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Research article

Vol 6 No 2 (2012): Volume 6, Number 2, 2012

Studi tekno-ekonomi pemurnian biogas dari limbah domestik

DOI
https://doi.org/10.22146/jrekpros.4695
Submitted
November 14, 2023
Published
December 31, 2012

Abstract

Biogas purification can increase the caloric value of combustion and prevent corrosion. Biogas with 95% of methane is similar to pipeline quality natural gas. The objective of this research was to study technical and economical feasibility of biogas purification and also to estimate gas production cost and scale up capacities.
This research used the secondary data from pilot plant of Biogas of Pasar Induk Buah dan Sayuran Gemah Ripah, Gamping, Sleman, Yogyakarta. This research was to obtain the production cost and scale up capacities for each biogas purification method. The sensitivity analysis was conducted to study the influence of gas composition ranged at 30-70% CH4 toward the flow of absorbent to gas ratio, the price of waste changed from decreasing 100% up to increasing 100% and the finance changed ranged at 0-15% to the change of production cost.
The result showed that water scrubber was the cheapest method for scrubbing impurities. The production cost of scale up capacities compared to the price of pipeline quality natural gas which ranged at 6-10 US$/MMBtu. The minimum capacity of economical biogas purification methods was 100 tons waste/day. The influence of gas composition ranged at 30-70% of CH4 produced the L/G value change in the absorber column ranged at 0,005-0,025; the influence of waste price from decreasing and up to increasing 100% and finances from 0-15% produced the production cost change ranged at 3-8 US$/MMBtu and 2-14 US$/MMBtu respectively.

References

  1. Cahyari K, and Putra, R. A., 2010, Design of Biogas Plant From Fruit Market Waste in Indonesia
  2. Cavenati, S.; Grande, C.A.; Rodrigues, A.E, 2004, Adsorption Equilibrium of Methane,Carbon Dioxide and Nitrogen on Zeolite 13X at High Pressures. J. Chem. Eng. Data, Vol. 49, No. 4, (June 2004), pp 1095-1101, ISSN 0021- 9568.
  3. Deublein D., and Steinhauser A., 2008, Biogas From Waste and Renewable Resources an Introduction. Weinheim : WILEY-VCH Verlag Gmbh Co. KGaA
  4. Graaf D., dan Fendler R., 2010, Biogas Production in Germany. Federal Environment Agency. DessauRosslau, p 29
  5. Jönsson O, 2004, Biogas Upgrading dan Use as Transportation Fuel, Swedish gas Centre, Malmoe, Sweden
  6. Mahomed, 2010, Design and Development Software Tool For Techno Economic Assessment.
  7. Peters, M.S., Timmerhaus, K.D., and West, R.E., 2003, Plant Design and Economics for Chemical Engineering, 5 ed., McGraw-Hill Companies, Inc., New York.
  8. Rousta K, 2008, Municipality Solid Waste Management : An Evaluation on the Boras System, University College of Boras, Sweden
  9. Ryckebosch E., Drouillon M., dan Vervaeren H., 2011. Techniques For Transformation Biogas To Biomethane, Biomass and Bioenergy Journal, Belgium
  10. Syamsiah S dkk, 2011, Final Report Demostration Project Biogas from fruit wastes in Indonesia
  11. Turton, R., Bailie, R.C., Whiting, W.B., Shaeiwitz, J.A. 2003. Analysis, synthesis, and design of chemical processes. 2nd ed. Prentice Hall PTR, Upper Saddle River, New Jersey.
  12. Wellinger, A., Lindberg, A., 2001, Biogas Upgrading and Utilisation, IEA Bioenergy
  13. www.alibaba.com tanggal akses 15 April 2012
  14. www.matche.com tanggal akses 15 April 2012
  15. www.indexmundi.com tanggal akses 12 Desember 2012