鱼—菜共生种养技术模式研究现状

doi:10.13733/j.jcam.issn.2095-5553.2022.12.012

摘要/Abstract

摘要： 鱼—菜共生种养技术是一种多学科交叉融合的新型复合种养殖技术，将水产养殖与作物栽培有机结合，实现种养生产循环利用，可有效改善传统的水产养殖模式带来的大量养殖尾水排放、环境污染和资源浪费的负面影响。近年来，鱼—菜共生种养技术发展迅速，以该技术的研究进展为主线，对鱼—菜共生种养技术的技术要点、影响鱼—菜共生种养系统平衡的关键因素进行概述。客观分析现阶段鱼—菜共生种养技术发展中存在对菌藻利用氮磷转化的研究不足、水产及植物种类局限、经济可行性尚不明确、人工智能技术的应用不足、缺乏专业性人才及政府支持等问题。针对存在的问题，提出促进鱼—菜共生种养技术可持续发展的建议，如需要加强对各类微生物的利用以及对氮磷转化吸收效率的研究，并实现投入品种多元化，加快人工智能技术与鱼—菜共生种养技术相结合，政府提高重视，注重培养专业人才等

关键词: 鱼菜共生, 循环利用, 种养结合, 可持续发展

Abstract: The aquaponic planting and breeding technology is a new type of composite breeding technology with multidisciplinary integration. It combines aquaculture and crop cultivation organically to realize the recycling of farming and production, and can effectively improve the negative impact of the traditional aquaculture mode on the discharge of large quantities of aquaculture tail water, environmental pollution and resource waste. In recent years, the aquaponic planting and breeding technology has developed rapidly. Taking the research progress of this technology as the main line, this paper summarizes the technical key points of aquaponic and the key factors affecting the balance of aquaponic. Through the objective analysis of the current stage of the development of aquaponic planting and breeding technology, there are existing problems such as insufficient research on the conversion of nitrogen and phosphorus by bacteria and algae, limited aquatic products and plant species, unclear economic feasibility, insufficient application of artificial intelligence technology, lack of professional personnel and government support. In view of the existing problems, this paper puts forward to promote the aquaponic and raising suggestions for the sustainable development of technology, such as the need to strengthen the use of all kinds of microorganisms and the study of transformation of nitrogen and phosphorus uptake efficiency, and realize in species diversity and accelerate the artificial intelligence technology combined with an aquaponic planting and breeding technology, and for the government to raise awareness, pay more attention to the training of professional talents, etc.

Key words: aquaponics, cyclic utilization, combined planting and breeding, sustainable development

中图分类号:

S953： S964

刘慧, 汪小旵, 施印炎, 李天沛, 於海明, 郝向泽. 鱼—菜共生种养技术模式研究现状[J]. 中国农机化学报, 2022, 43(12): 75-83.

Liu Hui, Wang Xiaochan, Shi Yinyan, Li Tianpei, Yu Haiming, Hao Xiangze. Research status on aquaponics technology system[J]. Journal of Chinese Agricultural Mechanization, 2022, 43(12): 75-83.

参考文献

［1］　
FAO. The state of world fisheries and aquaculture: Meeting the sustainable development goals ［M］. Rome: FAO, 2018.

［2］　
陈霞, 陈健, 李良玉, 等. 鱼菜共生在水产养殖中的应用现状与前景［J］. 渔业致富指南, 2020(19): 14-17.

［3］　
杨思宇, 朱浩辰, 刘友晴, 等. 鱼菜共生发展与经济效益分析［J］. 养殖与饲料, 2021, 20(10): 64-66.

［4］　
Rakocy J, Shultz R C, Bailey D S, et al. Aquaponic production of tilapia and basil: Comparing a batch and staggered cropping system ［J］. Acta Horticulturae, 2004, 648: 63-69.

［5］　
McMurtry M R, Sanders D C, Cure J D, et al. Efficiency of water use of an integrated fish/vegetable coculture system ［J］. Journal of the World Aquaculture Society, 1997, 28(4): 420-428.

［6］　
徐琰斐, 张宇雷, 顾川川, 等. 鱼菜共生发展历史、典型模式与发展趋势［J］. 渔业现代化, 2020, 47(5): 1-7.

［7］　
王雅敏. 鱼菜共生系统的研究及其开发(上)［J］. 渔业机械仪器, 1991(5): 2-4.

［8］　
Somerville C, Cohen M, Pantanella E, et al. Smallscale aquaponic food production: integrated fish and plant farming ［M］. Rome: Food and Agriculture Organization of the United Nations, 2014.

［9］　
张明华, 丁永良, 杨菁, 等. 鱼菜共生技术及系统工程研究［J］. 现代渔业信息, 2004(4): 7-12.

［10］　
刘星, 刘艳, 虎治军, 等. 鱼菜共生立体高效生产系统研究进展［J］. 安徽农业科学, 2021, 49(15): 14-17.

Liu Xing, Liu Yan, Hu Zhijun, et al. Research progress of symbiotic threedimensional and efficient production system of aquaponics ［J］. Journal of Anhui Agricultural Sciences, 2021, 49(15): 14-17.

［11］　
丁永良, 张明华, 张建华, 等. 鱼菜共生系统的研究［J］. 中国水产科学, 1997(S1): 71-76.

［12］　
叶鸽, 郝淑贤, 李来好, 等. 不同养殖模式罗非鱼品质的比较［J］. 食品科学, 2014, 35(2): 196-200.

［13］　
Savidov N A, Hutchings E, Rakocy J E. Fish and plant production in a recirculating aquaponic system: a new approach to sustainable agriculture in Canada ［J］. Acta Horticulturae, 2005, 742: 209-221.

［14］　
Endut A, Lananan F, Hamid S H A, et al. Balancing of nutrient uptake by water spinach (Ipomoea aquatica) and mustard green (Brassica juncea) with nutrient production by African catfish (Clarias gariepinus) in scaling aquaponic recirculation system ［J］. Desalination and Water Treatment, 2016: 1-10.

［15］　
刘帅, 袁胜煜, 魏海峰, 等. 鲤Cyprinus carpio、泥鳅Misgurnus anguillicaudatus与黄豆种子共生系统对水质的影响［J］. 水产学杂志, 2021, 34(3): 78-82.

Liu Shuai, Yuan Shengyu, Wei Haifeng, et al. Effects of symbiotic system of Common carp (cyprinus carpio), loach (Misgurnus anguillicaudatus) and soybean seeds on water quality ［J］. Chinese Journal of Fisheries, 2021, 34(3): 78-82.

［16］　
Parrish C C, Kader W, Bathia C, et al. Ornamental fish as complementary species in aquaponics ［J］. Bulletin of the Aquaculture Association of Canada, 2012, 110(SPEC.1): 54-56.

［17］　
王冰, 张凯, 华向美, 等. 鱼菜共生系统矿物元素对蔬菜生长的影响［J］. 安徽农业科学, 2019, 47(13): 76-77, 81.

Wang Bing, Zhang Kai, Hua Xiangmei, et al. Effects of mineral elements on vegetable growth in aquaponics system ［J］. Journal of Anhui Agricultural Sciences, 2019, 47(13): 76-77, 81.

［18］　
毛宇光, 杨迎春. 麦饭石在鱼菜共生系统中的妙用［J］. 赤峰学院学报(自然科学版), 2018, 34(5): 24-25.

［19］　
Eck M, Sare A R, Massart S, et al. Exploring bacterial communities in aquaponic systems ［J］. Water, 2019, 11: 260.

［20］　
方颖珂. 基于氮迁移转化过程优化的鱼菌藻共生系统构建及性能研究［D］. 泰安: 山东大学, 2018.

Fang Yingke. Study on construction and performance of algalbacterial aquaponics based on optimization of nitrogen transformation processes ［D］. Taian: Shandong University, 2018.

［21］　
孟静静, 华磊, 吴德轩, 等. 硝化细菌对鱼菜共生种养模式下蔬菜生物学性状的影响［J］. 现代园艺, 2020, 43(13): 40-41, 43.

［22］　
李静, 陈小文, 张雪松. 硝化细菌在鱼菜共生系统中的应用［J］. 现代农村科技, 2021(10): 102-103.

［23］　
赵月玲, 李俊泽, 裴欣彤, 等. 基于传感器技术的鱼菜共生系统的研究与实现［J］. 电脑与信息技术, 2018, 26(2): 41-44.

［24］　
孙剑, 张莉. 基于物联网的鱼菜共生环境监测系统的研究［J］. 物联网技术, 2018, 8(6): 22-23.

［25］　
任小娅. 鱼菜共生水质环境智能测控系统研发［D］. 泰安: 山东农业大学, 2019.

Ren Xiaoya. Research and development on intelligent measurement and control system for water quality environment of aquaponics ［D］. Taian: Shandong University, 2019.

［26］　
Stone N, Thomforde H K. Understandingyour fish pond water analysis report ［J］. University of Arkansas Cooperative Extension Program, 2003, 21-23.

［27］　
Ebeling J M, Timmons M B, Bisogni J J. Engineering analysis of the stoichiometry of photoautotrophic, autotrophic, and heterotrophic removal of ammonianitrogen in aquaculture systems ［J］. Aquaculture, 2006, 257(1-4): 346-358.

［28］　
邹艺娜, 胡振, 张建, 等. 鱼菜共生系统氮素迁移转化的研究与优化［J］. 环境工程学报, 2015, 9(9): 4211-4216.

［29］　
李晗溪, 刘峰, 李雪, 等. 铁元素调控的鱼菜共生系统氮和总磷的变化规律［J］. 农业网络信息, 2016(12): 42-46.

［30］　
胡浩东, 高航, 胡振. 磺胺嘧啶对鱼菜共生系统氮元素转化的影响［J］. 中国环境科学, 2021, 41(4): 1697-1703.

Hu Haodong, Gao Hang, Hu Zhen. Effect of sulfadiazine on the nitrogen transformation of aquaponic systems ［J］. China Environmental Science, 2021, 41(4): 1697-1703.

［31］　
Ranka J, Bettina K, Morris V, et al. Strategic points in aquaponics ［J］. Water, 2017, 9(3): 182.

［32］　
Kuhn D D, Drahos D D, Marsh L, et al. Evaluation of nitrifying bacteria product to improve nitrification efficacy in recirculating aquaculture systems ［J］. Aquacultural Engineering, 2010, 43(2): 78-82.

［33］　
Seawright D E, Stickney R R, Walker R B. Nutrient dynamics in integrated aquaculturehydroponics systems ［J］. Aquaculture, 1998, 160(3-4): 215-237.

［34］　
Bhatnagar A, Devi P. Water quality guidelines for the management of pond fish culture ［J］. International Journal of Environmental Sciences, 2013, 3(6): 1980-2009.

［35］　
饶伟, 杨卫中, 位耀光, 等. 鱼菜共生水体溶解氧时空变化规律及其影响因素研究［J］. 农业机械学报, 2017, 48(S1): 374-380.

Rao Wei, Yang Weizhong, Wei Yaoguang, et al. Temporal and spatial variability of water dissolved oxygen with influence factors in aquaponics system ［J］. Transactions of the Chinese Society of Agricultural Machinery, 2017, 48(S1): 374-380.

［36］　
Khater E, Ali S A. Effect of flow rate and length of gully on lettuce plants in aquaponic and hydroponic systems ［J］. Journal of Aquaculture Research & Development, 2015, 6(3): 100318.

［37］　
蔡淑芳, 陈敏, 陈永快, 等. 种植密度对鱼菜共生系统氮素转化的影响［J］. 农业工程学报, 2019, 35(4): 132-137.

Cai Shufang, Chen Min, Chen Yongkuai， et al. Effects of plant density on nitrogen transformation in aquaponics system ［J］. Transactions of the Chinese Society of Agricultural Engineering, 2019, 35(4): 132-137.

［38］　
Lam S S, MA N L, Jusoh A, et al. Biological nutrient removal by recirculating aquaponic system: Optimization of the dimension ratio between the hydroponic & rearing tank components ［J］. International Biodeterioration & Biodegradation, 2015, 102: 107-115.

［39］　
Liang J Y, Chien Y H. Effects of feeding frequency and photoperiod on water quality and crop production in a tilapiawater spinach raft aquaponics system ［J］. International Biodeterioration & Biodegradation, 2013, 85: 693-700.

［40］　
Urquhart A N, Koetsier P. Lowtemperature tolerance and critical thermal minimum of the invasive oriental weatherfish Misgurnus anguillicaudatus in Idaho, USA ［J］. Transactions of the American Fisheries Society, 2014, 143(1): 68-76.

［41］　
刘爽, 安诗琦, 严子微, 等. 现代鱼菜共生技术研究进展与展望［J］. 中国农业科技导报, 2020, 22(3): 160-166.

Liu Shuang, An Shiqi, Yan Ziwei, et al. Progress and prospect of aquaponics technology ［J］. Journal of Agricultural Science and Technology, 2020, 22(3): 160-166.

［42］　
章海鑫, 余智杰, 张燕萍, 等. 养殖模式对草鱼池塘底泥微生物群落结构影响的分析［J］. 淡水渔业, 2021, 51(2): 3-12.

Zhang Haixin, Yu Zhijie, Zhang Yanping， et al. Effect of culture modes on microbial community structure of sediments in grass carp Ctenopharyngodon idellus ponds ［J］. Freshwater Fisheries, 2021, 51(2): 3-12.

［43］　
刘海鹏. 鱼菜共生系统的作用机理及其对现代农业发展的意义［J］. 中国食品, 2021(19): 142-143.

［44］　
马雪, 杨振亚. 鱼菜共生循环农业优质高效［J］. 农业知识, 2021(3): 62-63.

［45］　
李嘉丽, 赖小华, 戚湛, 等. 鱼菜共生系统概述［J］. 农业技术与装备, 2020(4): 120-122.

[1]	仇宇俊, 汪小旵, 李天沛, 葛朋彪. 鱼菜共生环境中多参数监测系统设计与试验[J]. 中国农机化学报, 2022, 43(12): 67-74.
[2]	杨建辉;. 农业现代化对农业可持续发展的影响及空间演化研究[J]. 中国农机化学报, 2020, 41(8): 229-236.
[3]	杨发展;李维华;王黎阳;牟家宏;荐世春;史嵩;. 大型农机专业合作社面临的问题与可持续发展策略研究——以山东农业生态区为例[J]. 中国农机化学报, 2019, 40(3): 212-216.
[4]	张恒;康建明;张国海;王永刚;杜洪恿;孙海博;. 黄淮海地区农膜污染现状及对策分析[J]. 中国农机化学报, 2019, 40(1): 156-161.