DOI: 10.5937/jaes0-28385
This is an open access article distributed under the CC BY 4.0
Volume 19 article 803 pages: 375-382
The purpose of this study was to determine the effect of use ember element from woven nickel wire to increasing
the efficiency of the LPG stoves. It is supposed that high-temperature embers can burn more fuel around the wire,
thereby increasing the area of complete combustion. The test was conducted by means of a Water Boiling Test
(WBT) and the number of ember layers varied from one to four. It was found that the use of elements of fire without
reflectors could increase efficiency by 8.32%, with the highest efficiency being with the use of a single layer ember
element of the fire, of 61.71%. However, the use of elements of fire in the finned heat reflectors causes efficiency to
decrease, as the pattern to put elements of fire interfere with the reflectivity. This means the heat reflection is blocked
by the pattern and trapped between the reflector and pattern elements. As a result, the heat energy from the reflector
reflection cannot be forwarded to the combustion zone. The test results also show that the temperature distribution
from ember element use can increase the area of complete combustion.
This work was supported by the Beasiswa Program Pascasarjana
Dalam Negeri (BPPDN) from the Ministry for
Research and Technology Higher Education of Indonesia,
with contract No. 3594/UN10.14/KU/2015. In addition,
we would like to thank Prof. Dr. Eng. Mikrajuddin
Abdullah from the Bandung Institute of Technology, Indonesia,
Rizal Arifin, M.Si, Ph.D. from Muhammadiyah
University of Ponorogo, Indonesia, and Aceng Sambas,
M.Si, Ph.D. from Muhammadiyah University of Tasikmalaya,
Indonesia.
1. Khan, M. Y., Saxena, A. (2013). Performance of LPG cooking stove using different design of burner heads. International Journal of Engineering Research & Technology (IJERT), vol. 2, no. 7, 656-659.
2. Wu, C.Y., Chen, K.H., Yang, S.Y. (2014). Experimental study of porous metal burners for domestic stove applications. Energy Conversion and Management, vol. 77, 380-388, DOI: 10.1016/j.enconman. 2013.10.002
3. Zhen, H. S., Leung, C. W., Wong, T. T. (2014). Improvement of domestic cooking flames by utilizing swirling flows. Fuel, vol. 119, 153–156, DOI: 10.1016/j.fuel.2013.11.025
4. Dongbin, Z., Jinsheng, L., Guangchuan, L., Yan, D., Gang, X., Lihua L. (2007). Effects on combustion of liquefied petroleum gas of porous ceramic doped with rare earth elements. Journal of Rare Earths, vol. 25, 212-215, DOI: 10.1016/S1002-0721(07)60472-4
5. Muthukumar, P., Shyamkumar, P.I. (2013). Development of novel porous radiant burners for LPG cooking applications. Fuel, vol. 112, 562-566, DOI: 10.1016/j.fuel.2011.09.006
6. Mishra, N.K., Mishra, S.C., Muthukumar, P. (2015). Performance characterization of a medium-scale liquefied petroleum gas cooking stove with a two-layer porous radiant burner. Applied Thermal Engineering, vol. 89, 44-50, DOI: 10.1016/j.applthermaleng. 2015.05.077
7. Pantangi, V.K., Mishra, S.C., Muthukumar, P., Reddy, R. (2011). Studies on porous radiant burners for LPG (Liquefied Petroleum Gas) cooking applications. Energy, vol. 36, no. 10, 6074-6080, DOI: 10.1016/j.energy.2011.08.008
8. Mishra, N., K., Muthukumar, P. (2018). Development and testing of energy efficient and environment friendly porous radiant burner operating on liquefied petroleum gas. Applied Thermal Engineering, vol. 129, 482–489, DOI: 10.1016/j.applthermaleng. 2017.10.068
9. Abdurrachim, Wardani, D., Yudi, T. (2009). Fuel saver on household gas stoves. Jurnal Teknik Mesin, vol. 24 no. 1, 57-66.
10. Gohil, P., P., Channiwala, S., A. (2011). Experimental investigation of performance of conventional LPG cooking stove. Fundamental Journal Thermal Science and Engineering, vol. 1, no. 1, 25-34.
11. Syahrial, M. (2012). High efficiency biogas-stove fuel performance by adding reflectors. Bachelor thesis, Institut Teknologi Sepuluh November, Indonesia.
12. Sudarno, Fadelan (2015). The Improvement of The Efficiency of LPG Stoves Using Finned Heat Radiation Reflector. Jurnal Ilmiah Semesta Teknika, vol. 18, no. 1, 94–105.
13. Widodo, A. S. (2014). Radiation sheath for efficient use of energy in gas stoves. Jurnal Rekayasa Mesin, vol. 5 no. 3, 291–295.
14. Aisyah, L., Rulianto, D., Wibowo, C., S. (2015). Analysis of the Effect of Preheating System to Improve Efficiency in LPG-fuelled Small Industrial Burner. Energy Procedia, Vol. 65, 180-185, DOI: 10.1016/j. egypro.2015.01.055
15. World Bank, E., D. (1985). Test results on kerosene and others stoves for developing countries.
16. VITA, Volunteers in Technical Assistance, (1982). Testing the efficiency of woodburning cookstoves: international standards, Mt. Rainier, Maryland, USA.
17. EPA., PCIA., A. (2007). The water boiling test, Series: 4.2.2 (January), 1-86.
18. EPA., PCIA., A. (2014). The water boiling test, Series: 4.2.3 (March), 1-86.
19. L’Orange C., Defoort, M., Willson, B. (2012). Influence of testing parameters on biomass stove performance and development of an increased testing protocol. Energy for Sustainable Development, vol. 16, no. 1, 3-12, DOI: 10.1016/j.esd.2011.10.008
20. Mac Carty, N., Still, D., Ogle, D. (2010). Fuel use and emissions performance of fifty cooking stoves in the laboratory and related benchmarks of performance. Energy for Sustainable Development, vol. 14, no. 3, 161-171, DOI: 10.1016/j.esd.2010.06.002
21. Muthukumar, P., Anand, P., Sachdeva, P. (2011). Performance analysis of porous radiant burners used in LPG cooking stove. International Journal of Energy and Environment, vol. 2, no. 2, 367–374.
22. Kotb, A., Saad, H., (2017). Case study for co and counter swirling domestic burners. Case Studies in Thermal Engineering, vol. 11, 98–104, DOI: 10.1016/j.csite.2018.01.004