skip to main content

Energy Efficient Dryer with Rice Husk Fuel for Agriculture Drying

1Department of Chemical Engineering,Faculty of Engineering, Diponegoro University, Jl Prof H. Soedarto, Tembalang, Semarang, Indonesia 50276, Indonesia

2BPTP Research Agency Ministry of Farming Chapter Central Java, Indonesia, Jl Sidomulyo 40, Ungaran, Central Java, Indonesia 50501, Indonesia

3BBP Mektan (Farming Machinery) Research Agency Ministry of Farming, Indonesia, Situgadung, Tromol Pos 2 Serpong, Tanggerang, Banten, Indonesia 15310, Indonesia

Published: 15 Feb 2015.
Editor(s):

Citation Format:
Abstract

Energy usage is crucial aspect on agriculture drying process. This step spends about 70% of total energy in post harvest treatment. The design of efficient dryer with renewable energy source is urgently required due to the limitation of fossil fuel energy. This work discusses the performance of air dehumidification using rice husk fuel as heat source for onion, and paddy drying. Unlike conventional dryer, the humidity of air during the drying was dehumidified by adsorbent. Hence, the driving force of drying can be  kept high.  As consequences, the drying time and energy usage can be reduced. Here, the research was conducted in two step: laboratory and pilot scale tests. Results showed that the lowering air humidity with rice husk fuel has improved the energy efficiency. At operational temperature 60oC, the heat efficiency of 75%  was achieved.

 

Fulltext View|Download
Keywords: adsorbent, dehumidified, heat efficiency, onion, paddy

Article Metrics:

  1. Atuonwu, J.C.; van Straten, G.; van Deventer, H.C.; van Boxtel, A.J.B. (2011). Optimizing energy efficiency in low temperature drying. Chemical Engineering Transaction 25: 111 – 116
  2. Djaeni, M.; Bartels P.V.; van Asselt, C.J.; Sanders J.P.M.; van Straten, G.; van Boxtel, A.J.B. (2009). Assessment of a Two-Stage Zeolite Dryer for Energy Efficient Drying. Journal of Drying Technology 27(10): 1205 - 1216
  3. Djaeni, M.; Sasongko, S.B.; van Boxtel, A.J.B. (2013a). Enhancement of energy efficiency and food product quality using adsoprtion dryer with zeolite. Int. Journal of Renewable Energy Development 2(2): 81 – 86
  4. Djaeni, M.; Ayuningtyas, D.; Asiah, N.; Hargono, H. Ratnawati, R.; Jumali, J.; Wiratno, W. (2013b). Paddy drying in mixed adsorption dryer with zeolite: Drying rate and time estimation. Reaktor 14(3): 173 – 178
  5. Djaeni, M.; Asiah, N. (2014). Heat efficiency of paddy drying in fluidized bed dryer using rice husk fuel. National Seminar, UPN Veteran Yogyakarta, Indonesia
  6. Gilmour, J.E.; Oliver, T.N.; Jay, S .(2004). Energy use for drying process: The potential benefits of airless drying. In: Energy aspects in drying; Kudra T. Drying Technology 22(5): 917 - 932
  7. Kudra T. (2004). Energy aspects in drying. Drying Technology 22(5): 917 – 932
  8. Ratti, C. (2001). Hot air and freeze-drying of high-value foods: A review. Journal of Food Engineering 49: 311 - 319
  9. Revilla, G.O.; Velázquez, T.G.; Cortés, S.L.; Cárdenas, S.A .(2006). Immersion drying of wheat using Al-PILC, zeolite, clay, and sand as particulate media. Drying Technology 24(8), 1033-1038
  10. Soponronnarit, S., (1999). Fluidized-bed paddy drying. Science Asia :51 - 56 ( http://www.scienceasia.org/ accessed 22nd January 2013)
  11. Taweerarattanapanish, A.; Soponronnarit, S.; Wetchakama, S.; Kongseri, N.; Wongpiyachon, S. (1999). Effects of drying on head rice yield using fluidization technique. Drying Technology 17(2): 346 - 353. DOI: 10.1080/07373939908917535
  12. Witinantakit, K.; Prachayawarakom, S.; Nathakaranakule, A.; Soponronnarit, S. (2006). Paddy drying using adsorption technique: Experiments and simulation. Drying Technology, 24 (5): 609 - 617

Last update:

  1. Air dehumidification with advance adsorptive materials for food drying: A critical assessment for future prospective

    Mohamad Djaeni, Dewi Qurrota A’yuni, Misbahudin Alhanif, Ching Lik Hii, Andri Cahyo Kumoro. Drying Technology, 39 (11), 2021. doi: 10.1080/07373937.2021.1885042
  2. Evaluation of food drying with air dehumidification system: a short review

    M Djaeni, F D Utari, S B Sasongko, A C Kumoro. IOP Conference Series: Earth and Environmental Science, 102 , 2018. doi: 10.1088/1755-1315/102/1/012069
  3. Performance Evaluation of Pneumatic Dryer for Aren (Arenga piñata) Flour

    Suherman Suherman, Nur Hidayati, A.C. Kumoro, Hadiyanto, S.A. Roces, L. Yung, X. Rong, A.W. Lothongkum, M.T. Phong, M.A. Hussain, W.R.W. Daud, P.T.S. Nam. MATEC Web of Conferences, 156 , 2018. doi: 10.1051/matecconf/201815605023
  4. Parametric optimization and statistical evaluation of a spray dryer for the evaporation of caustic soda solution

    B.A. Olufemi, M.K. Ayomoh. Heliyon, 5 (7), 2019. doi: 10.1016/j.heliyon.2019.e02026

Last update: 2024-10-11 02:43:36

  1. Air dehumidification with advance adsorptive materials for food drying: A critical assessment for future prospective

    Mohamad Djaeni, Dewi Qurrota A’yuni, Misbahudin Alhanif, Ching Lik Hii, Andri Cahyo Kumoro. Drying Technology, 39 (11), 2021. doi: 10.1080/07373937.2021.1885042
  2. Evaluation of food drying with air dehumidification system: a short review

    M Djaeni, F D Utari, S B Sasongko, A C Kumoro. IOP Conference Series: Earth and Environmental Science, 102 , 2018. doi: 10.1088/1755-1315/102/1/012069
  3. Performance Evaluation of Pneumatic Dryer for Aren (Arenga piñata) Flour

    Suherman Suherman, Nur Hidayati, A.C. Kumoro, Hadiyanto, S.A. Roces, L. Yung, X. Rong, A.W. Lothongkum, M.T. Phong, M.A. Hussain, W.R.W. Daud, P.T.S. Nam. MATEC Web of Conferences, 156 , 2018. doi: 10.1051/matecconf/201815605023
  4. Parametric optimization and statistical evaluation of a spray dryer for the evaporation of caustic soda solution

    B.A. Olufemi, M.K. Ayomoh. Heliyon, 5 (7), 2019. doi: 10.1016/j.heliyon.2019.e02026