This paper aims at developing the potential of cellulose-based energy generation using pyrolysis, gasification, and combustion methods with biodegradable waste media. The cellulose-based material used in this study was sawdust. The sawdust was heated using a biomass stove, which was then analyzed in terms of heat conduction and propagation as well as temperature distribution. To ensure the effectiveness of sawdust as the main material in the biomass stove, sawdust particles were pressed and compacted under various pressure conditions. This experiment was integrated with the Project-Based Learning method through the following steps: (1) determination of projects testing, (2) project design, (3) project implementation schedules, (4) project completion and progress monitoring, (5) reports and presentations of project results, and (6) project evaluation. The results provide new findings that the denser sawdust particles correlate with the greater temperature and propagation rate. This can be obtained from the measured temperature distribution. Areas close to the heat source tend to have the same heat propagation. The density of the sawdust particle is the main key point for producing better pyrolysis and gasification process, in which it correlates with long combustion energy. Integrasi This finding opens a new concept and can be used as a reference for other researchers who develop research related to renewable energy from waste, especially when using a biomass stove.  This study also gives ideas for the need for developing project-based learning using the burning of sawdust using biomass stove as a tool for the teaching and learning process.

Biodegradable waste; Biomass Stove; Conduction; Project-Based Learning; Sawdust

Adler-Beléndez, D., Hoppenstedt, E., Husain, M., Chng, E., and Schneider, B. (2020). How are 21st century skills captured in makerspaces?: A review of the literature. ACM International Conference Proceeding Series, 2020, 40–45.

Ahtee, T., and Poranen, T. (2009). Risks in students’ software projects. Proceedings - 22nd Conference on Software Engineering Education and Training, 2009, 154–157.

Bahri, S., Venezia, A. M., and Upadhyayula, S. (2019). Utilization of greenhouse gas carbon dioxide for cleaner Fischer-Tropsch diesel production. Journal of Cleaner Production, 228, 1013–1024.

Berman, E. T., Hamidah, I., Mulyanti, B., and Setiawan, A. (2021). Low cost and portable laboratory kit for teaching and learning of air conditioning process in vocational education. Journal of Technical Education and Training, 13(3), 133–145.

Chua, K. J., and Islam, M. R. (2021). The hybrid project-based learning–flipped classroom: A design project module redesigned to foster learning and engagement. International Journal of Mechanical Engineering Education, 49(4), 289–315.

Damayanthi, L. P. E., Sugihartini, N., Damasanti, I. A. R., and Ryantini, K. T. D. (2021). Identifying students’ learning difficulties in human and computer interaction course through the implementation of Project-based learning model. Journal of Physics: Conference Series, 1810(1), 012068.

Demirbas, A. (2011). Waste management, waste resource facilities and waste conversion processes. Energy Conversion and Management, 52(2), 1280–1287.

El-Shafay, A. S., Hegazi, A. A., Zeidan, E. S. B., El-Emam, S. H., and Okasha, F. M. (2020). Experimental and numerical study of sawdust air-gasification. Alexandria Engineering Journal, 59(5), 3665–3679.

Guo, P., Saab, N., Post, L. S., and Admiraal, W. (2020). A review of project-based learning in higher education: Student outcomes and measures. International Journal of Educational Research, 102, 101586.

Hu, M., Gao, L., Chen, Z., Ma, C., Zhou, Y., Chen, J., Ma, S., Laghari, M., Xiao, B., Zhang, B., and Guo, D. (2016). Syngas production by catalytic in-situ steam co-gasification of wet sewage sludge and pine sawdust. Energy Conversion and Management, 111, 409–416.

Kan, R., Kaosol, T., and Tekasakul, P. (2013). Characterization and elemental composition of lignite and rubber wood sawdust pellets. KKU Engineering Journal, 40, 131–138.

Kazmi, M. Z. H., Karmakar, A., Michaelis, V. K., and Williams, F. J. (2019). Separation of cellulose/hemicellulose from lignin in white pine sawdust using boron trihalide reagents. Tetrahedron, 75(11), 1465–1470.

Linder, S. P., Abbott, D., and Fromberger, M. J. (2006). An instructional scaffolding approach to teaching software design. Journal of Computing Sciences in Colleges, 21(6), 238–250.

MacLean, J. D. (1941). Thermal conductivity of wood. Heating, Piping and Air Conditioning, 13(6), 380–391.

Mason, P. E., Darvell, L. I., Jones, J. M., and Williams, A. (2016). Comparative study of the thermal conductivity of solid biomass fuels. Energy and Fuels, 30(3), 2158–2163.

Mujiyono, Nurhadiyanto, D., Pratiwi, H., Pratama, G. D., Priyono, P., Kassyaf, K. M., and Fauzi, F. H. (2020). Experimental study on integrated biomass pyrolysis and gasification process from teak wood waste: Preliminary. Journal of Physics: Conference Series, 1700(1), 012005.

Muzana, S. R., Jumadi, Wilujeng, I., Yanto, B. E., and Mustamin, A. A. (2021). E-STEM project-based learning in teaching science to increase ICT literacy and problem solving. International Journal of Evaluation and Research in Education, 10(4), 1386–1394.

Owusu, F., Kuranchie, F. A., Odonkor, S., Frimpong, K., and Muri, M. (2020). Biomass Stove for Pelletized Sawdust Fuel in Ghana. Combustion Science and Technology, 192(9), 1719–1730.

Pipatjumroenkul, Y., Siripattanakul, S., and Sompong, N. (2019). Development of using model on project-based blended E-learning courseware for teacher’s ICT skills in 21st century in the central region of Thailand. ACM International Conference Proceeding Series, 2019, 103–107.

Sabura Banu, U. (2020). Technical skill upgradation by Project-based learning and exposing to state-of-art technologies. Procedia Computer Science, 172, 950–953.

Sepe, A. M., Li, J., and Paul, M. C. (2016). Assessing biomass steam gasification technologies using a multi-purpose model. Energy Conversion and Management, 129, 216–226.

Silva, J., Ferreira, A. C., Teixeira, S., Martins, L., Ferreira, E., and Teixeira, J. C. (2021). Sawdust drying process in a large-scale pellets facility: An energy and exergy analysis. Cleaner Environmental Systems, 2, 100037.

Subagyono, R. R. D. J. N., Qi, Y., Chaffee, A. L., Amirta, R., and Marshall, M. (2021). Pyrolysis-gc/ms analysis of fast growing wood macaranga species. Indonesian Journal of Science and Technology, 6(1), 141–158.

Vasubsbu, M., Nagaraju, B., Kumar, J. V., and Kumar, R. J. (2015). Experimental measurement of thermal conductivity of wood species in india: effect of density and porosity. International Journal of Science, Environment and Technology, 4(5), 1360–1364.

Wang, Z., Duanmu, L., Yuan, P., Ning, M., and Liu, Y. (2015). Experimental study of thermal performance comparison based on the traditional and multifunctional biomass stoves in China. Procedia Engineering, 121, 845–853.

Yang, S. W., Yi, J. M., Qiu, K. Q., Deng, X., and Chen, J. S. (2012). Dynamic study on vacuum pyrolysis reaction of Chinese fir sawdust biomass. Advanced Materials Research, 512–515, 375–378.

Young, J., Spichkova, M., and Simic, M. (2021). Project-based learning within eHealth, bioengineering and biomedical engineering application areas. Procedia Computer Science, 192, 4952–4961.

Younis, A. A., Sunderraman, R., Metzler, M., and Bourgeois, A. G. (2021). Developing parallel programming and soft skills: A Project-based learning approach. Journal of Parallel and Distributed Computing, 158, 151–163.