1 year ago

Food Waste to Energy: An Overview of Sustainable Approaches for Food Waste Management and Nutrient Recycling (BMRI2017-2370927)

  • Text
  • Anaerobic
  • Methane
  • Microbial
  • Organic
  • Biogas
  • Bioresource
  • Reported
  • Environmental
  • Bacteria
  • Yield
  • Overview
  • Sustainable
  • Approaches
  • Nutrient
  • Recycling
Review Article Food Waste to Energy: An Overview of Sustainable Approaches for Food Waste Management and Nutrient Recycling Kunwar Paritosh, 1 Sandeep K. Kushwaha, 2 Monika Yadav, 1 Nidhi Pareek, 3 Aakash Chawade, 2 and Vivekanand Vivekanand 1 1 Centre for Energy and Environment, Malaviya National Institute of Technology, Jaipur, Rajasthan 302017, India Department of Plant Breeding, Swedish University of Agricultural Sciences, P.O. Box 101, 230 53 Alnarp, Sweden 3 Department of Microbiology, School of Life Sciences, Central University of Rajasthan Bandarsindri, Kishangarh, Ajmer, Rajasthan 305801, India 2 Correspondence should be addressed to Vivekanand Vivekanand; Received 14 November 2016; Revised 29 December 2016; Accepted 12 January 2017; Published 14 February 2017 Academic Editor: José L. Campos Copyright © 2017 Kunwar Paritosh et al. This is an open access article distributed under the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited. Food wastage and its accumulation are becoming a critical problem around the globe due to continuous increase of the world population. The exponential growth in food waste is imposing serious threats to our society like environmental pollution, health risk, and scarcity of dumping land. There is an urgent need to take appropriate measures to reduce food waste burden by adopting standard management practices. Currently, various kinds of approaches are investigated in waste food processing and management for societal benefits and applications. Anaerobic digestion approach has appeared as one of the most ecofriendly and promising solutions for food wastes management, energy, and nutrient production, which can contribute to world’s ever-increasing energy requirements. Here, we have briefly described and explored the different aspects of anaerobic biodegrading approaches for food waste, effects of cosubstrates, effect of environmental factors, contribution of microbial population, and available computational resources for food waste management researches.

16 BioMed Research

16 BioMed Research International [71]H.Bouallagui,Y.Touhami,R.BenCheikh,andM.Hamdi, “Bioreactor performance in anaerobic digestion of fruit and vegetable wastes,” Process Biochemistry,vol.40,no.3-4,pp.989– 995, 2005. [72] P. D. Cotter and C. Hill, “Surviving the acid test: responses of gram-positivebacteriatolowpH,”Microbiology and Molecular Biology Reviews,vol.67,no.3,pp.429–453,2003. [73] B. Zhang, L.-L. Zhang, S.-C. Zhang, H.-Z. Shi, and W.-M. Cai, “The influence of pH on hydrolysis and acidogenesis of kitchen wastes in two-phase anaerobic digestion,” Environmental Technology, vol. 26, no. 3, pp. 329–339, 2005. [74] J. A. Eastman and J. F. Ferguson, “Solubilisation of particulate organic carbon during theacid phase of AD,” Journal of the Water Pollution Control Federation,vol.53,pp.352–366,1981. [75] E. P. Taiganides, “Biomass-energy recovery from animal waste Part I,” World Animal Review, vol. 35, p. 2, 1980. [76] N. Nagao, N. Tajima, M. Kawai et al., “Maximum organic loading rate for the single-stage wet anaerobic digestion of food waste,” Bioresource Technology,vol.118,pp.210–218,2012. [77]E.Tampio,S.Ervasti,T.Paavola,S.Heaven,C.Banks,andJ. Rintala, “Anaerobic digestion of autoclaved and untreated food waste,” Waste Management,vol.34,no.2,pp.370–377,2014. [78] F. O. Agyeman and W. Tao, “Anaerobic co-digestion of food wasteanddairymanure:effectsoffoodwasteparticlesizeand organic loading rate,” Journal of Environmental Management, vol. 133, pp. 268–274, 2014. [79] M. Carlsson, A. Lagerkvist, and H. Ecke, “Electroporation for enhanced Methane yield from municipal solid waste,” in Proceedings of the Moving Organic Waste Recycling Towards Resource Management and Biobased Economy (ORBIT ’08),vol. 6, pp. 1–8, Wageningen, the Netherlands, October 2008. [80] L. H. Hagen, V. Vivekanand, R. Linjordet, P. B. Pope, V. G. H. Eijsink, and S. J. Horn, “Microbial community structure and dynamics during co-digestion of whey permeate and cow manure in continuous stirred tank reactor systems,” Bioresource Technology, vol. 171, pp. 350–359, 2014. [81] O. Yenigün and B. Demirel, “Ammonia inhibition in anaerobic digestion: a review,” Process Biochemistry, vol.48,no.5-6,pp. 901–911, 2013. [82] M. J. Whelan, T. Everitt, and R. Villa, “A mass transfer model of ammonia volatilisation from anaerobic digestate,” Waste Management, vol. 30, no. 10, pp. 1808–1812, 2010. [83] M. Walker, K. Iyer, S. Heaven, and C. J. Banks, “Ammonia removal in anaerobic digestion by biogas stripping: an evaluation of process alternatives using a first order rate model based on experimental findings,” Chemical Engineering Journal, vol. 178, pp. 138–145, 2011. [84] C. Zhang, H. Su, and T. Tan, “Batch and semi-continuous anaerobic digestion of food waste in a dual solid–liquid system,” Bioresource Technology,vol.145,pp.10–16,2013. [85] F.Raposo,V.Fernández-Cegrí, M. A. de la Rubia et al., “Biochemical methane potential (BMP) of solid organic substrates: evaluation of anaerobic biodegradability using data from an international interlaboratory study,” Journal of Chemical Technology and Biotechnology, vol. 86, no. 8, pp. 1088–1098, 2011. [86] P. Jin, S. K. Bhattacharya, C. J. Williams, and H. Zhang, “Effects of sulfide addition on copper inhibition in methanogenic systems,” Water Research, vol. 32, no. 4, pp. 977–988, 1998. [87] A. Schattauer, E. Abdoun, P. Weiland, M. Plöchl, and M. Heiermann, “Abundance of trace elements in demonstration biogas plants,” Biosystems Engineering,vol.108,no.1,pp.57–65, 2011. [88] V. Facchin, C. Cavinato, F. Fatone, P. Pavan, F. Cecchi, and D. Bolzonella, “Effect of trace element supplementation on the mesophilic anaerobic digestion of foodwaste in batch trials: the influence of inoculum origin,” Biochemical Engineering Journal, vol. 70, pp. 71–77, 2013. [89] C.A.Jackson-Moss,J.R.Duncan,andD.R.Cooper,“Theeffect of calcium on anaerobic digestion,” Biotechnology Letters, vol. 11, no.3,pp.219–224,1989. [90] H. Q. Yu, J. H. Tay, and H. H. P. Fang, “The roles of calcium in sludge granulation during UASB reactor start-up,” Water Research,vol.35,no.4,pp.1052–1060,2001. [91] C.-Y. Lin and C.-C. Chen, “Effect of heavy metals on the methanogenic UASB granule,” Water Research,vol.33,no.2,pp. 409–416, 1999. [92] G. Zayed and J. Winter, “Inhibition of methane production from whey by heavy metals—protective effect of sulfide,” Applied Microbiology and Biotechnology,vol.53,no.6,pp.726–731,2000. [93] S. Ghosh, M. P. Henry, and R. W. Christopher, “Hemicellulose conversion by anaerobic digestion,” Biomass, vol.6,no.4,pp. 257–269, 1985. [94] E. Elbeshbishy, G. Nakhla, and H. Hafez, “Biochemical methane potential (BMP) of food waste and primary sludge: influence of inoculum pre-incubation and inoculum source,” Bioresource Technology,vol.110,pp.18–25,2012. [95] M. S. Lisboa and S. Lansing, “Characterizing food waste substrates for co-digestion through biochemical methane potential (BMP) experiments,” Waste Management, vol. 33, no. 12, pp. 2664–2669, 2013. [96] M. Murto, L. Björnsson, H. Rosqvist, and I. Bohn, “Evaluating the biogas potential of the dry fraction from pretreatment of food waste from households,” Waste Management,vol.33,no.5, pp.1282–1289,2013. [97] J. Marin, K. J. Kennedy, and C. Eskicioglu, “Effect of microwave irradiation on anaerobic degradability of model kitchen waste,” Waste Management,vol.30,no.10,pp.1772–1779,2010. [98]K.Izumi,Y.K.Okishio,C.Niwa,S.Yamamoto,andT.Toda, “Effects of particle size on anaerobic digestion of food waste,” International Journal of Bio-Deterioration Biodegradation, vol. 64,no.7,pp.601–608,2010. [99] J.Ma,T.H.Duong,M.Smits,W.Verstraete,andM.Carballa, “Enhanced biomethanation of kitchen waste by different pretreatments,” Bioresource Technology,vol.102,no.2,pp.592–599, 2011. [100] J.-Y. Wang, X.-Y. Liu, J. C. M. Kao, and O. Stabnikova, “Digestion of pre-treated food waste in a hybrid anaerobic solidliquid (HASL) system,” Journal of Chemical Technology and Biotechnology,vol.81,no.3,pp.345–351,2006. [101] O. Stabnikova, X. Y. Liu, and J. Y. Wang, “Digestion of frozen/thawed food waste in the hybrid anaerobic solid-liquid system,” Waste Management,vol.28,no.9,pp.1654–1659,2008. [102]X.Liu,W.Wang,X.Gao,Y.Zhou,andR.Shen,“Effectof thermal pretreatment on the physical and chemical properties of municipal biomass waste,” Waste Management,vol.32,no.2, pp. 249–255, 2012. [103] S. W. Kim, J. Y. Park, J. K. Kim et al., “Development of a modified three-stage methane production process using food wastes,” Applied Biochemistry and Biotechnology,vol.84–86,pp.731–741, 2000. [104] J. W. Lim and J.-Y. Wang, “Enhanced hydrolysis and methane yield by applying microaeration pretreatment to the anaerobic co-digestion of brown water and food waste,” Waste Management,vol.33,no.4,pp.813–819,2013.

BioMed Research International 17 [105] L. Neves, R. Oliveira, and M. M. Alves, “Co-digestion of cow manure, food waste and intermittent input of fat,” Bioresource Technology,vol.100,no.6,pp.1957–1962,2009. [106] S. G. Kim, “System for separation of oil and sludge from food waste leachate,” Korea Patent 10-2010-0053719. [107]C.-F.Chu,Y.-Y.Li,K.-Q.Xu,Y.Ebie,Y.Inamori,andH.-N. Kong, “A pH- and temperature-phased two-stage process for hydrogen and methane production from food waste,” InternationalJournalofHydrogenEnergy,vol.33,no.18,pp.4739–4746, 2008. [108] J.Massanet-Nicolau,R.Dinsdale,A.Guwy,andG.Shipley,“Use of real time gas production data for more accurate comparison of continuous single-stage and two-stage fermentation,” Bioresource Technology,vol.129,pp.561–567,2013. [109] Y. Koike, M.-Z. An, Y.-Q. Tang et al., “Production of fuel ethanol and methane from garbage by high-efficiency two-stage fermentation process,” Journal of Bioscience and Bioengineering, vol. 108, no. 6, pp. 508–512, 2009. [110] X. Hai-Lou, W. Jing-Yuan, and T. Joo-Hwa, “A hybrid anaerobic solid-liquid bioreactor for food waste digestion,” Biotechnology Letters,vol.24,no.10,pp.757–761,2002. [111] Y. Li, S. Y. Park, and J. Zhu, “Solid-state anaerobic digestion for methane production from organic waste,” Renewable and Sustainable Energy Reviews,vol.15,no.1,pp.821–826,2011. [112] L.Appels,J.Baeyens,J.Degrève, and R. Dewil, “Principles and potential of the anaerobic digestion of waste-activated sludge,” Progress in Energy and Combustion Science, vol.34,no.6,pp. 755–781, 2008. [113] O. P. Karthikeyan and C. Visvanathan, “Bio-energy recovery from high-solid organic substrates by dry anaerobic bioconversion processes: a review,” Reviews in Environmental Science and Bio/Technology,vol.12,no.3,pp.257–284,2013. [114] J. Guendouz, P. Buffière, J. Cacho, M. Carrère, and J.-P. Delgenes, “Dry anaerobic digestion in batch mode: design and operation of a laboratory-scale, completely mixed reactor,” Waste Management, vol. 30, no. 10, pp. 1768–1771, 2010. [115] L. Yang, F. Xu, X. Ge, and Y. Li, “Challenges and strategies for solid-state anaerobic digestion of lignocellulosic biomass,” Renewable and Sustainable Energy Reviews,vol.44,pp.824–834, 2015. [116] A. Abbassi-Guendouz, E. Trably, J. Hamelin et al., “Microbial community signature of high-solid content methanogenic ecosystems,” Bioresource Technology,vol.133,pp.256–262,2013. [117] J. Lindmark, E. Thorin, R. Bel Fdhila, and E. Dahlquis, “Problems and possibilities with the implementation of simulation and modeling at a biogas plant,” in Proceedings of the International Conference on Applied Energy (ICAE ’12), Suzhou, China, July 2012. [118] I. Angelidaki, L. Ellegaard, and B. K. Ahring, “A mathematical model for dynamic simulation of anaerobic digestion of complex substrates: focusing on ammonia inhibition,” Biotechnology and Bioengineering,vol.42,no.2,pp.159–166,1993. [119] S. Kalyuzhnyi, A. Veeken, and B. Hamelers, “Two-particle model of anaerobic solid state fermentation,” Water Science and Technology,vol.41,no.3,pp.43–50,2000. [120] D. J. Martin, L. G. A. Potts, and V. A. Heslop, “Reaction mechanisms in solid-state anaerobic digestion. I. The reaction front hypothesis,” Process Safety and Environmental Protection, vol.81,no.3,pp.171–179,2003. [121] D. J. Martin, “A novel mathematical model of solid-state digestion,” Biotechnology Letters,vol.22,no.1,pp.91–94,2000. [122] V.A.Vavilin,M.Y.Shchelkanov,andS.V.Rytov,“Effectofmass transfer on concentration wave propagation during anaerobic digestion of solid waste,” Water Research,vol.36,no.9,pp.2405– 2409, 2002. [123] V. A. Vavilin, L. Y. Lokshina, J. P. Y. Jokela, and J. A. Rintala, “Modeling solid waste decomposition,” Bioresource Technology, vol.94,no.1,pp.69–81,2004. [124] V. A. Vavilin, S. V. Rytov, L. Y. Lokshina, S. G. Pavlostathis, and M. A. Barlaz, “Distributed model of solid waste anaerobic digestion: effects of leachate recirculation and pH adjustment,” Biotechnology and Bioengineering,vol.81,no.1,pp.66–73,2003. [125] V. A. Vavilin and I. Angelidaki, “Anaerobic degradation of solid material: importance of initiation centers for methanogenesis, mixing intensity, and 2D distributed model,” Biotechnology and Bioengineering,vol.89,no.1,pp.113–122,2005. [126] V. A. Vavilin, L. Y. Lokshina, X. Flotats, and I. Angelidaki, “Anaerobic digestion of solid material: multidimensional modeling of continuous-flow reactor with non-uniform influent concentration distributions,” Biotechnology and Bioengineering, vol.97,no.2,pp.354–366,2007. [127] H. J. Eber, “Simulation of chemical reaction fronts in anaerobic digestion of solid waste,” in Proceedings of the Computational ScienceandItsApplications(ICCSA’03), pp. 503–512, Montreal, Canada, May 2003. [128] H. J. Eberl, “The role of spatio-temporal effects in anaerobic digestion of solid waste,” Nonlinear Analysis: Theory, Methods &Applications,vol.63,no.5–7,pp.e1497–e1505,2005. [129] A. Abbassi-Guendouz, D. Brockmann, E. Trably et al., “Total solids content drives high solid anaerobic digestion via mass transfer limitation,” Bioresource Technology, vol. 111, pp. 55–61, 2012. [130] J. Bollon, R. Le-Hyaric, H. Benbelkacem, and P. Buffiere, “Development of a kinetic model for anaerobic dry digestion processes: focus on acetate degradation and moisture content,” Biochemical Engineering Journal,vol.56,no.3,pp.212–218,2011. [131] F. Liotta, P. Chatellier, G. Esposito et al., “Modified Anaerobic Digestion Model No.1 for dry and semi-dry anaerobic digestion of solid organic waste,” Environmental Technology, vol.36,no. 5–8,pp.870–880,2015. [132] F. Xu, Z.-W. Wang, L. Tang, and Y. Li, “A mass diffusion-based interpretation of the effect of total solids content on solidstate anaerobic digestion of cellulosic biomass,” Bioresource Technology,vol.167,pp.178–185,2014. [133] S. Pommier, D. Chenu, M. Quintard, and X. Lefebvre, “A logistic model for the prediction of the influence of water on the solid waste methanization in landfills,” Biotechnology and Bioengineering,vol.97,no.3,pp.473–482,2007. [134] L. A. Fdez-Güelfo, C. Álvarez-Gallego, D. Sales, and L. I. Romero García, “Dry-thermophilic anaerobic digestion of organic fraction of municipal solid waste: methane production modeling,” Waste Management,vol.32,no.3,pp.382–388,2012. [135] J. Fernández, M. Pérez, and L. I. Romero, “Kinetics of mesophilic anaerobic digestion of the organic fraction of municipal solid waste: influence of initial total solid concentration,” Bioresource Technology,vol.101,no.16,pp.6322–6328, 2010. [136] L. N. Liew, J. Shi, and Y. Li, “Methane production from solidstate anaerobic digestion of lignocellulosic biomass,” Biomass and Bioenergy,vol.46,pp.125–132,2012. [137] D. Brown, J. Shi, and Y. Li, “Comparison of solid-state to liquid anaerobic digestion of lignocellulosic feedstocks for biogas production,” Bioresource Technology,vol.124,pp.379–386,2012.

Episode One

The Futurist (Haringey) - Episode 01 - 2018
Special Report: The flaws in Attainment 8 - Part 1
Food Waste to Energy: An Overview of Sustainable Approaches for Food Waste Management and Nutrient Recycling (BMRI2017-2370927)
EER and CREC Summer Event 2018 - uLearn Naturally Radio - Podcast
Home-School-Knowledge-Exchange (HSKE) Icon- (the neuron key)
Parent TEAMs for Raised Attainment - Project Introduction
Black Open University (BOU) Prospectus 2019-2020
Prospectus - Level Being 9 - The Best - The highest possible level - uLearn Naturally GCSE Mathematics
The Futurist (Haringey) magazine - advert rates info


© 2018 The Futurist: a STEAM'd uP3 Magazine

© 2018 uLearn Naturally Learners' Cooperative

© 2018 Abundance Centres (UK)

© 2018 Peoplescience Intelligence Unit