ABSTRAK

Biogas merupakan salah satu sumber energi terbarukan yang murah dan berkategori non-polusi. Kebutuhan untuk memonitor serta mengontrol plant biogas bertambah seiring kebutuhan mengoptimalkan stabilitas proses untuk mendapatkan performansi yang tinggi. Monitoring biogas dapat memberikan gambaran keseluruhan proses pembangkitan biogas dan digunakan untuk memprediksi proses fermentasi yang berlangsung. Selain itu, dapat pula meminimalkan gagalnya proses fermentasi dan menghasilkan biogas secara optimal. Dalam penelitian ini proses monitoring dilakukan pada digester dua tahap berbahan dasar ampas tahu dan difokuskan pada pH dan volume biogas yang dihasilkan menggunakan dfrobot sku Sen0160 dan YF-S201 serta solenoid valve sebagai aktuatornya. Hasil penelitian menunjukkan bahwa set point pH 5.3 pada digester asetogenesis dapat dicapai pada hari ke enam untuk tiga percobaan. Dalam digester metanogenesis nilai pH dapat dijaga pada pH 7 ±0.3. Jumlah volume biogas tertinggi yang dihasilkan sebesar 97.2 L.

Kata kunci: digester dua tahap, fermentasi, asetogenesis, metanogenesis

 

ABSTRACT

Biogas is one of an inexpensive and non-pollution renewable energy source. A requirement for optimization and stabilization of biogas plant affected on the need of monitor and control system in the plant. Biogas monitoring system represents a process in biogas generation and has the ability to predict fermentation. In addition, the system built can be used to control the fermentation process and to minimize the failure of the process. This means the process will produce biogas optimally. In this research, the monitoring system was used on two stages digester using tofu as raw material. pH and biogas volume produced are two focuses in this study using SKU Sen0160 dan YF-S201 as sensors and solenoid valve as an actuator. For three experiments data show, set point for pH (5.3) is achieved at day sixth for acetogenesis digester. For methanogenesis, pH can be maintained at 7 ±0.3. The highest volume of biogas produced was 97.2 L.

Keywords: two stages digester, fermentation, acetogenesis, methanogenesis digester

Ahmed, W. A., Aggour, M., & Bennani, F. (2015). Smart System for Bio Digester Monitoring. 3rd International Renewable and Sustainable Energy Conference (IRSEC), (pp. 1-4)

Angelidaki, I., & Ahring, B. K. (1997). Co-digestion of olive oil mill wastewaters with manure, household waste or sewage sludge. Biodegradation, 8, 6.

Batstone, D. J., Keller, J., & Blackall, L. L. (2004). The influence of substrate kinetics on the microbial community structure in granular anaerobic biomass. Water Research, 38, 15.

Boe, K. (2006). Online monitoring and Control of the Biogas Process: Lyngby. Technical University of Denmark.

Dedgaonkar, S., Mohire, A., Jadhav, A., Pawar, S., & Bane, R. (2016). Biogas Monitoring System for Measuring Volume using Micro-controller & GSM. International Journal of Current Engineering and Technology, 6(5), 1553 -1557.

Demirtas, M., Sefa, I., Irmak, E., & Colak, I. (2008). Low-Cost and High Sensitive Microcontroller Based Data Acquisition System for Renewable Energy Sources. Paper presented at the International Symposium on Power Electronics, Electrical Drives, Automation and Motion.

Iriani, Purwinda., Utami, Sri., dan Y. Suprianti. (2018). Biomethanation of Tofu Liquid Waste Using Two-stage Anaerobic Fermentation System. American Institute of Physics (AIP) Conference Proceedings. 2021, 020005-1 - 020005-7

Juangga, A. (2007). Biogas untuk Masa Depan Pengganti BBM. Jurnal Ilmiah, 4 : 25.

Karoly, R., & Dumitru, C. D. (2014). The Monitoring and Control Processes of a Renewable Energy Management System. Paper presented at the 8th International Conference Interdisciplinarity in Engineering, Romania.

Labatut, A. R. (2009). The Effect pH on Digester Multi Stage. Cambriddge university.

Maheshwari, O., Ramesh, S. M., Arasi, M. M., & Priya, C. L. (2014). Wind Turbine Measurement System Using Microcontroller As Data Acquisition. International Journal of Advanced Research in Electronics and Communication Engineering (IJARECE), 3(10), 2.

Muljatiningrum, & Sukmana, R. (2011). Biogas dari Limbah Ternak. Bandung Penerbit Nuansa.

Soetopo, R. S., Purwati, S., Idiyanti, T., Wardhana, K. A., & Aini, M. N. (2010). Produksi Biogas Sebagai Hasil Pengolahan Limbah Lumpur Industri Kertas dengan Proses Digestasi Anaerobik Dua Tahap. Riset Industri Kemenperin.

Sunil, M., Narayan, A., Bhat, V., & Vinay, S. (2013). Smart Biogas Plant. International Journal of Innovative Technology and Exploring Engineering (IJITEE), 3(3), 62-66.

Switzenbaum, M. S., Giraldo-Gomez, E., & Hickey, R. F. (1990). Monitoring of the anaerobic methane fermentation process. Enzyme and Microbial Technology, 12, 8.

Trisna, A. (2015). Rancang Bangun Teknologi Pemurni Air. Universitas Negeri Jember.

Utami, S., Saodah, S., & Pudin, A. (2018). Penggunaan Algoritma Incremental Conductance pada MPPT dengan Buck Converter untuk Pengujian Indoor dan Outdoor. Elkomika, 6(1), 97- 109.