연구동향 분석

열가수분해와 고액분리 결합공정 적용을 통한 혐기성 소화능 향상 = Enhancement of Anaerobic Digestion using Thermal Hydrolysis and Solid-Liquid Separation Combined Process

이시영 2022년

논문상세정보
인용/피인용
' 열가수분해와 고액분리 결합공정 적용을 통한 혐기성 소화능 향상 = Enhancement of Anaerobic Digestion using Thermal Hydrolysis and Solid-Liquid Separation Combined Process' 의 주제별 논문영향력
논문영향력 선정 방법
논문영향력 요약
주제
  • 고세균
  • 고액분리
  • 메탄생성
  • 바이오가스
  • 박테리아
  • 열가수분해
  • 하수슬러지
  • 혐기성 소화
동일주제 총논문수 논문피인용 총횟수 주제별 논문영향력의 평균
277 0

0.0%

' 열가수분해와 고액분리 결합공정 적용을 통한 혐기성 소화능 향상 = Enhancement of Anaerobic Digestion using Thermal Hydrolysis and Solid-Liquid Separation Combined Process' 의 참고문헌

  • 하수슬러지의 초음파 적용을 통한 혐기성소화 특성 연구
    구자옥 한밭대학교 박사학위논문 [2018]
  • 하수슬러지의 열 가수분해 전처리를 적용한 혼합 혐기성 소화 효율 향상
    이승필 서울시립대학교 박사학위논문 [2021]
  • 하수슬러지의 마이크로웨이브 가열 가스화 및 바이오가스 개질 특성
    임문섭 조선대학교 박사학위논문 [2017]
  • 하수슬러지 재활용을 위한 전처리 공정별 최적의 반응 메 카니즘 규명
    백선재 서울시립대학교 박사학위논문 [2015]
  • 하수도 통계
    환경부 [2015]
  • 하수도 통계
    환경부 [2019]
  • 폐자원을 이용한 하수슬러지의 마이크로파 건조 및 고형 연료화
    김종철 동아대학교 박사학위논문 [2011]
  • 이선주, , 하수슬러지와 한약재 부 산물을 이용한 Bio-drying 적용성 평가
    안정원 오민아 이영진 이재영 한국폐기물자원순환학회 추 계학술연구발표회 논문집, 6-19 [2017]
  • 열가수분해를 이용한 하수슬러지 탈수능 향상 및 가용화 의 최적화
    김희중 성균관대학교 박사학위논문 [2021]
  • 열가수분해 반응온도에 따 른 하수슬러지의 물리 화학적 특성변화
    김호 송형운 이상은 최창식 한성국 한국폐기물자원순환학회지, 29.4, 414-420 [2012]
  • 곰페르츠 모형을 활용한 한국 제약 기업 수명 및 자원 투 입 특성에 대한 연구
    최규진 한양대학교 박사학위논문 [2021]
  • 가축분뇨와 음식물류 폐기물의 통합 바이오가스 시설 최 적 운영 방안
    김완주 한밭대학교 박사학위논문 [2021]
  • `` Purifying an organic hydroperoxide containing stream '' research disclosure
    Hirst , M. Vol.470 No.2 , 769 [2003]
  • Zábranská, J., Dohányos, M., Jenícek, P., and Kutil, J., 2006, “Disintegration of excess activated sludge evluation and experience of full-scale applications”, Water Science & Technology, Vol. 53, 229-236.
    [2006]
  • Zhen, G., Lu, X., Kato, H., Zhao, Y. and Li, Y. Y., 2017, “Overview of pretreatment strategies for enhancing sewage sludge disintegration and subsequent anaerobic digestion: Current advances, full-scale application and future perspectives” Renewable and Sustainable Energy Reviews, 69, 559-577.
    [2017]
  • Zhang, J., Xue, Y., Eshtiaghi, N., Dai, X., Tao, W. and Li, Z., 2017, “Evaluation of thermal hydrolysis efficiency of mechanically dewatered sewage sludge via rheological measurement”, Water Res. 116, 34–43.
    [2017]
  • Zhang, B., Zhang, L. L., Zhang, S. C., Shi, H. Z., and Cai, W. M., 2005, “The influence of pH hydrolysis and acidogenesis of kitchen wastes in two-phase anaerobic digestion”, Environmental Technology, Vol. 26, No. 3, 329-340.
    [2005]
  • Yu, B., Xu, J., Yuan, H., Lou, Z., Lin, J., and Zhu, N.. 2014, “Enhancement of anaerobic digestion of waste activated sludge by electrochemical pretreatment”, Fuel, Vol. 130, No. 10, 279-285.
    [2014]
  • Xue, Y., Liu, H., Chen, S., Dichtl, N., Dai, X. and Li, N., 2015, “Effects of thermal hydrolysis on organic matter solubilization and anaerobic digestion of high solid sludge”, Chem. Eng. J. 264, 174–180.
    [2015]
  • Xue, Y., Liu, H., Chen, S., Dichtl, N., Dai, X and Li N., 2015, "Effects of thermal hydrolysis on organic matter solubilization and anaerobic digestion of high solid sludge", chemical engineering journal –lausanne-, Vol.264 No., 174-180.
    [2015]
  • Xie, R., Xing, Y., Ghani, Y. A., Ooi, K., and Ng, S., 2007, “Full-scale demonstration of an ultrasonic disintegration technology in enhancing anaerobic digestion of mixed primary and thickened secondary sewage sludge”, Journal of Environmental Engineering and Science, Vol. 6, No. 5, 533-541.
    [2007]
  • Wilson, C. A. and Novak, J. T., 2009, “Hydrolysis of macromolecular components of primary and secondary wastewater sludge by thermal hydrolytic pretreatment”, Water Research, (43), 4489-4498.
    [2009]
  • Veluchamy, C., Raju, V. W., and Kalamdhad, A. S., 2018, “Electrohydrolysis pretreatment for enhanced methane production from lignocellulose waste pulp and paper mill sludge and its kinetics”, Bioresource Technology, Vol. 252, 52-58.
    [2018]
  • Veluchamy, C., Raju, V. W., and Kalamdhad, A. S., 2017, “Prerequisite – an electrohydrolysis pretreatment for anaerobic digestion of lignocellulose waste material”, Bioresource Technology, Vol. 235, 274-280.
    [2017]
  • Veluchamy, C. and Kalamdhad, A. S., 2017, “Influence of pretreatment techiques on anaerobic digestion of pulp and paper mill sludge: a review”, Bioresource Technology, 245, 1206-1219.
    [2017]
  • Veeken, A., Kalyuzhnyi, S., Scharff, H. and Hamelers, B., 2000, Effect of pH and VFA on hydrolysis of organic solid waste, Journal of Environmental Engineering, 126, 1076-1081.
    [2000]
  • Valo, A., Carrère, H. and Delgenès, J. P., 2004, “Thermal, chemical and thermo-chemical pre-treatment of waste activated sludge for anaerobic digestion”, Journal of Chemical Technology and Biotechnology.
    [2004]
  • Urbain, V., Pys, E., Block, J. C. and Manem, J., 1993, "Composition and Activity of Activated Sludge under Starvation Conditions", Environmental Technology, Vol.14 No.8, 731.
    [1993]
  • Ueki, A., Akasaka, H., Suzuki, D. and Ueki, K., 2006, “Paludibacter propionicgenes gen. nov., sp. nov., a novel strictly anaerobic, Gram-negative, propionate-producing bacterium isolated from plant residue in irrigated rice-field in Japan,” International Journal of Systematic and Evolutionary Microbiology, 56, 39-44.
    [2006]
  • US Environmental Protection Agency (US EPA), 1999. Environmental Regulations and Technology-Control of pathogens and vector attraction in sewage sludge. EPA/625/R-92/013. Washington, DC.
    [1999]
  • Tyagi, V. K., and Lo, S. L., 2011, “Application of physico-chemical pretreatment methods to enhance the sludge disintegration and subsequent anaerobic digestion: an up to date review”, Rev. Environ. Sci. Bio/Technol., Vol. 10, No. 3, 215-242.
    [2011]
  • The microbiology of anaerobic digesters
  • The effects of ultrasonic disintegration as a function of waste activated sludge characteristics and technical conditions of conducting the process ? comprehensive analysis
    Tytia , M. Vol . 15 , No . 10 , 2311 . [2018]
  • Tanja, J., Jelena, A., Srđan, M., Latinka, S., Dalibor, S., Jelena, M., Mila Ilić, V. B., Gordana, G., and Miroslav, M. V., 2017, “Transformation and synthesis of humic substances during bioremediation of petroleum hydrocarbons”, Int. Biodeterior. Biodegradation, Vol. 122, 47-52.
    [2017]
  • Tampio, E., Ervasti, S., Paavola, T., Heaven, S., Banks, C. and Rintala, J., 2014, “Anaerobic digestion of autoclaved and untreated food waste” Waste Manag. 34(2), 370-377.
    [2014]
  • Suhartini, S., Melville, L., and Amato, T., 2017, “Pre-treatment of thickened waste activated sludge (TWAS) for enhanced biogas production via the application of a novel radial horn sonication technology”, Water Science & Technology, Vol. 75, No. 9, 2179-2193.
    [2017]
  • Stuckey, D. C and McCarty, P. L., 1984 “The effect of thermal pretreatment on the anaerobic biodegradability and toxicity of waste activated sludge”, Water Research, 18(11), 1343-1353.
    [1984]
  • Stronach, S. M., Rudd, T. and Lester, J. N., 1986, “Anaerobic digestion processes in industrial wastewater treatment”, Springer-Verlag.
    [1986]
  • Stephenson, R., Rabinowitz, B., Laliberte, S., and Elson, P., 2005, “Teaching an old digester new tricks: full-scale demonstration of the MicroSludge process to liquefy municipal waste activated sludge”, In: Proceedings of the Water Environment Federation, Residuals and Biosolids Management, 386-411.
    [2005]
  • Standard Methods for Examination of Water and Wastewater , 21st ed.
    APHA [2005]
  • Sobeck, D. C. and Higgins, M. J., 2002, "Examination of three theories for mechanisms of cation-induced bioflocculation", Water research, Vol.36 No.3, 527-538.
    [2002]
  • Smith, K. S. and Ingram-Smith, C., 2007, “Methanosaeta, the forgotten methagen?”, Trends Microbiology, 15(4), 150-155.
    [2007]
  • Sludge processing to optimize digestibility and energy production
  • Shah, F. A., Mahmood, Q., Shah, M. M., Pervez, A. and Asad, S. A., 2014, “Microbial ecology of anaerobic digesters: The key players of anaerobiosis,” The Scientific World Journal, 1-21.
    [2014]
  • Sapkaite, I., Barrado, E., Fdz-Polanco, F. and Pérez-Elvira, S. I., 2017, “Optimization fo a thermal hyddrolysis process for sludge pre-treatment”, J. of Environ. Manag., 192, 25-30.
    [2017]
  • Rodriguez, F. J., Schlenger, P. and Garciavalverde, M., 2016, “Monitoring changes in the structure and properties of humic substances following ozonation using UV-Vis”, FTIR and (1)H NMR techniques. Sci. Total Environ. 541, 623–637.
    [2016]
  • Pèrez-Elvira, S. I., Sapkaite, I. and Fdz-Polanco, F., 2015, “Evaluation of thermal steam-explosion key operation factors to optimize biogas production from biological sludge”, Wat. Sci. & Technol., 72, 937-945.
    [2015]
  • Pavlostathis, S. G. and Giraldo-Gomez, E., 1991, “Kinetics of anaerobic treatment: A critical review”, Critical Reviews in Environmental Control, Vol. 21(5-6), 411-490.
    [1991]
  • Ormaechea, P., Castrillón, L., Suárez-Peña, B., Megido, L., Fernández-Nava, Y., Negral, L., Marañón, E., and Rodríguez-Iglesias, J., 2018, “Enhancement of biogas production from cattle manure pretreated and/or co-digested at pilot-plant scale. Characterization by SEM” Renewable Energy, Vol. 126, 897-904.
  • Oremland, R. S., 1988, “Biogeochemistry of methanogenic bacteria. In Biology of Anaerobic Microorganisms”, edited by J. B. Alexander Zehnder, pp. 641–705. John Wiley & Sons, Inc., New York, USA.
    [1988]
  • Oosterhuis, M., Ringoot, D., Hendriks, A. and Roeleveld, P., 2014, “Thermal hydrolysis of waste activated sludge at Hengelo wastewater treatment plant”, The Netherlands. Water Sci. Technol. 70(1), 1-7.
    [2014]
  • Novak, J. T., Muller, C. D. and Murthy, S. N., 2001, "Floc structure and the role of cations", Water science and technology, Vol.44 No.10, 209-214.
    [2001]
  • Nopharatana, A., Pullammanappallil, P. C. and Clarke, W. P., 2007, "Kinetics and dynamic modelling of batch anaerobic digestion of municipal solid waste in a stirred reactor", Waste Management, Vol.27 No.5, 595-603.
    [2007]
  • Ngwenya, Z., Beightol, S., Ngone O, T., Vega, J., Pathak, B., Al-Omari, A., Zhu, K., Wadhawan, T., Murthy, S. N. and Higgins, M.J., 2015, “A stoichiometric a roach to control digester chemistry and ammonia inhibition in anaerobic digestion with thermal hydrolysis pretreatment: model development”, In: Proceedings of WEF Residuals and Biosolids 2015. Water and Environment Federation, Washington DC.
  • Ngo, P. L., Udugama, I., Gernaey, K. V., Young, B. R. andBaroutian, S., 2021,“Mechanisms, status, and challenges of thermal hydrolysis and advanced thermal hydrolysis processes in sewage sludge treatment” Chemosphere Vol. 281, 130890
  • Neyens, E., Baeyens, J., Dewil, R. and De, H. B., 2004, "Advanced sludge treatment affects extracellular polymeric substances to improve activated sludge dewatering", Journal of hazardous materials, Vol.106 No.2-3, 83-92.
    [2004]
  • Neyens, E., Baeyens, J. and Creemers, C., 2003, "Alkaline thermal sludge hydrolysis", Journal of hazardous materials, Vol.97 No.1-3, 295-314.
    [2003]
  • Neis, U., Nickel, K., and Lundèn, A., 2008, “Improving anaerobic and aerobic degradation by ultrasonic disintegration of bio-mass”, Journal of Environmental Science and Health Part A. Vol. 43, 1541-1545.
    [2008]
  • Müller, J. A., 2001, “Prospects and problems of sludge pre-treatment processes”, Water Science & Technology, 44(10), 121–128.
    [2001]
  • Microbiology of anaerobic digestion
    Novaes , R. F. V. Vol . 18 , No . 12 , 1-14 . [1986]
  • Merry, J. and Oliver, B., 2015, “A comparison of real ad plant performance: howdon, bran sands, cardiff and afan., In: Proceedings of Aquaenviro's 20th European Biosolids and Organic Resources Conference and Exhibition, Manchester, UK.
    [2015]
  • McCarty, P. L. and Mosey, F. E., 1991, “Modelling of anaerobic digestion processes (A discussion of concepts)”, Water Science & Technology, 24(8), 17-33.
    [1991]
  • Mata-Alvarez, J., Dosta, J., Romero-Güiza, M. S., Fonoll, X., Peces, M. and Astals, S., 2013, “A critical review on anaerobic co-digestion achievements between 2010 and 2013”, Renewable and Sustainable Energy Reviews, 36, 412-427.
    [2013]
  • Martins, M. S., Cabral, J., Lanceros-Mendez, S. and Rocha, G., 2015, "Effect of the acoustic impedance in ultrasonic emitter transducers using digital modulations", Ocean Engineering, Vol.100 No.-, 107-116.
    [2015]
  • Malina, J. F. and Pohland, J. F. G., 1992, “Design of anaerobic processes for the treatment of industrial and municipal wastes”, CRC Press.
    [1992]
  • Ma, J., Frear, C., Wang, Z., Yu, L., Zhao, Q., Li, X. and Chen, S., 2013, “A simple methodology for rate-limiting step determination for anaerobic digestion of complex substrates and effect of microbial community ratio”, Bioresource Technology, 134, 391-395.
    [2013]
  • MBR에서 MLSS가 막 fouling 발생에 미치는 영 향에 대한 연구
    김윤지 황선진 한국폐기물자원순환학회 춘계학술발표논문집, 2020, 288-288 [2020]
  • Liu, X., Wang, W., Gao, X., Zhou, Y. and Shen, R., 2012, “Effect of thermal pretreatment on the physical and chemical properties of municipal biomass waste”, Waste Manag. 32 (2), 249-255.
    [2012]
  • Liu, Changgeng., Zhang, Xuefeng., Wu, B., Chen, X and Xie, Sicai., 2019, "Dewatering characteristics of sludge conditioned by surfactant with bioleaching pretreatment", Water and Environment Journal, Vol.33 No.2, 223-229.
    [2019]
  • Liao, X., Li, H., Zhang, Y., Liu, C. and Chen, Q., 2016, “Accelerated high-solids anaerobic digestion of sewage sludge using low-temperature thermal pretreatment”, Int. Biodeterior. Biodegrad. 106, 141-149.
    [2016]
  • Li, Y. Y. and Noike, T., 1992, “Upgrading of anaerobic digestion of waste activated sludge by thermal hydrolysis”, Water Sci. Technol. 26, 857–866.
    [1992]
  • Lee, W., Westerhoff, P. and Esparza-Soto, M., 2006, “Occurrence and removal of dissolved organic nitrogen in US water treatment plants”. Journal American Water Works Association 98(10), 102 –110.
    [2006]
  • Lee, S. H., Park, J. H., Kang, H. J., Lee, Y. H., Lee, T. J. and Park, H. D., 2013, “Distribution and abundane of Spirochaetes in full-scale anaerobic digesters”, Bioresour. Technol. 145, pp. 25– 32.
    [2013]
  • Lee, J., Shin, S. G., Han, G., Koo, T. and Hwang, S., 2017, “Bacteria and archaea communities in full-scale thermophilic and mesophilic anaerobic digestion treating food wastewater: key process parameters and microbial indicators of process instability”. Bioresour. Technol. 245, 689–697.
    [2017]
  • Lee, I. S. and Rittmann, B. E., 2011, "Effect of low solids retention time and focused pulsed pre-treatment on anaerobic digestion of waste activated sludge", Bioresource technology, Vol.102 No.3, 2542-2548.
    [2011]
  • Lay, J. J., Li, Y. Y. and Noike, T., 1998, “The influence of pH and ammonia concentration on the methane production in high-solids digestion processes”, Water Environment Research, 70(5), 1075-1082.
    [1998]
  • Laurent, J., Casellas, M., Pons, M. N. and Dagot, C., 2009, "Flocs surface functionality assessment of sonicated activated sludge in relation with physico-chemical properties", Ultrasonics sonochemistry, Vol.16 No.4, 488-494.
    [2009]
  • Kuglarz, M., Karakashev, D. and Angelidaki, I., 2013, "Microwave and thermal pretreatment as methods for increasing the biogas potential of secondary sludge from municipal wastewater treatment plants", Bioresource Technology, Vol.134 No.- , 290-297.
    [2013]
  • Kopplow, O., Barjenbruch, M., and Heinz, V., 2004, “Sludge pre-treatment with pulsed electric fields”, Water Science & Technology, Vol. 49, No. 10, 123-129.
    [2004]
  • Kim, S. J., Park, S. J., Cha, I. T., Min, D., Kim, J. S., Cung, W. H., Chae, J. C., Jeon, C. O. and Rhee, S. K., 2014, “Metabolic versatility of toluene-degrading, iron-reducing bacteria in tidal flat sediment, characterized by stable isotope probing-based metagenomic analysis”, Environmental Microbiology, 16(1), 189-204.
  • Kelleher, B. P., Leahy, J. J., Henihan, A. M., ODwyer, T. F., Sutton, D. and Leahy, M. J., 2002, “Advances in poultry litter disposal technology-a review”, Bioresource Technology, 83, 27-36.
    [2002]
  • Kafle, G. K. and Kim, S. H., 2013, "Anaerobic treatment of apple waste with swine manure for biogas production: Batch and continuous operation", applied energy -barking then oxford- , Vol.103 No.-, pp 61-72.
    [2013]
  • Jeong, S. Y., Chang, S, W., Ngo H. H., Guo, W., Nghiem, L. D. ,Banu, J. R., Jeon, B. H. and Nguyen, D. D., 2019, "Influence of thermal hydrolysis pretreatment on physicochemical properties and anaerobic biodegradability of waste activated sludge with different solids content" Waste Management, Vol.85 No.- , 214-221.
    [2019]
  • Jeon, B. C. and Namb, S. Y., 2019, “The relation between sewage sludge solubilization and extracellular polymeric substances”, Journal of the Korea Organic Resources Recycling Association, 27(4), 43-49.
    [2019]
  • Huang, F., Wen, J., Zhao, C., Dong, L. and Liu, H., 2021, “Underestimated humic acids release and influence on anaerogic digestion during sludge thermal hydrolysis”, Water Research, 201, 117310.
  • Houghton, J. I., Quarmby, J. and Stephenson, T., 2001, "Municipal wastewater sludge dewaterability and the presence of microbial extracellular polymer", Water science and technology, Vol.44 No.2-3, 373-380.
    [2001]
  • Houghton, J. I. and Stephenson, T., 2002, "Effect of influent organic content on digested sludge extracellular polymer content and dewaterability", Water research, Vol.36 No.14, 3620-3628.
    [2002]
  • Hosseini K. E., and Eskicioglu, C., 2016, “Conventional heating vs. microwave sludge pretreatment comparison under identical heating/cooling profiles for thermophilic advanced anaerobic digestion”, Waste Management, Vol. 53, 182-195.
    [2016]
  • Hong, S. M., Park, J. K., Teeradej, N., Lee, Y. O., Cho, Y. K., and Park, C. H., 2006, “Pretreatment of sludge with microwave for pathogen destruction and improved anaerobic digestion performance”, Water Environ. Res., Vol. 78, No. 1, 76-83.
    [2006]
  • Higgins, M. J., Beightol, S., Mandahar, U., Suzuki, R., Xiao, S., Lu, H.-W., Le, T., Mah, J., Pathak, B., DeClippeleir, H., Novak, J.T., Al-Omari, A. and Murthy, S.N., 2017, “Pretreatment of a primary and secondary sludge blend at different thermal hydrolysis temperatures: impacts on anaerobic digestion, dewatering and filtrate characteristics”, Water Res. 122, 557–569.
  • Higgins, M. J. and Novak, J. T., 1997, "Characterization of Exocellular Protein and Its Role in Bioflocculation", Journal of environmental engineering, Vol.123 No.5, 479-485.
    [1997]
  • Haug, R. T., Stuckey, D. C., Gossett, J. M. and McCarty, P. L., 1978, “Effect of thermal pretreatment on digestibility and dewaterability of organic sludges”, J.Water Pollut. Control Fed., 73-85.
    [1978]
  • Gujer, W. and Zehnder, A. J. B., 1983, “Conversion processes in anaerobic digestion”, Water Science & Technology, 15(8-9), 127-167.
    [1983]
  • Graja, S., Chauzy, J., Fernendes, P., Patria, L. and Cretenot, D., 2005, “Reduction of sludge production from WWTP using thermal pretreatment and enhanced anaerobic methanisation”, Water Science & Technology, 52(1-2), 267-273.
    [2005]
  • Fricke, K., Santen, H., Wallmann, R., Huttner, A. and Dichtl, N., 2007, “Operating problems in anaerobic digestion plants resulting from nitrogen in MSW”, Waste Management, 27(1), 30-43.
    [2007]
  • Ebenezer, A. V., Kaliappan, S., Kumar, S. A., Yeom, I. T., and Banu, J. R., 2015, “Influence of deflocculation on microwave disintegration and anaerobic biodegradability of waste activated sludge”, Bioresource Technology, Vol. 185, 194-201.
    [2015]
  • Dwyer, J., Starrenbury, D., Tait, S., Barr, K., Batstone, D. J. and Lant, P., 2008, “Decreasing activated sludge thermal hydrolysis temperature reduces product colour, without decreasing degradability”, Water Res. 42 (18), 4699–4709.
    [2008]
  • Demirel, B. and Scherer, P., 2008, "Production of methane from sugar beet silage without manure addition by a single-stage anaerobic digestion process", biomass and bioenergy, Vol.32 No.3, 203-209.
    [2008]
  • Cysneiros, D., Banks, C. J., Heaven, S. and Karatzas, K. A., 2012, "The effect of pH control and `hydraulic flush' on hydrolysis and Volatile Fatty Acids (VFA) production and profile in anaerobic leach bed reactors digesting a high solids content substrate", Bioresource technology, Vol.123 No.-, 263-271.
    [2012]
  • Conklin, A., Stensel, H. D. and Ferguson, J., 2006, “Growth kinetics and competition between Methanosarcina and Methanosaeta in mesophilic anaerobic digestion”, Water Environmental Research, 78, 486-496.
    [2006]
  • Coca, M., Pena, M. and Gonzalez, G., 2005, "Chemical Oxidation Processes for Decolorization of Brown-Colored Molasses Wastewater", Ozone Science and Engineering, Vol.27 No.5, 365-370.
    [2005]
  • Chu, C. P., Lee, D. J., Chang, B. V., You, C. S. and Tay, J. H., 2002, “"Weak" ultrasonic pre-treatment on anaerobic digestion of flocculated activated biosolids", Water Research, Vol.36 No.11, 2681-2688.
    [2002]
  • Christensen, M. L., Keiding, K., Nielsen, P. H. and Jørgensen, M. K., 2015, "Dewatering in biological wastewater treatment: A review", Water Research, Vol.82 No.-, pp 14-24.
    [2015]
  • Choi, J. M., Han, S. K. and Lee, C. Y., 2018, “Enhancement of methane production in anaerobic digestion of sewage sludge by thermal hydrolysis pretreatment”, Bioresource Technology, 259, 207-213.
    [2018]
  • Chen, Y. C., Higgins, M. J., Beightol, S. M., Murthy, S. N. and Toffey, W.E., 2011, “Anaerobically digested biosolids odor generation and pathogen indicator regrowth after dewatering”, Water Res. 45(8), 2616-2626.
    [2011]
  • Characteristics on degradability of organic materials in mesophilic anaerobic digestion with ultrasound
  • Carrere, H., Bougrier, C., Castets, D. and Delgenes, J. P., 2008, "Impact of initial biodegradability on sludge anaerobic digestion enhancement by thermal pretreatment", Journal of Environmental Science and Health. Part A: Toxic Hazardous Substances and Environmental Engineering, Vol.43 No.13, 1551-1555.
    [2008]
  • Carosia, M. F., Okada, D. Y., Sakamoto, I. K., Silva, E. L. and Varesche, M. B. A., 2014, “Microbial characterization and degradation of linear alkylbenzene sulfonate in an anaerobic reactor treating wastewater containing soap powder”, Bioresource Technology, 167, 316-323.
    [2014]
  • Bushwell, A. M. and Mueller, H. F., 1952, “Mechanisms of methane fermentation”, Industrial & Engineering Chemistry, 44(3), 550-552.
    [1952]
  • Bougrier, D. J. and Carrère, H., 2007, “Impacts of thermal pre-treatments on the semicontinuous anaerobic digestion of waste activated sludge”, Biochem. Eng. J. 34 (1), 20-27.
    [2007]
  • Biomethanization of the organic fraction of municipal solids wastes
  • Bian, X., Gong, H. and Wang, K., 2018, “Pilot-scale hydrolysis-aerobic treatment for actual municipal wastewater: Performance and microbial community analysis”, International Journal of Environmental Research and Public Health, 15, 1-8.
    [2018]
  • Beszedes, S., Laszlo, Z., Horvath, Z. H., Szabo, G. and Hodur, C., 2011, "Comparison of the effects of microwave irradiation with different intensities on the biodegradability of sludge from the dairy- and meat-industry", Bioresource technology, Vol.102 No.2, 814-821.
    [2011]
  • Basic wastewater treatment
    Yu , S. H. [1998]
  • Barber, W.P.F., 2016, “Thermal hydrolysis for sewage treatment: a critical review”, Water Res., 104, 53–71.
    [2016]
  • Bala Subramanian, S., Yan, S., Tyagi, R. D. and Surampalli, R. Y., 2010, "Extracellular polymeric substances (EPS) producing bacterial strains of municipal wastewater sludge: Isolation, molecular identification, EPS characterization and performance for sludge settling and dewatering", Water Research, 2253-2266.
    [2010]
  • Bala Subramanian S, Kamat, A. S., Ussuf, K. K. and Tyagi, R. D., 2006, "Virulent gene based DNA probe for the detection of pathogenic Bacillus cereus strains found in food", Process Biochemistry, 783-788.
    [2006]
  • Ashley, N. V. and Hurst, T. J., 1981, “Acid and alkaline phosphatase activity in anaerobic digested sludge: a biochemical predictor of digester failure”, Water Research, 15, 633-638.
    [1981]
  • Appels, L., Degreve, J., van der Bruggen, B., van Impe, J. and Dewil, R., 2010, "Influence of low temperature thermal pre-treatment on sludge solubilisation, heavy metal release and anaerobic digestion", Bioresource technology, Vol.101 No.15, 5743-5748.
    [2010]
  • Anaerobic digestion for sustainable development : a natural approach
    Gijzen , H. H. 45 ( 10 ) , 321-328 . [2002]
  • Anaerobic biotechnology for industrial wastewaters
  • Anaerobic biotechnology for bioenergy production : Principles and applications
  • Abelleira-Pereira, J. M., Pérez-Elvira, S. I., Sánchez-Oneto, J., de la, Cruz. R., Portela, J. R. and Nebot, E., 2015, "Enhancement of methane production in mesophilic anaerobic digestion of secondary sewage sludge by advanced thermal hydrolysis pretreatment", Water research, Vol.71 No.-, 330-340.
    [2015]
  • Abelleira, J., Pérez-Elvira, S. I., Portela, J. R., Sánchez-Oneto, J. and Nebot, E., 2012, “Adavanced thermal hydrolysis: Optimization of a novel thermochemical process to aid sewage sludge treatment” Environmental Science & Technology, 46(11), 6158-6166.
    [2012]
  • Abe, N., Tang, Y. Q., Iwamura, M., Morimura, S., and Kida, K., 2013, “Pretreatment followed by anaerobic digestion of secondary sludge for reduction of sewage sludge volume”, Water Science & Technology, Vol. 67, No. 11, 2527-2533.
    [2013]
  • 2030 하수슬러지감량 및 바이오가스 생산 활용 계획(안)
    환경부 [2012]