Comparative performance of mesophilic and thermophilic anaerobic digestion for high-solid sewage sludge

Bioresource Technology

Volumn 149, Issue , 2013, Pages 177-183

  Hidaka, Taira ^a   Wang, Feng ^a   Togari, Taketo ^b   Uchida, Tsutomu ^a,c   Suzuki, Yutaka ^a  

^a PUBLIC WORKS RESEARCH INSTITUTE   (Japan)

^b Water Environment Policy Division Environment Department Ishikawa Prefectural Government   (Japan)

^c Japan Sewage Works Agency   (Japan)

Author keywords

Ammonia inhibition; Anaerobic digestion; High solid sewage sludge; Small facilities; Thermophilic

Indexed keywords

AMMONIA; METHANE; SEWAGE SLUDGE; SEWAGE TREATMENT PLANTS;

AMMONIA INHIBITION; BIODEGRADABLE ORGANIC MATTER; COMPARATIVE PERFORMANCE; HIGH-SOLIDS; THERMOPHILIC; THERMOPHILIC ANAEROBIC DIGESTION; THERMOPHILIC CONDITIONS; TOTAL SOLIDS CONCENTRATIONS;

ANAEROBIC DIGESTION;

AMMONIA; METHANE; ORGANIC MATTER;

AMMONIA; BIODEGRADATION; CONCENTRATION (COMPOSITION); DIGESTION; INDUSTRIAL PERFORMANCE; SEWAGE TREATMENT; URBAN AREA;

ANAEROBIC DIGESTION; ANAEROBIC REACTOR; ARTICLE; BIODEGRADABILITY; COMPARATIVE STUDY; CONTROLLED STUDY; COST; ENERGY; FERMENTATION; HIGH SOLID SEWAGE SLUDGE; LABORATORY SCALE REACTOR; MESOPHILIC ANAEROBIC DIGESTION; PRIORITY JOURNAL; REDUCTION; SEWAGE TREATMENT PLANT; SLUDGE; SOLID WASTE; THERMOPHILIC ANAEROBIC DIGESTION;

AMMONIA INHIBITION; ANAEROBIC DIGESTION; HIGH-SOLID SEWAGE SLUDGE; SMALL FACILITIES; THERMOPHILIC;

AMMONIA; ANAEROBIOSIS; BATCH CELL CULTURE TECHNIQUES; BIODEGRADATION, ENVIRONMENTAL; BIOLOGICAL OXYGEN DEMAND ANALYSIS; BIOREACTORS; HYDROGEN-ION CONCENTRATION; METHANE; NITROGEN; SEWAGE; TEMPERATURE; VISCOSITY; VOLATILIZATION; WASTE DISPOSAL, FLUID;

EID: 84885082320     PISSN: 09608524     EISSN: 18732976     Source Type: Journal    
DOI: 10.1016/j.biortech.2013.09.033     Document Type: Article

References (25)

1. APHA (American Public Health Association Publication), 1995. Standard Methods for the Examination of Water and Wastewater, 19th ed. Washington, DC, USA.
2. Appels L., Baeyens J., Degrève J., Dewil R. Principles and potential of the anaerobic digestion of waste-activated sludge. Progress in Energy and Combustion Science 2008, 34:755-781.
3. Chen Y., Cheng J.J., Creamer K.S. Inhibition of anaerobic digestion process: a review. Bioresource Technology 2008, 99:4044-4064.
4. Chi Y., Li Y., Fei X., Wang S., Yuan H. Enhancement of thermophilic anaerobic digestion of thickened waste activated sludge by combined microwave and alkaline pretreatment. Journal of Environmental Sciences 2011, 23:1257-1265.
5. Cho S.-K., Im W.-T., Kim D.-H., Kim M.-H., Shin H.-S., Oh S.-E. Dry anaerobic digestion of food waste under mesophilic conditions: performance and methanogenic community analysis. Bioresource Technology 2013, 131C:210-217.
6. Dong B., Liu X., Dai L., Dai X. Changes of heavy metal speciation during high-solid anaerobic digestion of sewage sludge. Bioresource Technology 2012, 131C:152-158.
7. Duan N., Dong B., Wu B., Dai X. Bioresource technology high-solid anaerobic digestion of sewage sludge under mesophilic conditions: feasibility study. Bioresource Technology 2012, 104:150-156.
8. El-Mashad H.M. Kinetics of methane production from the codigestion of switchgrass and Spirulina platensis algae. Bioresource Technology 2013, 132:305-312.
9. Fujishima S., Miyahara T., Noike T. Effect of moisture content on anaerobic digestion of dewatered sludge: ammonia inhibition to carbohydrate removal and methane production. Water Science and Technology 2000, 41:119-127.
10. Guendouz J., Buffière P., Cacho J., Carrère M., Delgenes J.-P. High-solids anaerobic digestion: comparison of three pilot scales. Water Science and Technology 2008, 58:1757-1763.
11. Hidaka T., Uchida T. Comparative survey on characteristics of sewage sludge and its anaerobic digestion performance in sewage treatment plants in Japan. Journal of Japan Society of Civil Engineers, Ser. G (Environmental Research) 2012, 68(7):III_325-III_332. (in Japanese).
12. Hidaka T., Arai S., Okamoto S., Uchida T. Anaerobic co-digestion of sewage sludge with shredded grass from public green spaces. Bioresource Technology 2013, 130:667-672.
13. Hong, F., 2005. Methane gas production characteristics of thermophilic anaerobic digestion for kitchen garbage, Doctoral thesis, Kyoto University, Japan (in Japanese).
14. Ishikawa Prefecture, 2011. Annual report on sewer works in Ishikawa Prefecture for 2010. Ishikawa (in Japanese).
15. JSWA (Japan Sewage Works Association), 2012. Annual report on sewerage system in Japan 67. Tokyo (in Japanese).
16. Koster I.W., Lettinga G. Anaerobic digestion at extreme ammonia concentrations. Biological Wastes 1988, 25:51-59.
17. Nakashimada Y., Ohshima Y., Minami H., Yabu H., Namba Y., Nishio N. Ammonia-methane two-stage anaerobic digestion of dehydrated waste-activated sludge. Applied Microbiology and Biotechnology 2008, 79:1061-1069.
18. Nges I.A., Liu J. Effects of solid retention time on anaerobic digestion of dewatered-sewage sludge in mesophilic and thermophilic conditions. Renewable Energy 2010, 35:2200-2206.
19. Park Y., Hong F., Cheon J., Hidaka T., Tsuno H. Comparison of thermophilic anaerobic digestion characteristics between single-phase and two-phase systems for kitchen garbage treatment. Journal of Bioscience and Bioengineering 2008, 105:48-54.
20. Public Works Research Institute, Ministry of Construction, Japan, 1993. Annual report of wastewater management and water quality control, No.3215. (ISSN 0386-5878) (in Japanese).
21. Public Works Research Institute, Ministry of Construction, Japan, 1997. Annual report of wastewater management and water quality control, No.3528. (ISSN 0386-5878) (in Japanese).
22. Sung S., Liu T. Ammonia inhibition on thermophilic anaerobic digestion. Chemosphere 2003, 53:43-52.
23. Terashima M., Goel R., Komatsu K., Yasui H., Takahashi H., Li Y.Y., Noike T. CFD simulation of mixing in anaerobic digesters. Bioresource Technology 2009, 100:2228-2233.
24. Wang X., Yang G., Feng Y., Ren G., Han X. Optimizing feeding composition and carbon-nitrogen ratios for improved methane yield during anaerobic co-digestion of dairy, chicken manure and wheat straw. Bioresource Technology 2012, 120C:78-83.
25. Zhong W., Chi L., Luo Y., Zhang Z., Zhang Z., Wu W.-M. Enhanced methane production from Taihu Lake blue algae by anaerobic co-digestion with corn straw in continuous feed digesters. Bioresource Technology 2013, 134:264-270.