Integrating sludge drying in biomass fueled CHP plants

Jinshan Wang; Chaudhary Awais Salman; Bin Wang; Hailong Li; Eva Thorin

doi:10.1007/s40974-020-00187-x

Energy, Ecology and Environment ›› 2021, Vol. 6 ›› Issue (1) : 1 -12. DOI: 10.1007/s40974-020-00187-x

Original Article

Integrating sludge drying in biomass fueled CHP plants

Author information +

History +

PDF

Abstract

Handling sludge through thermal conversion is environmentally friendly, which, however, requires sludge drying. This work proposed to use the waste heat of flue gas (FG) to dry sludge. The integration of sludge drying in biomass fueled combined heat and power (CHP) plants can clearly affect the performance of downstream processes in FG cleaning, such as flue gas quench (FGQ) and flue gas condenser, and further affect the energy efficiency of CHP. In order to understand the influence, a mathematical model and an Aspen PLUS model were developed to simulate the drying process and the CHP, respectively. Based on simulations, it is found that the increase of feeding rate of sludge and the moisture content of sludge after drying can decrease the water evaporation in FGQ. An increase in the feeding rate of sludge in combination with a drop of moisture content of sludge after drying can decrease the heat recovery from FG. When using dried sludge to replace biomass, the amount of saving could be influenced by the moisture content after drying and the flow rate of sludge. Simulation results show that drying sludge to a moisture content of 40% leads to the maximum biomass saving.

Keywords

Flue gas quench / Heat recovery / Sludge drying / CHP / Energy efficiency

Cite this article

Download citation ▾

Jinshan Wang, Chaudhary Awais Salman, Bin Wang, Hailong Li, Eva Thorin. Integrating sludge drying in biomass fueled CHP plants. Energy, Ecology and Environment, 2021, 6(1): 1-12 DOI:10.1007/s40974-020-00187-x

登录浏览全文

4963

注册一个新账户忘记密码

References

Publishing order | Descend order by publishing year | Descend order by cited within

[1]	Akdağ AS, Atak O, Atimtay AT, Sanin FD. Co-combustion of sewage sludge from different treatment processes and a lignite coal in a laboratory scale combustor. Energy, 2018, 158: 417-426

[2]	Ameri B, Hanini S, Boumahdi M. Influence of drying methods on the thermodynamic parameters, effective moisture diffusion and drying rate of wastewater sewage sludge. Renew Energy, 2020, 147: 1107-1119

[3]	Arlabosse P, Chitu T. Identification of the limiting mechanism in contact drying of agitated sewage sludge. Dry Technol, 2007, 25: 557-567

[4]	Arlabosse P, Ferrasse JH, Lecomte D, Crine M, Dumont Y, Léonard A. Efficient sludge thermal processing: from drying to thermal valorization. Mod Dry Technol Energy Sav, 2011, 4: 295-329

[5]	Ayol A, Yurdakos OT, Gurgen A. Investigation of municipal sludge gasification potential: gasification characteristics of dried sludge in a pilot-scale downdraft fixed bed gasifier. Int J Hydrog Energy, 2019, 44(32): 17397-17410

[6]	Bennamoun L, Arlabosse P, Leonard A. Review on fundamental aspect of application of drying process to wastewater sludge. Renew Sust Energy Rev, 2013

[7]	Bianchini A, Bonfiglioli L, Pellegrini M, Saccani C. Sewage sludge drying process integration with a waste-to-energy power plant. Waste Manag, 2015, 42(aug): 159-165

[8]	Charlou C, Milhe M, Sauceau M, Arlabosse P. A new methodology for measurement of sludge residence time distribution in a paddle dryer using X-ray fluorescence analysis. Water Res, 2015

[9]	Chen S, Wang F, Milhé M, Arlabosse P, Liang F, Chi Y, Nzihou A, Yan J. Experimental and theoretical research on agitated contact drying of sewage sludge in a continuous paddle dryer. Dry Technol, 2016, 34(16): 1979-1990

[10]	Chen SQ, Wang F, Chi Y, Yan JH, Cen KF. Analysis on mass and energy balance of sludge drying and incineration system. Chin J Environ Eng, 2017, 11(1): 515-521

[11]	Chin S, Jurng J, Lee JH, Hur JH. Oxygen-enriched air for co-incineration of organic sludges with municipal solid waste: a pilot plant experiment. Waste Manag, 2008, 28(12): 2684-2689

[12]	Dai Z, Su M, Ma X, Wang G, Li D, Liu C, Weng H. Direct thermal drying of sludge using flue gas and its environmental benefits. Dry Technol, 2018, 36(8): 1006-1016

[13]	Deng WY, Yan JH, Li XD, Wang F, Lu SY, Chi Y, Cen KF. Measurement and simulation of the contact drying of sewage sludge in a Nara-type paddle dryer. Chem Eng Sci, 2009, 64(24): 5117-5124

[14]	Deng W, Su Y, Yu W. Theoretical calculation of heat transfer coefficient when sludge drying in a nara-type paddle dryer using different heat carriers. Proc Environ Sci, 2013, 18: 709-715

[15]	Emad AH, Nils G (2017) Sustainable flue-gas quench: for waste incineration plants within a water-energy-environment nexus perspective. Dissertation, Mälardalen University

[16]	Farid MAA, Roslan AM, Hassan MA, Ujang FA, Mohamad Z, Hasan MY, Yoshihito S. Convective sludge drying by rotary drum dryer using waste steam for palm oil mill effluent treatment. J Clean Prod, 2019, 240: 117986

[17]	Ferrasse JH, Arlabosse P, Lecomte D. Heat, momentum, and mass transfer measurements in indirect agitated sludge dryer. Dry Technol, 2002, 20(4–5): 749-769

[18]	Fraikin L, Salmon T, Herbreteau B, Levasseur JP, Nicol F, Crine M, Léonard A. Impact of storage duration on the gaseous emissions during convective drying of urban residual sludges. Chem Eng Technol, 2011, 34(7): 1172-1176

[19]	Galanopoulos C (2015) Impact analysis for major emissions from combustion of contaminated wooden fuels. Dissertation, KTH Royal Institute of Technology

[20]	Kim JH, Oh JI, Lee J, Kwon EE. Valorization of sewage sludge via a pyrolytic platform using carbon dioxide as a reactive gas medium. Energy, 2019, 179: 163-172

[21]	Kor-Bicakci G, Ubay-Cokgor E, Eskicioglu C. Effect of dewatered sludge microwave pretreatment temperature and duration on net energy generation and biosolids quality from anaerobic digestion. Energy, 2019, 168: 782-795

[22]	Kuan YH, Wu FH, Chen GB, Lin HT, Lin TH. Study of the combustion characteristics of sewage sludge pyrolysis oil, heavy fuel oil, and their blends. Energy, 2020

[23]	Kudra T. Sticky region in drying—definition and identification. Dry Technol, 2003, 21(8): 1457-1469

[24]	Lee U, Balu E, Chung JN. An experimental evaluation of an integrated biomass gasification and power generation system for distributed power applications. Appl Energy, 2013, 101: 699-708

[25]	Léonard A, Meneses E, Le TE, Salmon T, Marchot P, Toye D, Crine M. Influence of back mixing on the convective drying of residual sludges in a fixed bed. Water Res, 2008, 42(10–11): 2671-2677

[26]	Li H, Wang B, Yan J, Salman CA, Thorin E, Schwede S. Performance of flue gas quench and its influence on biomass fueled CHP. Energy, 2019, 180: 934-945

[27]	Ma XW, Weng HX, Su MH, Pan L. Drying sewage sludge using flue gas from power plants in China. Environ Earth Sci, 2012, 65(6): 1841-1846

[28]	Mahmoud A, Olivier J, Vaxelaire J, Hoadley AF. Electrical field: a historical review of its application and contributions in wastewater sludge dewatering. Water Res, 2010, 44(8): 2381-2407

[29]	Milhé M, Charlou C, Sauceau M, Arlabosse P. Modeling of sewage sludge flow in a continuous paddle dryer. Dry Technol, 2015, 33(9): 1061-1067

[30]	Milhé M, Sauceau M, Arlabosse P. Modeling of a continuous sewage sludge paddle dryer by coupling Markov chains with penetration theory. Appl Math Model, 2016, 40(19–20): 8201-8216

[31]	Murakami T, Suzuki Y, Nagasawa H, Yamamoto T, Koseki T, Hirose H, Okamoto S. Combustion characteristics of sewage sludge in an incineration plant for energy recovery. Fuel Process Technol, 2009, 90(6): 778-783

[32]	Salman CA, Naqvi M, Thorin E, Yan J. Impact of retrofitting existing combined heat and power plant with polygeneration of biomethane: a comparative techno-economic analysis of integrating different gasifiers. Energy Convers Manag, 2017, 152: 250-265

[33]	Salman CA, Schwede S, Thorin E, Li H, Yan J. Identification of thermochemical pathways for the energy and nutrient recovery from digested sludge in wastewater treatment plants. Energy Proc, 2019, 158: 1317-1322

[34]	Schnell M, Horst T, Quicker P. Thermal treatment of sewage sludge in Germany: a review. J Environ Manag, 2020, 263: 110367

[35]	Stockholm Water and Waste (2019) “Quality and control”. http://www.stockholmvatten.se/en/water-and-wastewater/drinking-water/quality-and-control/. Accessed 12 Jan 2019

[36]	Tańczuk M, Kostowski W, Karaś M. Applying waste heat recovery system in a sewage sludge dryer—a technical and economic optimization. Energy Convers Manag, 2016, 125: 121-132

[37]	The council of the European Union (1999) “Council Directive 1999/31/EC of 26 April 1999 on the landfill of waste”. https://eur-lex.europa.eu/legal-content/EN/TXT/HTML/?uri=CELEX:31999L0031&qid=1587699810546&from=EN. Accessed 12 April 2020

[38]	Tsotsas E, Schlünder EU. Contact drying of mechanically agitated particulate material in the presence of inert gas. Chem Eng Process, 1986, 20(5): 277-285

[39]	Wang R, Wang C, Zhao Z, Jia J, Jin Q. Energy recovery from high-ash municipal sewage sludge by hydrothermal carbonization: fuel characteristics of biosolid products. Energy, 2019, 186: 115848

[40]	Wang B, Wang J, Li H, Thorin E, Schwede S (2019b) Feasibility analysis of drying sludge using flue gas waste heat. In: DEStech Transactions on Environment, Energy and Earth Sciences (ICEEE). https://doi.org/10.12783/dteees/iceee2019/31826

[41]	Xu J, Liao Y, Yu Z, Cai Z, Ma X, Dai M, Fang S. Co-combustion of paper sludge in a 750 t/d waste incinerator and effect of sludge moisture content: a simulation study. Fuel, 2018, 217: 617-625

[42]	Zheng A, Li L, Tippayawong N, Huang Z, Zhao K, Wei G, Zhao Z, Li H. Reducing emission of NOx and SOx precursors while enhancing char production from pyrolysis of sewage sludge by torrefaction pretreatment. Energy, 2020, 192(2020): 116620