水产养殖尾水除磷技术研究进展

李贤; 田文静; 张翔宇; 徐文杰; 李晓林; 马腾; 田诚

引用本文:

【打印本页】【HTML】【下载PDF全文】【View/Add Comment】【EndNote】【RefMan】【BibTex】

←前一篇|后一篇→

过刊浏览高级检索

本文已被：浏览 60次下载 13次	码上扫一扫！
分享到：微信更多字体:加大+\|默认\|缩小-
水产养殖尾水除磷技术研究进展
李贤¹, 田文静², 张翔宇³, 徐文杰⁴, 李晓林⁵, 马腾⁶, 田诚⁷
1.中国海洋大学水产学院山东青岛 266003;2.中国海洋大学水产学院山东青岛 266004;3.中国海洋大学水产学院山东青岛 266005;4.中国海洋大学水产学院山东青岛 266006;5.山东寿光检测集团有限公司山东潍坊 262799;6.日照市海洋与渔业研究院山东日照 276827;7.日照经济技术开发区海洋发展服务中心山东日照 276826

摘要:

磷是构成生命体的必需元素，在生物生长过程中发挥着重要作用，然而水体中磷元素浓度超标易导致水体富营养化和蓝藻水华等问题，影响生态环境和经济发展。在“大食物观”背景下，水产养殖的绿色发展尤为重要，如何妥善处理养殖尾水中高浓度氮、磷营养盐，实现尾水磷达标排放或资源化利用已引起广泛重视。本文首先通过VOSviewer文献可视化软件的关键词贡献分析了近10年水产养殖尾水除磷技术的研究现状，详细介绍了水体中磷的赋存形态分类，阐述了国内外水产养殖尾水除磷技术分类、工作原理和研究进展，分析各个除磷技术的优缺点；同时针对现行水产养殖工艺的尾水磷处理方法进行了总结与展望。本文统领分析了水产养殖尾水除磷原理及工艺技术，可为尾水磷处理和资源回收提供新思路，推动水产养殖可持续发展。

关键词: 磷赋存形态水产养殖尾水循环水养殖除磷方法

DOI：10.19663/j.issn2095-9869.20241016002

分类号:

基金项目:山东省重点研发计划-重大科技创新工程项目(2023CXGC010410)资助

Research progress on water body phosphorus removal technology based on aquaculture tail water treatment

LI Xian¹, TIAN Wenjing², ZHANG Xiangyu³, XU Wenjie⁴, LI Xiaolin⁵, MA Teng⁶, TIAN Cheng⁷

1.Fisheries College, Ocean University of China, Qingdao 266003, China;2.Fisheries College, Ocean University of China, Qingdao 266004, China;3.Fisheries College, Ocean University of China, Qingdao 266005, China;4.Fisheries College, Ocean University of China, Qingdao 266006, China;5.Shandong Shouguang Collective Inspection Group Company, Weifang 262799, China;6.Rizhao Ocean and Fishery Research Institute, Rizhao 276827, China;7.Rizhao Economic and Technological Development Zone Development Service Center, Rizhao 276826, China

Abstract:

Phosphorus is an essential element for plants, animals, and other living organisms. The lack of phosphorus in aquatic environments can restrict primary productivity, a concern that has increasingly attracted global attention. However, the high phosphorus concentration leads to the eutrophication of water bodies, impacting human activities, compromising water quality, and causing notable economic losses. Therefore, studies on phosphorus removal and the recovery of phosphorus resources are important. In 2023, 27.3% of China’s important fishery waters in inland rivers exceeded the total phosphorus standard. The area of marine natural important fishery waters that exceeded the standard for reactive phosphate was 27.0%, and the area of seawater key aquaculture areas that exceeded the standard for reactive phosphate was 28.2%,. Aquaculture development is particularly important in the context of the ‘Big Food Concept’. The China’s total aquatic product output in 2023 was 71.16 million tons, an increase of 4.39% year-on-year, of which aquaculture production accounted for 81.6%. From 2022 to 2024, China’s provinces and municipalities introduced the aquaculture tail water discharge standard. For example, Shandong Province has implemented DB37 4676-2023, which sets a total phosphorus primary discharge limit of 0.7 mg/L and a secondary discharge limit of 1.0 mg/L. Recently, the rapid development of aquaculture tailwater phosphorus removal technology and phosphorus recovery technology based on physical, chemical, biological and ecological methods has provided strong support for aquaculture tailwater phosphorus removal and recycling. The current aquaculture tailwater phosphorus removal technology has made some progress. However, the advanced removal of phosphorus from the tailwater and phosphorus recovery technology requires further investigation. Enhancing the advanced removal of aquaculture tailwater is essential to ensure the sustainable development of aquaculture. This study classified the phosphorus in the water, examined the principle and current status of aquaculture tailwater phosphorus removal technology, and reviewed the application of phosphorus removal in the tailwater of the current aquaculture model. The principles and current status of phosphorus removal technology in aquaculture tailwater were discussed in terms of physical, chemical, and biological methods of phosphorus removal. The study indicated that the physical method of phosphorus removal technology in aquaculture primarily relies on adsorption and membrane separation technology, in which the high adsorption saturation of adsorbent materials and renewable is the key to adsorption of phosphorus removal, and the physical principle of membrane separation technology is the selective permeability of the membrane. Pollutant retention is achieved through the concentration difference between the two sides of the membrane, hydraulic pressure difference, and potential difference. The current membrane separation technology research methods continue to innovate and generally combine the membrane separation technology and biological method applied to aquaculture tail water phosphorus removal technology. Chemical phosphorus removal technologies such as precipitation, electro-flocculation, crystallization and depth oxidation are important for aquaculture tailwater phosphorus removal technology. These technologies are notable in phosphorus resource recovery and should not be ignored. Biological phosphorus removal technology is a primary method for phosphorus removal in aquaculture tailwater and mainly includes biofilm reactor, Biofloc, microalgae biological purification, bacterial and algal synergistic reactor, artificial wetland and other technologies. Biofilm reactors and Biofloc mainly rely on the role of phosphate accumulating organisms (PAOs) and denitrifying phosphate accumulating organisms (DPAOs), both of which have different processing capacities and biological responses to phosphorus in aerobic, anaerobic and anoxic stages. PAOs absorb phosphorus in aerobic conditions and release phosphorus in anaerobic conditions; DPAOs release phosphorus in anaerobic conditions and absorb phosphorus in the anoxic stage. Microalgae biological purification technology mainly uses the photosynthesis of microalgae and microalgae growth to absorb and remove phosphorus from the water. The microalgae bioreactor is a bacterial-algae synergistic reactor formed by combining microalgae and biofilm reactors to remove phosphorus. Artificial wetlands are a comprehensive phosphorus management method that integrates physical, chemical, and biological methods. This approach is becoming prominent as a crucial technique for phosphorus management in aquaculture tailwater. Current aquaculture modes such as recirculating aquaculture system (RAS), pond aquaculture and other modes, in which RAS mostly use biofilm reactors, bacterial and algal synergistic bioreactors and multi-level integrated aquaculture systems and other treatment methods, and in recent years, artificial wetlands are also gradually applied in the treatment of phosphorus in RAS tailwater. Artificial wetlands are used with sediment and microbial fuel cells to remove phosphorus from aquaculture tailwater. In phosphorus treatment in recirculating aquaculture tailwater, the bioecological method is gradually being used as the main method to treat phosphorus in tailwater, supplemented by physicochemical methods. The pond aquaculture tailwater phosphorus management is also based on bioecological methods, such as ‘three ponds and two dams’, artificial wetlands, multi-level integrated aquaculture treatment system and other methods to remove phosphorus. This study analyzed the aquaculture tailwater phosphorus removal technology, which can provide new ideas for tailwater phosphorus treatment and phosphorus resource recovery and promote the green development of aquaculture.

Key words: Phosphorus Existing form Aquaculture wastewater Recirculating aquaculture Phosphorus removal methods