Phosphorus consumption. From linear to circular flow

IF 2.4 Q3 CHEMISTRY, MULTIDISCIPLINARY Moroccan Journal of Chemistry Pub Date : 2020-07-02 DOI:10.48317/IMIST.PRSM/MORJCHEM-V8I4.20652
V. Nenov, G. Peeva, H. Yemendzhiev, M. Stancheva, F. Zerrouq
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引用次数: 3

Abstract

Wastewater and waste sludge are generated in all parts of the world during domestic and industrial activities. Conventional wastewater treatment methods generate a highly concentrated municipal sludge, which needs to be disposed of effectively without leading to secondary pollution. Animal manure and post generated manure wastewater are another environmental concern. Both of the above wastewater and sludge/manure are rich in organic/inorganic forms of carbon, nitrogen (N) and phosphorus (P). Anthropogenic and industrial activities in the global biogeochemical cycles have resulted in a drastic one-way mobilization of these resources into the atmosphere and the environment. The current intensive agriculture requires huge quantities of nitrogen (N) and Phosphorus (P) containing fertilizers. The industrial production of ammonia and nitrates is quite energy demanding; however, nitrogen is abundantly present in the nature and therefore it is a non-restricted resource for nitrogen derivate production. Unlike nitrogen, P can be obtained primarily from mineral deposits available only in few geographic locations. The phosphate rock reserves are finite and the current intensive fertilizer production based on economically mined rocks could last only another 50-100 years. Since phosphates are available only in limited geographic locations and the recognition that geologic phosphates are a non-renewable resource, Phosphorus recovery becomes a crucial for sustainable food production as EU depends for 90% on import of phosphate rocks (European Commission 2017). Within the EU only Finland has some phosphate rocks. The list of supplying countries is quite short; more than 70% of the present known global reserves of phosphate rock are located in Morocco as of all mined and processed phosphate rock (2009).  Phosphorus, being a finite resource with deficits starting approximately from the year 2070 due to increased demand might also result in high prices and reliance on single point sources, giving them monopoly over the market. The EU phosphorus flows show that the main losses of phosphorus in the food sector are through sewage sludge, other waste water and food waste. In general, phosphorus can be recycled, mainly from wastewater (e.g. sewage water), manure and organic waste (e.g. wasted food). Thus, wastewater can be considered as a renewable source of N and P. Instead of releasing the N and P rich wastewater into coastal and inland waters increasing eutrophication risk their utilization can be beneficial resulting in multiple benefits like nutrient recovery, water reclamation for reuse and maintenance of ecological balance in aquatic systems. Presently, the recovery and reuse of P is still far from being a main stream practice. Yet, the techniques already accepted and applied differ by the origin of the used matter (wastewater, sludge, ash) are mainly focused on the process of precipitation. One of these techniques is struvite precipitation, which can be implemented in wastewater treatment plants that use enhanced biological or semi biological/chemical phosphorus removal. Struvite (magnesium ammonium phosphate or MAP (MgNH4PO4·6H2O)) is formed by a basic precipitation reaction in different stages of the wastewater treatment process where magnesium (Mg 2+ ), ammonium (NH4 + ) and orthophosphate (PO4 −3 ). The article discusses the progress in extracting P from sewage sludge and animal manure, the conditions to create optimal conditions for struvite precipitation in such media and the way to overcome the problems associated with choosing the right Mg source, pH adjustment and the non-acceptable level of organic matter in the initial suspension.
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磷消耗量。从线性流到圆形流
在世界各地的生活和工业活动中都会产生废水和废污泥。传统的污水处理方法会产生高度浓缩的城市污泥,需要在不造成二次污染的情况下对其进行有效处理。动物粪便和粪便后产生的废水是另一个环境问题。上述废水和污泥/粪肥都富含有机/无机形式的碳、氮(N)和磷(P)。全球生物地球化学循环中的人为和工业活动导致了这些资源向大气和环境的剧烈单向调动。目前的集约农业需要大量的含氮(N)和含磷(P)肥料。氨和硝酸盐的工业生产对能源的要求相当高;然而,氮在自然界中大量存在,因此它是氮衍生物生产的非限制性资源。与氮不同,磷主要可以从只有少数地理位置的矿床中获得。磷矿储量有限,目前以经济开采的磷矿为基础的集约化肥生产只能再持续50-100年。由于磷酸盐仅在有限的地理位置可用,并且认识到地质磷酸盐是一种不可再生资源,磷回收对可持续粮食生产至关重要,因为欧盟90%的磷矿石依赖进口(欧盟委员会,2017年)。在欧盟内部,只有芬兰拥有一些磷矿石。供应国名单很短;目前已知的全球磷矿储量中,超过70%位于摩洛哥(2009年)。磷是一种有限的资源,由于需求的增加,大约从2070年开始就会出现赤字,这也可能导致高价格和对单点来源的依赖,从而垄断市场。欧盟的磷流量表明,食品部门磷的主要损失是通过污泥、其他废水和食品垃圾。一般来说,磷可以回收,主要来自废水(如污水)、粪肥和有机废物(如废弃食品)。因此,废水可以被视为氮磷的可再生来源。与其将富含氮磷的废水排放到沿海和内陆水域,增加富营养化风险,不如对其进行有益的利用,从而带来营养回收、水资源再生利用和维持水系统生态平衡等多重效益。目前,磷的回收和再利用还远远不是主流做法。然而,已经接受和应用的技术因使用物质(废水、污泥、灰烬)的来源而异,主要集中在沉淀过程上。其中一种技术是鸟粪石沉淀,可以在使用强化生物或半生物/化学除磷的废水处理厂中实施。Struite(磷酸铵镁或MAP(MgNH4PO4·6H2O))是在废水处理过程的不同阶段通过碱性沉淀反应形成的,其中镁(Mg2+)、铵(NH4+)和正磷酸盐(PO4−3)。本文讨论了从污泥和动物粪便中提取磷的进展,在这种介质中创造鸟粪石沉淀最佳条件的条件,以及克服与选择合适的镁源、pH调节和初始悬浮液中有机物含量不合格有关的问题的方法。
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来源期刊
Moroccan Journal of Chemistry
Moroccan Journal of Chemistry CHEMISTRY, MULTIDISCIPLINARY-
CiteScore
3.40
自引率
9.10%
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0
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