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Su ve Çevre Teknolojileri Dergisi 174. Sayı (Ocak 2023)

54 SU VE ÇEVRE TEKNOLOJİLERİ • Ocak / 2023 • Abu Ghunmi, L., Zeeman, G., Van Lier, J., Fayyed, M., (2008). Quantitative and qualitative characteristics of grey water for reuse requirements and treatment alternatives: The case of Jordan, Water Science and Technology, 58:7, 1385–1396. • Almeida, M. C., Butler, D., Friedler, E., (1999). At-source domestic wastewater quality, Urban Water, 1, 49–55. • AMSA (2000). Evaluation of Domestic Sources of Mercury, Association of Metropolitan Sewerage Agencies, Washington, DC. • ANZECC (2000). Australian Water Quality Guidelines for Fresh and Marine Waters, Canberra, Australian Capital Territory, Australia: Australian and New Zealand Environment and Conservation Council. • Atasoy, E., Murat, S., Baban, A., Tiris, M., (2007). Membrane Bioreactor (MBR) Treatment of Segregated Household Wastewater for Reuse, Clean Soil, Air, Water, 35, 465-472. • APHA. (2005) In: Standard Methods for the Examination of Water and Wastewater, Ed. A. D., Eaton, L. S., Clesceri, E. W., Rice, and A. E., Greenberg, 20th ed. Washington, DC: American Public Health Association. • Bani-Melhem, K., Smith, E., (2012). Grey water treatment by a continuous process of an electrocoagulation unit and a submerged membrane bioreactor system, Chemical Engineering Journal, 198- 199, 201-210. • Birks, R., ve Hills, S., (2007). Characterisation of indicator organisms and pathogens in domestic greywater for recycling, Environmental Monitoring and Assessment, 129:1–3, 61–69. • Donner, E., Eriksson, E., Revitt, D. M., Scholes, L., Lützhøft, H. C. H., Ledin, A., (2010). Presence and fate of priority substances in domestic greywater treatment and reuse systems, Sci. of the Total Environment, 408:12, 2444–2451. • Eriksson, E., ve Donner, E., (2009). Metals in greywater: Sources, presence and removal efficiencies, Desalination, 248:1–3, 271–278. • Eriksson, E., Auffarth, K., Henze, M., Ledin, A., (2002). Characteristics of grey wastewater, Urban Water 4:1, 85–104. • Eriksson, E., (2002). Potential and problems related to reuse of water in households. Ph.D. Thesis. Environment and Resources DTU, Technical University of Denmark, ISBN 87-89220-69-2. • Friedler, E., (2004). Quality of individual domestic greywater streams and its implication for on-site treatment and reuse possibilities, Environmental Technology, 25:9, 997–1008. • Friedler, E., Resnitsky, L., (2004). Study of Boron, Sodium and Chlorides Contribution of Domestic Dishwashers to Municipal Wastewater in Israel and Its Implication on Wastewater Reuse— Present Situation and Long Term Forecasting, Submitted to the Israeli Ministry of Environment, pp. 99 (Hebrew). • Friedler, E., (2008). The water saving potential and the socioeconomic feasibility of greywater reuse within the urban sector—Israel as a case study, International Journal of Environmental Studies, 65:1, 57–69. • Friedler, E., Hadari, M., (2006). Economic feasibility of on-site greywater reuse in multi-storey buildings, Desalination, 190, 221- 234. • Gilboa, Y., ve Friedler, E., (2008). UV disinfection of RBC-treated light greywater effluent: Kinetics, survival and regrowth of selected microorganisms, Water Research 42:4–5, 1043–1050. • Gross, A., Maimon, A., Alfiya, Y., Friedler, E., (2015). Greywater Reuse, Chapter 1. Greywater Characteristics, CRC Press, IWA Publishing. • Grey Water Recycling & Reuse, Towards a Sustainable Unitization of Domestic Water, (2011). Egyptian-German Private Sector Development Programme (PSDP), Editor: Dr. Wael Abdelmoez Mohamed, Cairo. • Humeau, P., Hourlier, F., Bulteau, G., Massé, A., Jaouen, P., Gérente, C., Faur, C., Le Cloirec, P., (2011). Estimated costs of implementation of membrane processes for on-site greywater recycling, Water Science and Technology, 63, 12. • Jabornig, S., Favero, E., (2013). Single household greywater treatment with a moving bed biofilm membrane reactor (MBBMR), J. of Mem. Sci., 446, 277-285. • Jefferson, B, Palmer, A, Jeffrey, P, Stuetz, R, Judd, S., (2004). Grey water characterisation and its impact on the selection and operation of technologies for urban reuse, Water Science and Technology, 50:2, 157–164. • Jong, J., Lee, J., Kim, J., Hyun, K., Hwang, T., Park, J., Choung, Y., (2010) The study of pathogenic microbial communities in graywater using membrane bioreactor, Desaliantion, 250, 568-572. • Kennedy, M. D., Kamanyi, J., Salinas-Rodriguez, S. G., Lee, N. H., Schippers, J. C., Amy, G., (2008). Water treatment by microfiltration and ultrafiltration. In: Advanced Membrane Technology and Applications, Ed. Li, N. N., Fane, A. G., W Ho, W. S. W., Matsuura, T., Hoboken, N. J., John Wiley & Sons. • Kraume, M., Scheumann, R., Baban, A., Elhamouri, B., (2010). Performance of a compact submerged membrane sequencing batch reactor (SM-SBR) for greywater treatment, Desalination, 250, 1011- 1013. • Leiknes, T., ve Ødegaard, H., (2007). The development of a biofilm membrane bioreactor, Desalination, 202, 135-143. • Lesjean , B., ve Gnirss, R., (2006). Grey water treatment with a membrane bioreactor operated at low SRT and low HRT, Desalination, 199, 432 – 434. • Lesjean, B., ve Huisjes, E.H., (2008). Survey of the European MBR market: trends and perspectives, Desalination, 231, 71-81. • Li, F., (2009). Treatment of household grey water for non-potable reuses, PhD thesis, Hamburg University of Technology. • Li, F., Wichmann, K., Otterpohl, R., (2009). Review of the technological approaches for grey water treatment and reuses, Science of the Total Environment, 407, 3439-3449. • Ludwing, A., (2000). A Compendium of greywater mistakes and misinformation on the web. • Meinzinger, F. ve Oldenburg, M., (2009). Characteristics of sourceseparated household wastewater flows: A statistical assessment, Water Science and Technology, 59:9, 1785–1791. • Merz, C., Scheumann, R., Elhamouri, B, Kraume, M., (2007).Membrane bioreactor technology for the treatment of greywater from a sports and leisure club, Desalination, 215, 37-43. • Metcalf ve Eddy, (2003). Wastewater Engineering: Treatment and Reuse, Ed. Tchobanoglous, G., Burton, F. L., Stensel, H. D., New York: McGraw- Hill. • Morel, A. ve Diener, S., (2006). Greywater Management—in Low and Middle-Income Countries. Sandec (Water and Sanitation in Developing Countries) at Eawag (Swiss Federal Institute of Aquatic Science and Technology), Vol. 14/06. • Nolde, E., (2000). Grey water reuse systems for toilet flushing in multi- storey buildings-over ten years of experience in Berlin, Urban Water, 1, 275-284. • Nolde, E., (1996). Greywater Reuse in Households-Experience from Germany. In J. Staudenmann, A. Schönborn, & C. Etnier (Eds.), Proceedings of the Second International Conference on Ecological Engineering for Wastewater Treatment. Environmental Research Forum Volumes 5–6, In Recycling the Resource–Ecological Engineering for Wastewater Treatment (pp. 55–64), September 18– 22, 1995, Wädenswil, Zürich, Switzerland. • Paris, S., Schlapp, C., (2010). Greywater recycling in Vietnam- Application of the HUBER MBR process, Desalination, 250, 1027- 1030. • Ramon, G., Green, M., Semiat, R., Dosoretz, C., (2004). Low strength graywater characterization and treatment by direct membrane filtration, Desalination 170:3, 241–250. • Santasmanas, G., Rovira, M., Clarens, F., Valderrama, C., (2013). Grey water reclamation by decentralized MBR prototype, Resources, Conservation and Recycling, 72, 102-107. • Salvato J.A., (1992.) Environmental Engineering and Sanitation, 4th edn. Wiley, New York. • Salvato J.A., (1994). Environmental Engineering and Sanitationsupplement 4th edn. Wiley, New York. • <URL>: MBR Atıksu Arıtma Sistemleri Ltd, (2017). http://www. mbraritma.com.tr/files/Hilton.pdf , 05.12.2017. Kaynaklar MAKALE

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