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Influence of Moisture Content, Particle Size, and Binder Ratio on Quality and Economics of Rice Straw Briquettes

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Abstract

Rice straw as solid residues are biomass residue materials that are not optimally used by farmers in Punjab and potentially become environmental pollutant. A large amount of rice straw (17 million tons) is generated and left as much in combine harvested rice fields in Punjab, India. It is very difficult to manage such huge amount of rice straw thus, farmers resort to burning it which leads to greenhouse gas emissions like CO2 due to open field burning and loss of rich organic matter present in the soil. Further due to imposition of restrictions by the state government, the practice of burning rice straw has now become an offense. So farmers are looking for alternatives which are economically viable. Rice straw can be effectively used as bio energy as it has about the same heating value (15 kJ kg−1) as that of wood, half that of good quality coal and one third of oil. The operational conditions required to produce high-quality chopped rice straw briquettes have not been determined and this study determined the optimal moisture content, particle size, and binder ratio required to produce rice straw briquettes. The optimized conditions resulted in formation of high-density (1030.38–1159.22 kg m−3) briquettes with durability ranging from 71.9 to 92.3% with minimum power requirement for briquetting (36.60 kW), maximum calorific value of 15.61 MJ kg−1, and minimum ash content (16.34%).Total cost of making chopped rice straw briquettes was 0.041 USD per kg and 0.00281 USD per mega joule of energy. Cost of briquetting from chopped rice straw with 10 and 20% cotton stalks was 0.050 and 0.051 USD per kg, respectively, and 0.0033 USD per mega joule of energy. Also, the briquettes prepared from chopped rice straw with and without cotton stalk as a binder were economically viable.

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References

  1. Ali MA, Nasir A, Muneer A, Ali S, Rashid U (2015) Compaction characteristics of sawdust, cotton stalks, maize straw and rice straw briquettes. J Energy Environ Carbon Credits 5(1):1–9

    CAS  Google Scholar 

  2. Anonymous 2014. www.indiastat.com . A site registered with main library, Punjab Agricultural University, Ludhiana (Accessed on August 20, 2015).

  3. ASTM Standard D1102–84 2001. Standard test method for ash in wood. ASTM International:West Conshohocken, PA.

  4. ASTM Standard E711–87 2004. Standard test method for gross calorific value of refuse-derived fuel by the bomb calorimeter. ASTM International:West Conshohocken, PA.

  5. Chou CS, Lin SH, Peng CC, Lu WC (2009) The optimum conditions for preparing solid fuel briquette of rice straw by a piston-mold process using the Taguchi method. Fuel Process Technol 90:1041–1046

    Article  CAS  Google Scholar 

  6. Dobermann A, Witt C (2000) The potential impact of crop intensification on carbon and nitrogen cycling in intensive rice systems. In: Kirk GJD, Olk DC (eds) Carbon and nitrogen dynamics in flooded soils. International Rice Research Institute, Los Baños, Philippines, pp 1–25

    Google Scholar 

  7. IS 9164–1979 (Reaffirmed 2002). Guide for estimating cost of farm machinery operation.

  8. Ishii K, Furuichi T (2014) Influence of moisture content, particle size and forming temperature on productivity and quality of rice straw pellets. Waste Manag 34(12):2621–2626

    Article  Google Scholar 

  9. Jenkins, B.M., Ebeling, J.M., 1985. Correlation of physical and chemical properties of terrestrial biomass with conversion. Symposium energy from biomass and waste IX, Institute of Gas Technology, Lake Buena Vista, FL (USA), Jan.28-Feb.1, 371.

  10. Mani S, Tabil LG, Sokhansanj S (2006) Specific energy requirement for compacting corn stover. Bioresour Technol 97(12):1420–1426

    Article  CAS  Google Scholar 

  11. Rezvani Z, Chegini GR, Arabhosseini A, Kianmehr MH (2013) Environmental control with recycling of rice straw briquettes. J Automot Appl Mech 1(1):14–20

    Google Scholar 

  12. Sahay, K.M., Singh, K.K., (ed) 2001. Unit operations of agricultural processing. Vikas Publishing House Pvt. Ltd., 109

  13. Sahin, S., Sumnu, S.G., 2006. Size, shape, volume and related attributes. In: Physical properties of foods. Springer science + Business media, LLC, New York, 19–20

  14. Sharma PK, Mishra B (2001) Effect of burning of rice and wheat crop residue, Loss of N P K and S from soil and changes in the nutrient availability. J Indian Soc Soil Sci 49(3):425–426

    CAS  Google Scholar 

  15. Singh A, Singh Y (1982) Briquetting of paddy straw. Agric Mech Asia Africa Latin Am Autumn 13(4):42–44

    Google Scholar 

  16. Singh AK, Singh S, Sidhu GK, Kumar M (2012) Studies on briquetting of paddy straw. Environ Ecol 30(3):435–440

    Google Scholar 

  17. Singh J, Singh L, Singh G (2013) Evaluation of crop residue potential for power generation for Indian state Punjab. IOSR J Agric Vet Sci 4(4):99–112

    Article  Google Scholar 

  18. Tripathi AK, Iyer PVR, Kandpal TC (1998) A techno-economic evaluation of biomass briquetting in India. Biomass Bioenergy 14(5):479–488

    Article  CAS  Google Scholar 

  19. Wang Q, Han K, Gao J, Li H, Lu C (2017a) The pyrolysis of biomass briquettes: effect of pyrolysis temperature and phosphorus additives on the quality and combustion of bio-char briquettes. Fuel 199(1):488–496

    Article  CAS  Google Scholar 

  20. Wang Q, Han K, Wang J, Gao J, Lu C (2017b) Influence of phosphorous based additives on ash melting characteristics during combustion of biomass briquette fuel. Renew Energy 113:428–437

    Article  CAS  Google Scholar 

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This research did not receive any specific grant from funding agencies in the public, commercial or not-for-profit sectors.

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Authors and Affiliations

  1. Department of Farm Machinery and Power Engineering, Punjab Agricultural University, Ludhiana, Punjab, India

    Nishant Gill & Baldev Dogra

  2. School of Renewable Energy Engineering, Punjab Agricultural University, Ludhiana, Punjab, 141001, India

    Nishant Gill & Ritu Dogra

Authors
  1. Nishant Gill
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  2. Ritu Dogra
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  3. Baldev Dogra
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Correspondence to Nishant Gill or Ritu Dogra.

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Gill, N., Dogra, R. & Dogra, B. Influence of Moisture Content, Particle Size, and Binder Ratio on Quality and Economics of Rice Straw Briquettes. Bioenerg. Res. 11, 54–68 (2018). https://doi.org/10.1007/s12155-017-9877-9

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