Rural communities require appropriate technology to process livestock waste that has been polluting the environment, particularly water bodies such as rivers. Biogas technology offers a solution by converting waste into renewable energy, namely biogas, which can be utilized for daily needs and high-quality organic fertilizer production. Unfortunately, the biogas reactors currently in use were developed over 50 years ago without significant innovations. Hence, there is a pressing need for a more efficient (affordable and user-friendly) and effective (in terms of performance) biogas reactor technology suitable for rural communities—specifically, the Fiber Reinforced Plastic (FRP) biogas reactor technology. The objective of this endeavor is to create a household-scale prototype FRP biogas reactor, designed according to specific requirements and standardized for widespread use. This prototype will be implemented and tested in the field, allowing for dissemination to a broader audience. For modeling purposes, the FRP reactor design will be applied in a demonstration plot in Sunten Jaya Village, Lembang Subdistrict, West Bandung Regency. The results from the demonstration plot reveal that the produced biogas amounts to 40 L/kg of cow dung.

Afrian, C. (2017). PRODUKSI BIOGAS DARI CAMPURAN KOTORAN SAPI DENGAN RUMPUT GAJAH (Pennisetum Purpureum) [Universitas Lampung].

Aminah, N., Aksan, Indriati, S., & Rusdi Wartapane. (2023). BIOGAS UNTUK RUMAH TANGGA DI DESA LENGKESE KABUPATEN TAKALAR. J-ABDI: Jurnal Pengabdian kepada Masyarakat, 2(8), 5741–5748.

Backes, J. G., Traverso, M., & Horvath, A. (2022). Environmental assessment of a disruptive innovation: Comparative cradle-to-gate life cycle assessments of carbon-reinforced concrete building component. The International Journal of Life Cycle Assessment, 28(1), Article 1.

Backes, J. G., Traverso, M., & Horvath, A. (2023). Environmental assessment of a disruptive innovation: Comparative cradle-to-gate life cycle assessments of carbon-reinforced concrete building component. The International Journal of Life Cycle Assessment, 28(1), 16–37.

Baiti. (2023). PENGARUH PENAMBAHAN AIR TERHADAP PRODUKSI BIOGAS PADA PRODUK FERMENTASI SAMPAH ORGANIK [Universitas Muhammadiyah Mataram].

Harun, E. H., & Ilham, J. (2023). Analisis Potensi Sampah Organik Pasar Sentral Kota Gorontalo sebagai Bahan Baku Energi Biogas. ELKOMIKA: Jurnal Teknik Energi Elektrik, Teknik Telekomunikasi, & Teknik Elektronika, 11(1), 113.

Islam, Md. I., Maruf, Md. H., Al Mansur, A., Ashique, R. H., Asif ul Haq, M., Shihavuddin, A., & Jadin, M. S. (2023). Feasibility analysis of floating photovoltaic power plant in Bangladesh: A case study in Hatirjheel Lake, Dhaka. 55.

Kusumah, A. A., Wiranto, S., Sarjito, A., Priyanto, Suseto, B., & Prakoso, L. Y. (2023). COLLABORATION ON DAS CITARUM HANDLING THROUGH THE TNI BHAKTI PROGRAM AND LAW ENFORCEMENT IN THE FRAMEWORK OF MILITARY CAMPAIGN STRATEGY. 2(6), 2693–2704.

Marselina, M., Wibowo, F., & Mushfiroh, A. (2022). Water quality index assessment methods for surface water: A case study of the Citarum River in Indonesia. Heliyon, 8(7), Article 7.

Mohammed, A. S., Atnaw, S. M., & Desta, M. (2022). The Biogas Technology Development in Ethiopia: The Status, and the Role of Private Sectors, Academic Institutions, and Research Centers. In S. A. Sulaiman (Ed.), Energy and Environment in the Tropics (pp. 227–243). Springer Nature Singapore.

Parapat, R. Y., Amin, M. A., Rosmayani, R., & Aschuri, I. (2023). Optimization of nanoasphalt rubber using response surface method. AIP Conference Proceedings, 2772(1), 060004.

Parapat, R. Y., Rosa, S. N., Pratiwi, V. D., & Kurniawan, R. (2023). Analisis Ekonomi Pra-Rancangan Pabrik Bio-Oil Dari Tongkol Jagung Menggunakan Proses Pirolisis Cepat. Journal of Comprehensive Science (JCS), 2(3), 764–744.

Parapat, R. Y., Suhartono, J., Aschuri, I., Schwarze, M., & Schomaecker, R. (2020). Plant Design for a Production Process of Nanoasphalt Emulsion from Asbuton Rock. INTERNATIONAL CONFERENCE ON GREEN TECHNOLOGY AND DESIGN (ICGTD), 2020, 67–74.

Rasheed, R., Anwar, I., Tahir, F., Rizwan, A., Javed, H., & Sharif, F. (2023). Techno-economic and environmental sustainability analysis of filament-winding versus pultrusion based glass-fiber composite technologies. Environmental Science and Pollution Research, 30(13), 36276–36293.

Sawale, S. D., & Kulkarni, A. A. (2022). Chapter 20—Current technical advancement in biogas production and Indian status. 501–532. https://doi.org/10.1016/B978-0-323-88427-3.00024-6

Thakur, H., Dhar, A., & Powar, S. (2022). Biogas production from anaerobic co-digestion of sewage sludge and food waste in continuously stirred tank reactor. 16.

You, X., Yan, G., Al-Masoudy, M. M., Kadimallah, M. A., Alkhalifah, T., Alturise, F., & Ali, H. E. (2023). Application of novel hybrid machine learning approach for estimation of ultimate bond strength between ultra-high performance concrete and reinforced bar. 180.

Zulhadi, Pitono, A., & Wargadinata, E. L. (2023). Collaborative Governance Dalam Pengelolaan Kawasan Citarum Harum di Kabupaten Bandung.