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Using Sawdust to Treat Synthetic Municipal Wastewater and Its Consequent Transformation Into Biogas

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Warianty tytułu
Języki publikacji
EN
Abstrakty
EN
Sawdust, as an agricultural waste which is highly efficient, readily available, and relatively inexpensive, has the potential to be an applicable alternative adsorbent for the total organic carbon (TOC) removal from synthetic domestic wastewater. This study aims firstly to investigate the feasibility of sawdust as a new adsorbent and understand its adsorption mechanism for TOC. The impact of particle size, pH, contact time, and temperature has been evaluated as the controlling factors on the adsorption process. The results presented that the removal efficiency rose with the decrease of particle size, pH, and temperature, as well as the increase of the contact time. The maximum adsorption was obtained at particle size of 0.05 mm, pH of 1, contact time of 1.5 h, and temperature of 15°C, respectively. The second aim of this study is to utilize the sawdust that is used in the adsorption process as biomass in batch anaerobic digestion (AD) to produce methane. Spent sawdust was characterized by the methane production which was 5.9 times greater than in the case of raw sawdust. Four operating parameters were checked, Carbon/Nitrogen ratio (C/N), inoculation, particle size, and total solid (TS) content. The batch results indicated that the optimum parameters were: 20%, 30%, 2 mm, and 15%, respectively.
Rocznik
Strony
10--18
Opis fizyczny
Bibliogr. 28 poz., rys., tab.
Twórcy
autor
  • Environmental Engineering Department, Faculty of Engineering, Al-Mustansiryiah University, Baghdad, Iraq
Bibliografia
  • 1. Agyeman, F.O., Tao, W. 2014. Anaerobic co-digestion of food waste and dairy manure: Effects of food waste particle size and organic loading rate. Journal of Environmental Management, 133, 268–274.
  • 2. Ahn, Y., Logan, B.E. 2010. Effectiveness of domestic wastewater treatment using microbial fuel cells at ambient and mesophilic temperatures. Bioresource technology, 101(2), 469–475.
  • 3. Benetti, A.D. 2008. Water reuse: issues, technologies, and applications. Engenharia Sanitaria e Ambiental, 13(3), 247–248.
  • 4. Castoldi, R., Correa, V.G., de Morais, G.R., de Souza, C.G., Bracht, A., Peralta, R.A., Moreira, R.F.P.-M., Peralta, R.M. 2017. Liquid nitrogen pretreatment of eucalyptus sawdust and rice hull for enhanced enzymatic saccharification. Bioresource technology, 224, 648–655.
  • 5. Dai, X., Duan, N., Dong, B., Dai, L. 2013. Highsolids anaerobic co-digestion of sewage sludge and food waste in comparison with mono digestions: Stability and performance. Waste Management, 33(2), 308–316.
  • 6. De la Rubia, M.A., Fernández-Cegrí, V., Raposo, F., Borja, R. 2011. Influence of particle size and chemical composition on the performance and kinetics of anaerobic digestion process of sunflower oil cake in batch mode. Biochemical Engineering Journal, 58–59(0), 162–167.
  • 7. Dechrugsa, S., Kantachote, D., Chaiprapat, S. 2013. Effects of inoculum to substrate ratio, substrate mix ratio and inoculum source on batch codigestion of grass and pig manure. Bioresource Technology, 146, 101–108.
  • 8. El-Naas, M.H., Al-Zuhair, S., Alhaija, M.A. 2010. Reduction of COD in refinery wastewater through adsorption on date-pit activated carbon. Journal of Hazardous Materials, 173(1–3), 750–757.
  • 9. Federation, W.E., Association, A. 2005. Standard methods for the examination of water and wastewater. American Public Health Association (APHA): Washington, DC, USA.
  • 10. Ghaedi, M., Sadeghian, B., Pebdani, A.A., Sahraei, R., Daneshfar, A., Duran, C. 2012. Kinetics, thermodynamics and equilibrium evaluation of direct yellow 12 removal by adsorption onto silver nanoparticles loaded activated carbon. Chemical Engineering Journal, 187, 133–141.
  • 11. Gupta, V., Agarwal, A., Singh, M. 2015. Belpatra (aegel marmelos) bark powder as an adsorbent for the color removal of textile dye "torque blue". Int J Sci Eng Tech, 4(2), 56–60.
  • 12. Haider, M.R., Zeshan, Yousaf, S., Malik, R.N., Visvanathan, C. 2015. Effect of mixing ratio of food waste and rice husk co-digestion and substrate to inoculum ratio on biogas production. Bioresource Technology, 190(0), 451–457.
  • 13. Huerta-Fontela, M., Galceran, M.T., Ventura, F. 2011. Occurrence and removal of pharmaceuticals and hormones through drinking water treatment. Water research, 45(3), 1432–1442.
  • 14. Katsoyiannis, A., Samara, C. 2005. Persistent organic pollutants (POPs) in the conventional activated sludge treatment process: fate and mass balance. Environmental Research, 97(3), 245–257.
  • 15. Kazemi, S.Y., Biparva, P., Ashtiani, E. 2016. Cerastoderma lamarcki shell as a natural, low cost and new adsorbent to removal of dye pollutant from aqueous solutions: Equilibrium and kinetic studies. Ecological Engineering, 88, 82–89.
  • 16. Khamparia, S., Jaspal, D. 2016. Investigation of adsorption of Rhodamine B onto a natural adsorbent Argemone mexicana. Journal of Environmental Management, 183, Part 3, 786–793.
  • 17. Kimming, M., Sundberg, C., Nordberg, Å., Baky, A., Bernesson, S., Norén, O., Hansson, P.-A. 2011. Biomass from agriculture in small-scale combined heat and power plants–a comparative life cycle assessment. Biomass and bioenergy, 35(4), 1572–1581.
  • 18. Liu, Q., Liu, Q., Ma, W., Liu, W., Cai, X., Yao, J. 2016. Comparisons of two chelating adsorbents prepared by different ways for chromium (VI) adsorption from aqueous solution. Colloids and Surfaces A: Physicochemical and Engineering Aspects, 511, 8–16.
  • 19. Lizasoain, J., Rincón, M., Theuretzbacher, F., Enguídanos, R., Nielsen, P.J., Potthast, A., Zweckmair, T., Gronauer, A., Bauer, A. 2016. Biogas production from reed biomass: Effect of pretreatment using different steam explosion conditions. Biomass and Bioenergy, 95, 84–91.
  • 20. Mor, S., Chhoden, K., Ravindra, K. 2016. Application of agro-waste rice husk ash for the removal of phosphate from the wastewater. Journal of Cleaner Production, 129, 673–680.
  • 21. Rickert, D.A., Hunter, J.V. 1971. General nature of soluble and particulate organics in sewage and secondary effluent. Water Research, 5(7), 421–436.
  • 22. Shukla, P., Fatimah, I., Wang, S., Ang, H., Tadé, M.O. 2010. Photocatalytic generation of sulphate and hydroxyl radicals using zinc oxide under lowpower UV to oxidise phenolic contaminants in wastewater. Catalysis Today, 157(1), 410–414.
  • 23. Speece, R.E. 2007. Anaerobic biotechnology and odor/corrosion control for municipalities and industries. Nashville (Ten.) : Archae press.
  • 24. Yang, H.I., Lou, K., Rajapaksha, A.U., Ok, Y.S., Anyia, A.O., Chang, S.X. 2017. Adsorption of ammonium in aqueous solutions by pine sawdust and wheat straw biochars. Environmental Science and Pollution Research, 1–10.
  • 25. Yen, H.-W., Brune, D.E. 2007. Anaerobic co-digestion of algal sludge and waste paper to produce methane. Bioresource Technology, 98(1), 130–134.
  • 26. Yi, J., Dong, B., Jin, J., Dai, X. 2014. Effect of increasing total solids contents on anaerobic digestion of food waste under mesophilic conditions: performance and microbial characteristics analysis. PloS one, 9(7), e102548.
  • 27. Yin, C.Y., Aroua, M.K., Daud, W.M.A.W. 2007. Review of modifications of activated carbon for enhancing contaminant uptakes from aqueous solutions. Separation and Purification Technology, 52(3), 403–415.
  • 28. Zhang, Y., Banks, C.J. 2013. Impact of different particle size distributions on anaerobic digestion of the organic fraction of municipal solid waste. Waste Management, 33(2), 297–307.
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-45861dc4-35a0-40c3-a6e4-86ee544ebfd1
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