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2019 | OriginalPaper | Buchkapitel

4. Green Gaseous Fuel Technology

verfasst von : Basanta Kumara Behera, Ajit Varma

Erschienen in: Bioenergy for Sustainability and Security

Verlag: Springer International Publishing

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Abstract

The concept of biogas production by anaerobic digestion (AD) and its subsequent conversion into electricity in combined heat and power (CHP) plants or feeding as biomethane into the gas networks is an essential contribution to utilizing biowastes from households, communities and agriculture, on the one hand, and the purposeful production of CO₂-neutral energy from regenerative raw materials (Fig. 4.1) on the other.

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Vorheriges Kapitel Diesel-Like Biofuels

Nächstes Kapitel Bioelectricity Generation

McCabe, J and Eckenfelder, W (eds.) (1957). Biological Treatment of Sewage and Industrial Wastes. Two volumes. New York: Reinbold Publishing.

Buswell, AM and Hatfield, WD (1936). Bulletin 32, Anaerobic Fermentations. Urbana, IL: State of Illinois Department of Registration and Education.

Sanders, WTM et al (2000). Anaerobic hydrolysis kinetics of particulate substrates. Water Science and Technology, 41(3): 17–24.CrossRef

Mata-Alvarez, J (2003). Fundamentals of the anaerobic digestion process. In: Mata-Alvarez, J. (ed.), Biomethanization of the Organic Fraction of Municipal Solid Waste. IWA Publishing, UK.

Pavlostathis, SG and Giraldo-Gomez, E (1991). Kinetics of anaerobic treatment: A critical review. Critical Reviews in Environmental Control, 21(5,6): 411–490.CrossRef

Gerardi, MH (ed.) (2003). The Microbiology of Anaerobic Digesters. Wiley Publishers.

Fayyaz Ali Shah et al. (2014). Microbial Ecology of Anaerobic Digesters: The Key Players of Anaerobiosis. Scientific World Journal, 183752.

Reinhold, F and Noak, W (1956). Laboratoriumsver-suche uber die Gasgewinnung aus landwirtschaftlichen Stoffen. In: Liebmann, H (ed.), Gewinnung und Verwertung von Methan aus Klärschlamm und Mist., R. Oldenbourg, Munchen, Germany.

Stewart, DJ et al (1984). Biogas production from crops and organic wastes. Results of continuous digestion tests. New Zealand J. Sci., 27: 285–294.

10.

Weiland, P (2008). Impact of competition claims for food and energy on German biogas production. Paper presented at the IEA Bio-energy Seminar, Ludlow, UK, April 17th, 2008 and Fachagentur für Nachwachsende Rohstoffe (FNR), Hofplatz 1, D-18276 Gülzow (ed.), ISBN 978-3-939371-46-5.

11.

MNES Report (2001). Renewable Energy in India and business opportunities. Govt of India, New Delhi.

12.

Nirmala, B and Gaur, AC (1997). Effects of carbon and nitrogen ratio on rice straw biomethanation. Journal of Rural Energy, 11: 1–16.

13.

Singh, JB and Anil, D (1988). Manual on Deenbandhu Biogas plant. New Delhi: Tata McGraw Hill Publishing.

14.

Allan Elliott and Talat Mahmood (2007). Pretreatment technologies for advancing anaerobic digestion of pulp and paper biotreatment residues. Water Research, 41: 4273–4286.CrossRef

15.

Erden, G and Filibeli, A (2009). Ultrasonic pre-treatment of biological sludge: Consequences for disintegration, anaerobic biodegradability, and filterability. J. Chem. Technol. Biotechnol., 85(1): 145–150.CrossRef

16.

Haug, RT et al (1978). Effect of thermal pretreatment on digestibility and dewaterability of organic sludges. J. Water Pol. Control Fed., 73–85.

17.

Kim, J et al (2003). Effects of various pretreatments for enhanced anaerobic digestion with waste activated sludge. J. Biosci. Bioeng., 95(3): 271–275.CrossRef

18.

Neyens, E and Baeyens, J (2002). A review of thermal sludge pretreatment processes to improve dewaterability. Journal of Hazardous Materials, B98: 51–67.CrossRef

19.

Penaud, V et al (1999). Thermo-chemical pretreatment of a microbial biomass: Influence of sodium hydroxide addition on solubilization and anaerobic biodegradability. Enz Microbial Tech, 25: 258–263.CrossRef

20.

Saktaywin, W et al (2005). Advanced sewage treatment process with excess sludge reduction and phosphorus recovery. Water Res., 39: 902–910.CrossRef

21.

Tanaka, S et al (1997). Effects of thermo-chemical pre-treatment on the anaerobic digestion of waste activated sludge. Wat Sci Tech, 35: 209–215.CrossRef

22.

Tiehm, A et al (1997). The use of ultrasound to accelerate the anaerobic digestion of sewage sludge. Water Sci. Technol., 36: 121–128.CrossRef

23.

Wang, Q et al (1999). Upgrading of anaerobic digestion of waste activated sludge by ultrasonic pre-treatment. Bioresour. Technol., 68: 309–313.CrossRef

24.

Weemaes et al (2000). Anaerobic digestion of ozonized biosolids. Water Research, 34(8): 2330–2336.CrossRef

25.

Yeom, IT (2002). Effects of ozone treatment on the biodegradability of sludge from municipal wastewater treatment plants. Water Science and Technology, 46(4–5): 421–425.CrossRef

26.

https://www.oxfordenergy.org Stern (2017). The Future of Gas in Decarbonising European Energy Markets.

27.

https://www.eba.europa.euEBA (2016). Statistical report.

28.

https://www.oxfordenergy.org (2017). Biogas: A significant contribution to decarbonising gas markets.

29.

www.ec.europa.eu/eurostat/.../Electricity_production,_consumption_and_market_overview Eurostat website (Electricity production, consumption and market overview).

30.

European-biogas.eu/events/all-events/eba-workshop EBA Workshop (2017). Contribution of biogas towards European renewable energy policy beyond 2020.

31.

Kuczyńska, I and Pomykała, R (2012). Biogaz z odpadów paliwem dla transportu? bariery i perspektywy, Energetyka gazowa, 4: 34–39.

32.

Niemiec. Możliwości wdrożenia technologii w Polsce (2011). www.cire. pl,14.12.2012

33.

Smerkowska, B (2012). Ekonomiczne aspekty wytwarzania biogazu w celu wprowadzenia do sieci gazowej, Info Day projektu GreenGasGrids, 24 kwietnia.

34.

Fuksa, D et al (2012). Pozytywne aspekty wykorzystania biogazuna przykładzie transportu, Materiały konferencyjne IZIP? Zakopane, 475–485.

35.

Ryckebosch, E et al (2011). Techniques for transformation of biogas to biomethane. Biomass and Bioenergy, 35(5): 1633–1645.CrossRef

36.

Lachwacka, ME (2009). Technologie uszlachetniania biogazu do jakości gazu ziemnego. Czysta Energia, 12: 26–27.

37.

Mroczkowski, P and Seiffert, M (2011). Oczyszczanie i zatłaczanie biogazu na przykładzie.

38.

Dyrektywa, Rady (1999). WE z dnia 26 kwietnia, r.w sprawie składowania odpadów.

39.

https://books.google.co.in/books (2007). Steve Gagnon, It’s Elemental: Hydrogen. Jefferson Lab.

40.

Levin, DB et al (2004). Biohydrogen production: Prospects and limitations to practical application. Int J Hydrogen Ener, 29: 173–185.CrossRef

41.

Ley, AC and Mauzerall, DC (1982). Absolute absorption cross sections for photosystem II and the minimum quantum requirement for photosynthesis in Chlorella vulgaris. Biochim Biophys Acta, 680: 95–106.CrossRef

42.

Greenbaum, E (1988). Energetic efficiency of hydrogen photoevolution by algal water-splitting. Biophys J, 54: 365–368.CrossRef

43.

Hallenbeck, PC and Benemann, JR (2002). Biological hydrogen production: Fundamentals and limiting processes. Int J Hydrogen Energy, 27: 1185–1193.CrossRef

44.

Smith, G et al (1992). Hydrogen production by Cyanobacteria. International Journal of Hydrogen Energy, 17(9): 695–698.CrossRef

45.

Kitashima, M et al (2012). Flexible Plastic Bioreactors for Photobiological Hydrogen Production by Hydrogenase-Deficient Cyanobacteria. Biosci. Biochem. Biotechnol., 76: 831–833.CrossRef

46.

Lindblad, P et al (2002). Photoproduction of H₂ by wildtype Anabaena PCC 7120 and a hydrogen uptake deficient mutant: From laboratory experiments to outdoor culture. International Journal of Hydrogen Energy, 27: 1271–1281.CrossRef

47.

Howarth, DC and Codd, GA (1985). The uptake and production of molecular hydrogen by unicellular cyanobacteria. Journal of General Microbiology, 131: 1561–1569.

48.

Weissman, JC and Benemann, JR (1977). Hydrogen production by nitrogen-starved cultures of Anabaena cylindrica. Applied and Environmental Microbiology, 33: 123–131.

49.

Sveshnikov, DA et al (1997). Hydrogen metabolism of mutant forms of Anabaena variabilis in continuous cultures and under nutritional stress. FEMS Microbiology Letters, 147: 297–301.CrossRef

50.

Borodin, VB et al (2000). Hydrogen production by Anabaena variabilis PK84 under simulated outdoor conditions. Biotechnology and Bioengineering, 69: 478–485.CrossRef

51.

Kosourov, S et al (2002). Effects of extracellular pH on the metabolic pathways in sulfur-deprived, H₂-producing Chlamydomonas reinhardtii cultures. Biotechnology and Bioengineering, 78: 731–740.CrossRef

52.

Guan, YF et al (2004). Two-stage photobiological production of hydrogen by marine green algae Platymonas subcordifermis. Biochemical Engineering Journal, 19: 69–73.CrossRef

53.

Laurinavichene, TV et al (2006). Demonstration of sustained hydrogen photoproduction by immobilized, sulfur-deprived Chlamydomonas reinhardtii cells. International Journal of Hydrogen Energy, 31: 659–667.CrossRef

54.

John Benemann (1996). Hydrogen biotechnology: Progress and prospects. Journal Nature Biotechnology, 14: 1101–1103.CrossRef

55.

Belafi-Bako, K et al (2002). Enzymatic biodiesel production from sunflower oil by Candida Antarctica lipase in a solvent-free system. Biocatalysis and Biotransformation, 20: 437–439.CrossRef

56.

Masukawa, H et al (2002). Disruption of the uptake hydrogenase gene, but not the bidirectional hydrogenase gene, leads to enhanced photobiological hydrogen production by the nitrogen-fixing cyanobacterium Anabaena sp. PCC 7120. Appl Microbiol Biotechnol, 58: 618–624.CrossRef

57.

Pinto, F et al (2002). A brief look at three decades of research on cyanobacterial hydrogen evolution. Int J Hydrogen Energy, 27: 1209–1215.CrossRef

58.

Gfeller, RP and Gibbs, M (1985). Fermentative Metabolism of Chlamydomonas reinhardtii: II. Role of Plastoquin. Plant Physiol., 77: 509–511.CrossRef

59.

Ohta, SK, Miyamoto and Miura, Y (1987) Hydrogen evolution as a consumption mode of reducing equivalent in green algae fermentation. Plant Physiology, 83: 1022–1026.CrossRef

60.

Miura, Y et al (1997). Stably sustained hydrogen production by biophotolysis in natural day/night cycle. Energy Conv Manag, 38: S533-S537.CrossRef

61.

Basak, N and Das, D (2007). The prospect of purple non-sulfur (PNS) photosynthetic bacteria for hydrogen production: The present state-of-the-art. World J. Microbiol. Biotechnol., 23: 31–42.CrossRef

62.

Redwood, MD (2009). Integrating dark and light bio-hydrogen production strategies: Towards the hydrogen economy. Rev. Environ. Sci. Biotechnol., 8: 149–185.CrossRef

63.

Holladay, JD et al (2009). An overview of hydrogen production technologies. Catal. Today, 139: 244–260.CrossRef

64.

Kapdan, IK et al (2009). Bio-hydrogen production from acid hydrolyzed wheat starch by photo-fermentation using different Rhodobacter sp. Int. J. Hydrog. Energy, 34: 2201–2207.CrossRef

65.

Keskin, T and Hallenbeck, PC (2012). Hydrogen production from sugar industry wastes using single-stage photofermentation. Bioresour. Technol., 112: 131–136.CrossRef

66.

Guo, XM et al (2010). Hydrogen production from agricultural waste by dark fermentation: A review. International Journal of Hydrogen Energy, 35: 10660–10673.CrossRef

67.

Zhao, X et al (2012). The effects of metal ions and L-cysteine on hydA gene expression and hydrogen production by Clostridium beijerinckii RZF-1108. International Journal of Hydrogen Energy, 37: 13711–13717.CrossRef

68.

Wolfrum, EJ and Maness, P (2003). Biological Water Gas Shift. U.S. DOE Hydrogen, Fuel Cell and Infrastructure Technologies Program Review; May 19–22, Berkeley, California.

69.

Akkerman, I et al (2002). Photobiological hydrogen production: Photochemical efficiency and bioreactor design. International Journal of Hydrogen Energy, 27: 1195–1208.CrossRef

70.

Greenbaum, E (1984). Biophotolysis of water: The light saturation curves. Photobiochemistry and Photobiophysics, 8: 323–332.

71.

Polle, JEW et al (2002). Truncated chlorophyll antenna size of the photosystems—A practical method to improve microalgal productivity and hydrogen production in mass culture. International Journal of Hydrogen Energy 27(11): 1257–1264.CrossRef

72.

Quigg, A et al (2006). Limitations on microalgal growth at very low photon flux densities: The role of energy slippage and H⁺ leakage. Photosynthesis Research, 88: 299–310.CrossRef

73.

www.roads2hy.com (2009). (Roads2HyCom D4.3 – Well-to-Tank Technology Pathways – S3.

74.