. Yaman S, SahanŞahan M, Haykiri-Açma H, Şeşen K, Küçükbayrak S (2001) Fuel briquettes from biomass-lignite blends. Fuel Process Technol 72(1):1–8

  40. Loo SV, Koppejan J (2008) The handbook of biomass combustion and co-firing. Earthscan, London

  41. Kim HJ, Lu GQ, Naruse I, Yuan J, Ohtake K (2001) Modeling combustion characteristics of bio-coal briquettes. J Energy Resour Technol 123:27–31

  42. Chou C, Lin S, Lu W (2009) Preparation and characterization of solid biomass fuel made from rice straw and rice bran. Fuel Process Technol 90(7–8):980–987

  43. He BB, JH v G, Thompson JC (2009) Sulfur content in selected oils and fats and their corresponding methyl esters. Appl Eng Agric 25(2):223–226

  44. Sotannde OA, Oluyege AO, Abah GB (2010) Physical and combustion properties of briquettes from sawdust of Azadirachta indica. Journal of Forestry Research 21(1):63–67

  45. Aina OM, Adetogun AC, Iyiola KA (2009) Heat energy from value-added sawdust briquettes of Albiziazygia. Ethiopian J Environ Stud Manag 2(1):42–49

  46. Acharya B, Dutta A (2015) Fuel property enhancement of lignocellulosic and nonlignocellulosic biomass through torrefaction. Biomass Convers Biorefin. doi: 10.1007/s13399-015-0170-x

  47. Grover PD, Mishra SK, JS C (1994) Development of an appropriate biomass briquetting technology suitable for production and use in developing countries. Energy Sustain Dev 1(11):45–48

  48. Hoekman SK, Broch A, Robbins C, Zielinska B, Felix L (2013) Hydrothermal carbonization (HTC) of selected woody and herbaceous biomass feedstocks. Biomass Convers Biorefin 3(2):113–126

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  1. Agricultural and Bioresources Engineering Department, Faculty of Engineering, University of Nigeria, Nsukka, Nigeria

    Okey Francis Obi & Kingsley Chukwudi Okongwu

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  1. Okey Francis Obi
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  2. Kingsley Chukwudi Okongwu
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Correspondence to Okey Francis Obi.

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Obi, O.F., Okongwu, K.C. Characterization of fuel briquettes made from a blend of rice husk and palm oil mill sludge. Biomass Conv. Bioref. 6, 449–456 (2016). https://doi.org/10.1007/s13399-016-0206-x

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  • DOI: https://doi.org/10.1007/s13399-016-0206-x

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