Phosphorus cycle - possibilities for its rebuilding

• Autorzy: Gorazda K. , Wzorek Z. , Tarko B. , Nowak A. K. , Kulczycka J. , Henclik A.
• Języki publikacji: EN

Abstrakty

EN

 The rebuilding of the phosphorus cycle can be performed with the use of both biotechnology and chemical technology. This paper presents a review of the phosphorus cycle and the different approaches that can be taken to the recovery of phosphorus from phosphate-rich waste. Critical issues in the phosphorus cycle are also discussed. Methods for the recovery of phosphorus form sewage sludge ash are widely explored and divided into two groups: wet extraction methods and thermochemical methods. Laboratory-scale methods are described, as well as proposed industrial technologies, with particular regard to the possibilities for their implementation in Poland. Phosphorus recovery methods from SSA (sewage sludge ash) in our country seems to be promising due to the increasing number of sewage sludge incineration plants, which could easily supply ash to future recovery installations. For the effective recovery of P from sewage sludge ash, it is essential to make the right choice in determining the appropriate method to use with respect to the particular properties of the ash composition; available. A patented method of phosphorus recovery by acid extraction methods, developed by Cracow University of Technology, results in an efficiency of 80-96% for phosphorus recovery. 3000 to 4000 tons of phosphorus per year can be recycled and introduced back into the environment, that covers around 7% of the total amount of phosphorus ore imported into Poland between 2008 and 2009.

• Wydawca: -
• Czasopismo: Acta Biochimica Polonica
• Rocznik: 2013
• Tom: 60
• Numer: 4
• Opis fizyczny: p.725-730,ref.

Twórcy

autor

Gorazda K.

• Cracow University of Technology, Krakow, Poland, Institute of Chemistry and Inorganic Technology

autor

Wzorek Z.

• Cracow University of Technology, Krakow, Poland, Institute of Chemistry and Inorganic Technology

autor

Tarko B.

• Cracow University of Technology, Krakow, Poland, Institute of Chemistry and Inorganic Technology

autor

Nowak A. K.

• Cracow University of Technology, Krakow, Poland, Institute of Chemistry and Inorganic Technology

autor

Kulczycka J.

• AGH University of Science and Technology, Krakow, Poland

autor

Henclik A.

• The Mineral and Energy Economy Research Institute of the Polish Academy of Sciences, Krakow, Poland

Bibliografia

• Adam C, Peplinski B, Michaelis M, Kley G, Simon F (2009) Termochemical treatment of sewage sludge ashes for phosphorus recovery. Waste Manag 29: 1122-1128. 
• Adeola O, Cowieson AJ (2011) Opportunities and challenges in using exogenous enzymes to improve nonruminant animal production. J Anim Sci 89: 3189-3218. 
• Biswas BK, Inoue K, Harada H, Ohto K, Kawakita H (2009) Leaching of phosphorus from incinerated sewage sludge ash by means of acid extraction followed by adsorption on orange waste gel. J Environ Sci 21: 1753-1760. 
• Blank LM (2012) The cell and P: from cellular function to biotechnological application. Curr Opin Biotechnol 23: 846-851. 
• Blöcher C, Niewersch C, Melin T (2012) Phosphorus recovery from sewage sludge with a hybrid process of low pressure wet oxidation and nanofiltration. Water Res 46: 2009-2019. 
• Bradford-Hartke Z, Lant P, Leslie G (2012) Phosphorus recovery from centralised municipal water recycling plants. Chem Eng Res Des 90: 78-85.
• Clift R, Shaw H (2012) An Industrial Ecology Approach to the Use of Phosphorus. Proc Eng 46: 39-44.
• Cordell D, Drangert JO, White S (2009) The story of phosphorus: global food security and food for thought. Glob Environ Change 19: 292-305.
• Dittrich C, Rath W, Montag D, Pinnekamp J (2009) Phosphorus recovery from sewage sludge ash by a wet-chemical process, In: International Conference on Nutrient Recovery from Wastewater Streams, IWA Publishing, London, England.
• Donatello S, Tong D, Cheeseman C R (2010) Production of technical grade phosphoric acid from incinerator sewage sludge ash (ISSA). Waste Manag 30: 1634-1642. 
• EEA - European Environment Agency (2011) "Resource efficiency in Europe - Policies and approaches in 31 EEA member and cooperating countries", EEA Report n°5/2011, October 2011.
• Elser JJ (2012) Phosphorus: a limiting nutrient for humanity? Curr Opin Biotechnol 23: 833-838. 
• Franz M (2008) Phosphate fertilizer from sewage sludge ash (SSA). Waste Manag 28: 1809-1818. 
• Fytili D, Zabaniotou A (2008) Utilization of sewage sludge in EU application of old and new methods: a review. Renew Sustain Energy Rev 12: 116-140.
• GSMiE PAN (2011) Bilans Gospodarki Surowcami Mineralnymi Polski i Świata, Wydawnictwo: Instytutu GSMiE PAN Kraków 2011.
• Gorazda K, Kowalski Z, Wzorek Z (2010) phosphorus recovery from industrial waste, PL Patent No. 207457.
• Gorazda K, Kowalski Z, Wzorek Z (2012) From sewage sludge ash to calcium phosphate fertilizers. Pol J Chem Technol 14: 54-58.
• Gorazda K, Jodko M, Kowalski Z, Wzorek Z (2010) PL Patent No. 207630 B1, Republic of Poland Patent and Trademark Office.
• Gorazda K, Jodko M, Kowalski Z, Wzorek Z (2012) PL Patent No. 210459 B1, Republic of Poland Patent and Trademark Office.
• Gorazda K, Wzorek Z (2006) Selection of leaching agent for phosphorus compounds extraction from the sewage sludge ash. Pol J Chem Technol 8: 15-18.
• GUS (2012) Main Statistical Office, Environmental Protection, Warszawa 2012.
• Heffer P, Prud'homme M, Muirhead B, Isherwood K (2006) Phosphorus fertilisation: issues and outlook. Proceedings International Fertiliser Society 586. 30 pp. York, UK,
• Hutnik N, Kozik A, Mazienczuk A, Piotrowski K, Wierzbowska B, Matynia A (2013) Phosphates (V) recovery from phosphorus mineral fertilizers industry wastewater by continuous struvite reaction crystallization process. Water Res 47: 3635-3643. 
• IFDC (2010) Sufficient phosphate rock resources Available for years. International Fertilizer Development Center, Muscle Shoals, AL 35662, USA. Report 35: 1.
• Jasinski SM (2010) Phosphate Rock In: Mineral Commodity Summaries, U.S. Geological Survey, United States Government Printing Office, Washington.
• Jasinski SM (2012) Phosphate rock. In: US Geological Survey, editor. Mineral commodity summaries. pp 118-119. USGS.
• Kelessidis A, Stasinakis AS (2012) Comparative study of the methods used for treatment and final disposal of sewage sludge in European countries. Waste Manag 32: 1186-1195. 
• Kodera H, Hatamoto M, Abe K, Kindaichi T, Ozaki N, Ohashi A (2013) Phosphate recovery as concentrated solution from treated wastewater by a PAO-enriched biofilm reactor. Water Res 47: 2025-2032. 
• Lapa N, Barbosa R, Mendes B, Abelha P, Gulyurtlu I, Oliveira S (2007) Chemical and ecotoxicological characterization of ashes obtained from sewage sludge combustion in a fluidised-bed reactor. J Hazard Mater 147: 175-183. 
• Li B, Brett MT( 2013) The influence of dissolved phosphorus molecular form on recalcitrance and bioavailability. Environ Pollut 182: 37-44. 
• Mattenberger H, Fraissler G, Jöller M, Brunner T, Obernberger I, Herk P, Hermann L (2010) Sewage sludge ash to phosphorus fertilizer (II): Influences of ash and granulate type on heavy metal removal. Waste Manag 30: 1622-1633. 
• Morse GK, Lester JN, Perry R (1993) The economic and environmental impact of phosphorus removal from wastewater in the European Community. Selpher Publications, London, 1993.
• Nieminen J (2010) Phosphorus recovery and recycling from municipal wastewater sludge. A Master of Sciences dissertation. Aalto University School of Science and Technology, Aalto, Finland.
• Nzihou A, Stanmore B (2013) The fate of heavy metals during combustion and gasification of contaminated biomass - A brief review. J Hazard Mater 256: 56-66. 
• Nowak B, Rocha SF, Aschenbrenner H, Winter F (2012) Heavy metal removal from MSW fly ash by means of chlorination and thermal treatment: Influence of the chloride type. Chem Eng J 179: 178-185.
• Petzet S, Cornel P (2012) Prevention of struvite scaling in digesters combined with phosphorus removal and recovery- the FIX-Phos process. Water Environ Res 84: 220-226. 
• Petzet S, Peplinski B, Cornel P (2012) On wet chemical phosphorus recovery from sewage sludge ash by acid or alkaline leaching and an optimized combination of both. Water Res 46: 3769-3780. 
• Raj SE, Banu PJ, Kaliappan S, Yeom IT, Kumar AS (2013) effects of side-stream, low temperature phosphorus recovery on the performance of anaerobic/anoxic/oxic systems integrated with sludge pretreatment. Bioresour Technol 140: 376-384. 
• Ridoutt GB, Wand E, Sanguansri P, Luo Z (2013) Life cycle assessment of phosphorus use efficient wheat grown in Australia. Agric Syst 120: 2-9.
• Rittmann BE, Mayer B, Westerhoff P, Edwards M (2011) Capturing the lost phosphorus. Chemosphere 84: 846-853. 
• Sano A, Kanomata M, Inoue H, Sugiura N, Xu KQ, Inamori Y (2012) Extraction of raw sewage sludge containing iron phosphate for phosphorus recovery. Chemosphere 89: 1243-1247. 
• Sengupta S, Pandit A (2011) Selective removal of phosphorus from wastewater combined with its recovery as a solid-phase fertilizer. Water Res 45: 3318-3330. 
• Schaum C, Cornel P, Norbert J (2013) Phosphorus Recovery from Sewage Sludge Ash - A Wet Chemical Approach. Retrieved 11 March, 2013, from:  http://www.bvsde.paho.org/bvsaar/cdlodos/pdf/phosphorusrecovery583.pdf.
• Schipper WJ, Klapwijk A, Potjer B, Rulkens WH, Temmink BG, Kiestra FDG, Lijmbach ACM (2001) Phosphate recycling in the phosphorus industry. Environ Technol 22: 1337-1345. 
• Scholz RW, Ulrich AE, Eilittä M, Roy A (2013) Sustainable use of phosphorus: A finite resource. Sci Total Environ 461: 799-803. 
• Scholz RW, Wellmer FW (2013) Approaching a dynamic view on the availability of mineral resources: what we may learn from the case of phosphorus? Glob Environ Change 23: 11-27.
• Schroder JJ, Cordell D, Smit AL, Rosemarin A. (2009) Sustainable use of phosphorus, European Union tender project ENV.B.1/ETU/2009/0025). Report 357, Plant Research International, Wageningen University and Research Centre. 122 pp. Wageningen, The Netherlands.
• Schröder JJ, Verloop J (2010) Slurry separation could allow a wider use of manure within the EU Nitrates Directive. In: Proceedings Ramiran 2010 Conference, Cordovil C, Ferreira L, eds. Lisboa, Portugal, Lissabona.
• SPIRIT21 (2007) Sewege Technology Development Project (LOTUS Project), (2007). Zero Sludge Discharge Technology, Technology Evaluation concerning Phosphorus Recovery from Sewage Sludge Incinerator Ash, from:  http://nett21.gec.jp/rerss/reports/rp02.pdf.
• Stark K, Plaza E, Hultman B (2006) Phosphorus release from ash, dried sludge and sludge residue from supercritical water oxidation by acid or base. Chemosphere 62: 827-832. 
• Steen I (1988) Phosphorus availability in the 21st century: Management of a non-renewable resources. Phosphorus and Potassium 217: 25-31.
• Tan Z, Lagerkvist A (2011) Phosphorus recovery from the biomass ash. A review. Renew Sust Energ Rev 15: 3588-3602.
• Tian J, Wang X, Tong Y, Chen X, Liao H (2012) Bioengineering and management for efficient phosphorus utilization in crops and pastures. Curr Opin Biotechnol 23: 866-871. 
• Technological Foresight (2011) Scenariusze i rekomendacje, grudzień 2011  http://www.inorganicwaste.eu/.
• Tyagi VK, Lo SL (2013) Sludge: A waste or renewable source for energy and resources recovery?. Renew Sustain Energy Rev 25: 708-728.
• Wong PY, Cheng KY, Kaksonen AH, Sutton DC, Ginige MP (2013) A novel post denitrification configuration for phosphorus recovery using polyphosphate accumulating organisms, Water Res http://dx.doi.org/10.1016/j.watres.2013.08.023 (in press). 
• Yan P, Ji F, Wang FJ, Guan W, Chen Q (2013) Pilot-scale test of an advanced, integrated wastewater treatment process with sludge reduction, inorganic solids separation, phosphorus recovery, and enhanced nutrient removal (SIPER). Bioresour Technol 142: 483-489.