Drying of Empty Fruit Bunches as Wasted Biomass by Hybrid Solar–Thermal Drying Technique

Authors

  • H. H. Al-Kayiem Mech. Eng. Dept., Universiti Teknologi PETRONAS, Bandar Seri Iskandar, 31750 Tronoh, Perak, Malaysia
  • Y. Md Yunus Mechanical Engineer, Field Engineer, Ranhill Worley Parsons Sdn. Bhd

DOI:

https://doi.org/10.15282/jmes.5.2013.12.0063

Keywords:

solar dryer, hybrid solar dryer, biomass drying, EFB, palm oil solid waste, thermal backup.

Abstract

Solar drying of EFB is highly feasible and economic, but the solar drying process is interrupted during cloudy or rainy days and also at night. In the present paper, a combined solar, as the main heat input, and biomass burner, as an auxiliary source of thermal energy, has been investigated experimentally to dry EFB. An experimental model consisting of a solar dryer integrated with a thermal backup unit was designed and fabricated. A series of experimental measurements were carried out in four different drying modes, namely, open sun, mixed direct and indirect solar, thermal backup, and hybrid. The results from the four modes used to dry 2.5 kg of EFB were summarized and compared. The results indicated that the solar drying mode required around 52 to 80 hours to dry the EFB, while the open sun drying mode required 100 hours. Usage of the thermal backup as heat source reduced the drying time to 48–56 hours. With the hybrid mode, the drying time was considerably reduced to 24–32 hours. The results demonstrate that the combined solar and thermal backup effectively enhanced the drying performance. The application of a solar dryer with a biomass burner is practical for massive production of solid fuels from EFB.

References

Bena, B., & Fuller, R. J. (2002). Natural convection solar dryer with biomass back-up heater. Solar Energy, 72(1), 75-83.

Brammer, J. G., & Bridgwater, A. V. (1999). Drying technologies for an integrated gasification bio-energy plant. Renewable and Sustainable Energy Reviews, 3(4), 243-289.

Chua, N. S. (1991). Optimal utilization of energy sources in a palm oil processing complex Seminar on Development in Palm Oil Milling Technology and Environmental Management

Energy Information Bureau (EIB) Malaysia.). Retrieved April 22, 2010, from http://eib.org.my/index.php?page=article&item=100,136,143,152.

Hasibuan, R., & Daud, W. R. W. (2007). Through drying characteristic of oil palm empty fruit bunch (efb) fibers using superheated steam. Asia-Pacific Journal of Chemical Engineering, 2(1), 35-40.

Madhlopa, A., & Ngwalo, G. (2007). Solar dryer with thermal storage and biomass-backup heater. Solar Energy, 81(4), 449-462.

Mannan, A. (2008). Composting efb - empty fruit bunches of oil palm. Retrieved May 11, 2010, from http://www.etawau.com/OilPalm/EFB.htm.

Mastekbayeva, A. G., Chandika, P. B., Augustus, M. L., & Kumar, S. (1999). Experimental studies on a hybrid dryer. Paper presented at the ISES 99 Solar World Congress, Israel.

Naber, J. D., Siebers, D. L., Westbrook, C. K., Caton, J. A., & DiJulio, S. S. (1994). Natural gas autoignition under diesel conditions: Experiments and chemical kinetic modeling. SAE Technical Paper.

Prasad, J., Vijay, V. K., Tiwari, G. N., & Sorayan, V. P. S. (2006). Study on performance evaluation of hybrid drier for turmeric (curcuma longa l.) drying at village scale. Journal of Food Engineering, 75(4), 497-502.

Rahim, S., & Suffian, M. (2006). Development of specialty particleboard from oil palm fibre., from http://info.frim.gov.my/cfdocs/infocenter/highlight.NONIRPA _2006?08%20Rahim%20Sudin.pdf.

Serafica, E., & del Mundo, R. (2005). Design and qualitative performance of a hybrid solar-biomass powered dryer for fish. Paper presented at the World Renewable Energy Regional Conference, Jakarta, Indonesia.

Sulaiman, F., Abdullah, N., & Aliasak, Z. (2013). Solar drying system for drying empty fruit bunches. Journal of Physical Science, 24(1), 75-93.

Tarigan, E., & Tekasakul, P. (2005). A mixed-mode natural convection solar dryer with biomass burner and heat storage back-up heater. Paper presented at the Australia and New Zealand Solar Energy Society (ANZSES) Annual Conference, Dunedin NZ.

Thanaraj, T., Dharmasena, D., & Samarajeewa, U. (2004). Development of a rotary solar hybrid dryer for small scale copra processing. Tropical Agriculture Research, 16, 305-315.

Yunus, Y. M. (2011). Development and analysis of hybrid solar dryer with biomass backup heater. (Master's), Universiti Teknologi PETRONAS. Retrieved from http://utpedia.utp.edu.my/id/eprint/3060

Yunus, Y. M., Al-Kayiem, H. H., & Albaharin, K. A. K. (2011). Design of a biomass burner/gas-to-gas heat exchanger for thermal backup of a solar dryer. Journal of Applied Sciences, 11, 1929-1936.

Downloads

Published

2013-12-31

How to Cite

[1]
H. H. Al-Kayiem and Y. Md Yunus, “Drying of Empty Fruit Bunches as Wasted Biomass by Hybrid Solar–Thermal Drying Technique”, J. Mech. Eng. Sci., vol. 5, no. 1, pp. 652–661, Dec. 2013.

Issue

Section

Article