International Journal on Advanced Science, Engineering and Information Technology

Nowadays, the global energy crisis has been encouraging the development of renewable energy. Biomass has emerged as one of the most attractive renewable energy sources in Indonesia. Compared with fossil fuels, biomass is available in abundant quantity, renewable, and non-toxic. Pyrolitic, a method to process biomass, was performed in a household cook stove (also known as a pyrolitic stove). The pyrolitic stove will be developed as an option for substituting traditional cook stove improve the thermal efficiency. In this study, the pyrolitic of twigs of Indonesian teak in the pyrolitic stove was investigated. The influence of bottom air apertures on the household pyrolitic stove performance was studied. It was found that the decreasing number of bottom air apertures resulted in a longer leg-phase of temperature change, higher char yield, lower ash yield, and energy recovery. However, the temperature change was only slightly affected by one-third open outer air apertures condition. According to the condition performed in this study, 60 bottom air apertures in the stove provided an optimum energy recovery for cooking.

renewable energy; biomass; teak; pyrolytic stove; bottom air holes

S. Wang, H. Lin, B. Ru, G. Dai, X. Wang, G. Xiao, and Z. Luo, “Kinetic modelling of biomass components pyrolitic using a sequential and coupling method ,“ Fuel, 2016, vol. 185, pp. 763-771.

H. Dewajani, Rochmadi, S. Purwono, and A. Budiman, “Catalytic cracking of Indonesian Nyamplung oil (Calophyllum inophyllum) for bio-fuels production using ZSM-5 catalyst,†Journal of Engineering Science and Technology, 2015, vol. 10 spec.issue. 7, pp. 61-69.

Daniyanto, Sutijan, Deendarlianto and A. Budiman, “Reaction kinetic pyrolitic in mechanism of pyrolitic-gasification process of dry torrified-sugarcane bagasse,†ARPN Journal of Engineering and Applied Sciences, 2016, vol. 11 no. 16, pp. 9974-9980.

Y.S. Pradana, A. Hidayat, A. Prasetya and A. Budiman, “Application of coconut-shell activated carbon as heterogeneous solid catalyst for biodiesel synthesis,†Defect and Diffusion Forum, 2018, vol. 382, pp. 280-285.

B. Brandelet, C. Rose, C. Rogaume, and Y. Rogaume, “Investigation of the organic carbon ratio analysis on particles from biomass combustion and its evolution in three generations of firewood stoves,†Biomass and Bioenergy, 2017, vol. 99, pp. 106-115.

V. Leban, S.P. Malovrh, L.Z. Stirn and J. Krc, “Forest biomass for energy in multi-functional forest management: Insight into the perceptions of forest-related professionals,†Forest Policy and Economics, 2016, vol 71, pp. 87-93.

H. Sudibyo, Y.S. Pradana, A. Budiman and W. Budhijanto, “Municipal Solid Waste Management in Indonesia – A study about selection of proper solid waste reduction method in D.I. Yogyakarta Province,†Energy Procedia, 2017, vol. 143, pp. 494-499.

C. L’orange, J. Volckens, and M. DeFoort, “Influence of stove type and cooking pot temperature on particulate matter emissions from biomass cook stoves,†Energy for Sustainable Development, 2012, vol. 16, pp. 448-455.

R. Suresh, V.K. Singh, J.K. Malik, A. Datta, R.C. Pal, “Evaluation of the performance of improved biomass cooking stoves with different solid biomass fuel types,†Biomass and Bioenergy, 2016, vol. 95, pp. 27-34.

M.M. Roy, and K.W. Corscadden, “An experimental study of combustion and emissions of biomass briquettes in a domestic wood stove,†Applied Energy, 2012, vol. 99, pp. 206-212.

M. Gallagher, M. Beard, M.J. Clifford, M.C. Watson, “An evaluation of a biomass stove safety protocol used for testing household cookstoves, in low and middle-income countries,†Energy for Sustainable Development, 2016, vol. 33, pp. 14-25.

Y.S. Pradana, A. Kurniawan, A, and A. Budiman, (2014). “Bio-oil Derived from Indonesian Oil Palm Empty Fruit Bunch (EFB) using Middle-scale Slow Pyrolitic,†in The International Oil Palm Conference, 2014, Bali, Indonesia.

H. Sudibyo, A.I. Majid, Y.S. Pradana, W. Budhijanto, Deendarlianto, and A. Budiman, “ Technological Evaluation of Municipal Solid Waste Management System in Indonesia,†Energy Procedia, 2017, vol. 105, pp. 263-269.

Y.S. Pradana, and A. Prasetya, “Performance evaluation of household pyrolytic stove: Effect of outer air apertures condition,†in AIP Conference Proceedings, 2017, vol. 1823, art. no. 020069.

D.M. Himmelblau, Basic Principles and Calculations in Chemical Engineering, 6th ed., Prentice-Hall International, Inc., 1996.

Y.D. Singh, P. Mahanta, and U. Bora, “Comprehensive characterization of lignocellulosic biomass through proximate, ultimate and compositional analysis for bioenergy production,†Renewable Energy, 2017, vol. 103, pp. 490-500.

K. Li, L. Zhang, L. Zhu, and X. Zhu, “Comparative study on pyrolitic of lignocellulosic and algal biomass using pyrolitic-gas chromatography/mass spectrometry,†Bioresource Technology, 2017, vol. 234, pp. 48-52.