The effect of secondary hole variation on the performance of concentric cylinder top-lit up draft gasifier (TLUD) stove
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Abstract
The Bagasse is one of the fuels that can be used as biomass fuel in micro-gasification because the fuel is abundant. Bagasse is a by-product of the sugar industry which can be used as a biomass fuel for micro-gasification in Indonesia because of its abundance. Gasification is a process of converting biomass fuel into syngas fuel that occurs in the gasifier. This research was conducted to determine the effect of secondary orifice variations on the TLUD Concentric Cylinder Type gasification stove on flame length, flame temperature, fuel efflux rate and thermal efficiency with secondary orifice variations; 30, 40, and 50. The test was carried out using the water boiling test method. The results showed that the stove with 50 secondary holes produced the highest flame temperature at T2 (the temperature at the top of the TLUD stove gasifier) of 653.3 °C, the best flame duration was 14.15 minute, the highest burning rate was 0.88 gr/s. The highest thermal efficiency value was achieved by a stove with a secondary 50 exhaust hole of 67%. Based on the tests, it shows that the variation of the furnace hole affects the flame temperature, flame duration, combustion rate and thermal efficiency.
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References
Directorate General of Oil and Gas. Oil and Gas Statistics Oil and Gas Statistics. Jakarta: Ministry of Energy and Mineral Resources, 2020. https://migas.esdm.go.id/uploads/uploads/Statistik-progress(2).pdf (Accessed 21.09.2022).
Parinduri, Luthfi., Parinduri, Taufiq.. Conversion of Biomass as a Renewable Energy Source. Journal of Electrical Technology. 5(2):88-92, 2020. https://jurnal.uisu.ac.id/index.php/jet/article/view/2885/1918 (Accessed 17.08.2022)
Ministry of Agriculture , Sugarcane Production by Province in Indonesia 2017-2021, 2021. https://www.pertanian.go.id. (Accessed 10.07.2022)
Styana, U. I. F., R. Indrawati, and M. S. Cahyono.. Characterization of Organic Waste Gasification Processes with Various Types of Materials. Journal Engine 3(1): 29-38, 2019. http://dx.doi.org/10.30588/jeemm.v3i1.495
Shayan E., V. Dan I. Mirzaee. Hydrogen production from biomass gasification; a theoretical comparison of using different gasification agents, Energy Convers. Manag Vol. 159:30–41,2018. https://doi.org/10.1016/j.enconman.2017.12.096
Ridwan, A. and B. Palace. Analysis of the Effect of Variations in Biomass Fuel on Flammability and Tar Content in Updraft Type Gasification Reactors. Engine Journal 2(1): 7-17, 2018. http://dx.doi.org/10.30588/jeemm.v2i1
Burhantoro, J.. Effect of Air Distributor on Updraft Gasification Furnace. Thesis. Surakarta: Undergraduate Program, Faculty of Engineering, MuhammadiyahUniversity,2016. https://eprints.ums.ac.id/53300/11/NASKAH%20PUBLIKASI%20-libraryums-jokor.pdf (Accessed 10.07.2022)
. Endang Suhendi, Gilang Umar Paradise, Idham Priandana, Effect of Air Flow Rate and Time of Gasification Process on Gas Producer of Tobacco Leaf Stem Waste Using Downdraft Type Gasifier, Journal of Renewable Natural Materials, vol (2), pp 45-53,2016.
https://doi.org/10.15294/jbat.v5i2
Anderson, P. S., T. B. Reed, and P. W. Wever, Micro-gasification: What it is and Why it Works. Boiling points 53(3): 35-37, 2007.
https://www.drtlud.com/wp-content/uploads/2012/08/BP53-Anderson-14.pdf (Accessed 17.06.2022)
Saputro, A. Burner Design with Variation in the Number of Secondary Airflow Holes 11, 13, 15,17 and Hole Diameters of 5mm, 10mm, 15 mm in Gasification Furnaces. Thesis. Surakarta: Muhammadiyah University of Surakarta), 2017. https://eprints.ums.ac.id/51348/15/Halaman%20Depan.pdf (Accessed 17.06.2022)
Pambudi, P., S. Widodo, and K. Suharno. The Effect of Variation in the Number of Air Holes on the Efficiency of Biomass Stoves. Mer-c Journal, 1(2): E-ISSN 2622-5735), 2019.
https://jom.untidar.ac.id/index.php/merc/article/view/468/pdf. (Accessed 18.06.2022)
Anggara, R., Kelvin, and R. Fauzi.. The Influence of the Number of Air Holes in the Combustion Furnace and Variations in Air Flow Speed on the Performance of Gasification Stoves with Teak Wood Pellet Fuel. eProceedings of Engineering, 6(2). 2019.
https://openlibrarypublications.telkomuniversity.ac.id/index.php/engineering/article/view/9705. . (Accessed 20.06.2022)
Sunarya, R., Zulfansyah, and S. Helianti. Performance of PP-Plus Gasification Stove Fueled by Processed Wood Waste. Indonesian Chemical Engineering National Seminar and APTEKINDO National Conference. September 20-24, 2012.
http://dx.doi.org/10.13140/RG.2.1.2019.4722.
Digdo Listyadi Setyawan, Nasrul Ilminnafik, Hary Sutjahjono, Intan Hardiatama, Allisa Salwasana, The Effect Of Chimney Height On Stove On The Performance Of Top Lit Up Draft Gasification Stove [TLUD], Gongcheng Kexue Yu Jishu/Advanced Engineering Science , Volume - 54, Issue – 07, p 2623 – 2622, 2022.
https://www.gkyj-aes-20963246.com/article/the-effect-of-chimney-height-on-stove-on-the-performance-of-top-lit-up-draft-gasification-stove-tlud. (Accessed 10.09.2022)
Muhammad Fajar Aryansyah, Hadi Santoso, Muh. Firdan Nurdin, Thermal Efficiency Analysis of Biomass Stoves Using the Water Boiling Test (WBT), Journal Bearings: Borneo Mechanical Engineering and Science P-Issn: 2964-1462 Vol 01, No. 01. PP 1-8, 2022.
http://jurnal.borneo.ac.id/index.php/bearings/article/view/2989/1942 (Accessed 20.12.2022)
BSN: National Standard for Biomass Stove Performance (SNI 7926:2013). BSNI, 2013. https://cleancooking.org/binary-data/DOCUMENT/file/000/000/14-1.pdf (Accessed 12.07.2022)
Saravanakumar, A., Haridasan, M., Reed, T.B. and Bai, R.K., Experimental investigation and modeling study of long stick wood gasification in a top lit updraft fixed bed gasifier. Fuel 2007; 17-18 (86): pp 2846-2856 , 2007; https://doi.org/10.1016/j.fuel.2007.03.028
Tryner, J., Tillotson, J. W., Baumgardner, M. E., Mohr, J. T., DeFoort, M. W., & Marchese, A. J. ,The Effects of Air Flow Rates, Secondary Air Inlet Geometry, Fuel Type, and Operating Mode on the Performance of Gasifier Cookstoves. Environmental Science & technology, acs. est.6b00440, 2016. https://doi.org/10.1021/acs.est.6b00440
MIT D-Lab, Handbook for Biomass Cookstove Research, Design, and Development A Practical Guide, Global Alliance for Clean Cookstoves TO Implementing Recent Advances. July 25, 2017.
https://cleancooking.org/binary-data/RESOURCE/file/000/000/517-1.pdf. (Accessed 12.06.2022)
Prayogi, Dimas Pondra. Performance of the Tlud Type Gasification Stove with Various Combustion Chambers Using Sugarcane Bagasse Waste Fuel. Thesis. Jember: Faculty of Engineering, University of Jember, 2023.
https://repository.unej.ac.id/xmlui/handle/123456789/117515 ( Accessed 12.07.2022)
Prasetiani, Chartika Fadilah, The Effect of Biomass Type and Air Flow Speed on the Performance of Biomass Gasification Stoves. E-Proceeding of Engineering. 6(2):5217-5224, 2019. https://openlibrarypublications.telkomuniversity.ac.id/index.php/engineering/article/view/9701. ( Accessed 15.07.2022)
Damayanti, Y., Lesmono, A.D., & Prihandono, T., Study of the Effect of Temperature on the Viscosity of Cooking Oil as a Material Design. Journal of Learning Physics, 7(3), pp 307–314. 2018. https://doi.org/10.19184/jpf.v7i3.8606
Mufid, F. and S. Anis, The Effect of Types of Size of Biomass on the Gasification Process Using a Downdraft Gasifier. Mechanical Engineering Journal, 10(3): 217-226. 2019. https://doi.org/10.21776/ub.jrm.2019.010.03.2
Yogesh Mehta and Cecilia Richards, Gasification Performance of a Top-Lit Updraft Cook Stove, Energies 2017, 10, 1529, 2017. https://doi.org/10.3390/en10101529
Whitman T, C Nicholson, D Torres, J Lehmann, Climate Change Impact of Biochar Cook Stoves in Western Kenyan Farm Households: System Dynamics Model Analysis. Environ. Sci. Technol. 45 (8):3687-3694, 2011. https://doi.org/10.1021/es103301k
Ioan Pavel , Radu-Iulian Rădoi1, Gabriela Matache, Ana-Maria Carla Popescu, and Ioan Caba, 2019, Experimental research on a hot air generator working on the TLUD principle, E3S Web of Conferences 112, 01006, 2019, https://doi.org/10.1051/e3sconf/201911201006
Don Lotter, Nathan Hunter , Mary Straub and David Msola, 2015, Microgasification cookstoves and pellet fuels from waste biomass: A cost and performance comparison with charcoal and natural gas in Tanzania, Afr. J. Environ. Sci. Technol. Vol. 9(6), pp. 573-583, June 2015, https: //10.5897/AJEST2015.1901
Banun, Nur Indah, Performance Analysis of Top Lit Up Draft (TLUD) Gasification Stoves with Variation of Furnace Holes. Thesis. Jember: Faculty of Engineering, University of Jember. 2022. https://repository.unej.ac.id/handle/123456789/112977. ( Accessed 10.06.2022)
Riaz Ahmad, Yuguang Zhou, Nan Zhao, Adnan Abbas, Gang Li, Raman Perumal, Crispin Pemberton-Pigott, Muhammad Sultan, Renjie Dong, Performa Investigation Of Top Lift Up Draft Gasifier stove Using Different Biomass Feuel, Article in Fresenius Environmental Bulletin , vol 28 no 12, pp 9835-9842, 2019, https://www.researchgate.net/publication/337757499. ( Accessed 10.07.2022)
Patrick Wamalwa, Prof, David Nyaanga, Dr, George Owino, Development of an Experimental Biomass Micro gasifier Cook Stove, IOSR Journal of Mechanical and Civil Engineering (IOSR-JMCE) e- Volume 14, Issue 5 Ver. V (Sep. - Oct. 2017), PP 06-10, 2017. https://10.9790/1684-1405050610 logohttps://www.semanticscholar.org/paper/Development-of-an-Experimental-Biomass-Micro-Cook-Wamalwa-Nyaanga/eef79e623137e7e2ae842d4cd02bdaee6e4e6542 ( Accessed 10.08.2022)