|
|
循环水养殖系统的研究进展及发展趋势 |
王海姮1,2, 侯昊晨1,2, 刘鹰1,2,3 |
1.大连海洋大学,设施渔业教育部重点实验室,辽宁 大连 116023; 2.大连海洋大学 海洋科技与环境学院,辽宁 大连 116023; 3.浙江大学 生物系统工程与食品科学学院,浙江 杭州 310058 |
|
Research Progress and Development Trend in RecirculatingAquaculture System |
WANG Haiheng1,2, HOU Haochen1,2, LIU Ying1,2,3 |
1. Key Laboratory of Environment Controlled Aquaculture, Dalian Ocean University, Dalian 116023, China; 2. College of Marine Technology and Environment, Dalian Ocean University, Dalian 116023, China; 3. College of Biosystems Engineering and Food Science, Zhejiang Universtiy, Hangzhou 310058, China |
[1]张晓双,傅玲琳,吕振明,等.国内外循环式工厂化水产养殖模式研究进展[J].饲料工业,2017,38(6):61-64. [2]徐皓,张建华,丁建乐,等.国内外渔业装备与工程技术研究进展综述(续)[J].渔业现代化,2010,37(3):1-5. [3]刘鹰.海水工业化循环水养殖技术研究进展[J].中国农业科技导报,2011,13(5):50-53. [4]刘长发,綦志仁,何洁,等.环境友好的水产养殖业——零污水排放循环水产养殖系统[J].大连水产学院学报,2002,17(3):220-226. [5]王峰,雷霁霖,高淳仁,等.国内外工厂化循环水养殖研究进展[J].中国水产科学,2013,20(5):1100-1111. [6]薛正锐,姜辉,陈庆生.工厂化循环水养鱼工程技术研究与开发[J].海洋水产研究,2006,27(4):77-81. [7]SUANTIKA G, SITUMORANG M L, SAPUTRA F I, et al. Metabolite profiling of whiteleg shrimp Litopenaeus vannamei from super-intensive culture in closed aquaculture systems:a recirculating aquaculture system and a hybrid zero water discharge-recirculating aquaculture system[J].Metabolomics,2020,16(4):49. [8]宋协法,李强,彭磊,等.半滑舌鳎封闭式循环水养殖系统的设计与应用[J].中国海洋大学学报(自然科学版),2012,42(10):26-32. [9]罗国芝,谭洪新,朱学宝.闭合循环水产养殖车间水处理核心单元的处理效率[J].大连水产学院学报,2008,23(1):68-72. [10]ZHANG S Y, LI G, WU H B, et al. An integrated recirculating aquaculture system (RAS) for land-based fish farming:the effects on water quality and fish production[J].Aquacultural Engineering,2011,45(3):93-102. [11]VERDEGEM M C J, BOSMA R H, VERRETH J A J. Reducing water use for animal production through aquaculture[J].International Journal of Water Resources Development,2006,22(1):101-113. [12]MARTINS C I M, EDING E H, VERDEGEM M C J, et al. New developments in recirculating aquaculture systems in Europe:a perspective on environmental sustainability[J].Aquacultural Engineering,2010,43(3):83-93. [13]YOGEV U, VOGLER M, NIR O, et al. Phosphorous recovery from a novel recirculating aquaculture system followed by its sustainable reuse as a fertilizer[J].Science of the Total Environment,2020,722:137949. [14]BÉNÉ C, ARTHUR R, NORBURY H, et al. Contribution of fisheries and aquaculture to food security and poverty reduction:assessing the current evidence[J].World Development,2016,79:177-196. [15]YANONG R P E. Biosecurity in aquaculture, Part 2: Recirculating aquaculture systems[J]. Retrieved November,2012,29:2018. [16]徐皓,张建华,丁建乐,等.国内外渔业装备与工程技术研究进展综述[J].渔业现代化,2010,37(2):1-8. [17]ALMEIDA P, DEWASME L, VANDE WOUWER A. Denitrification control in a recirculating aquaculture system—a simulation study[J].Processes,2020,8(10):1306. [18]徐皓,张祝利,张建华,等.我国渔业节能减排研究与发展建议[J].水产学报,2011,35(3):472-480. [19]韩晓磊,王浩,高俊杰,等.工厂化循环水养殖条件下大口黑鲈生长特点分析[J].水产科学,2020,39(4):567-572. [20]BOYD C E, D'ABRAMO L R, GLENCROSS B D, et al. Achieving sustainable aquaculture:historical and current perspectives and future needs and challenges[J].Journal of the World Aquaculture Society,2020,51(3):578-633. [21]DAHLE S W, BAKKE I, BIRKELAND M, et al. Production of lumpfish (Cyclopterus lumpus L.) in RAS with distinct water treatments:effects on fish survival, growth, gill health and microbial communities in rearing water and biofilm[J].Aquaculture,2020,522:735097. [22]周煊亦,房燕,曹广斌,等.臭氧处理技术在工厂化水产养殖中的应用研究[J].水产学杂志,2012,25(1):49-57. [23]EDING E H, KAMSTRA A, VERRETH J A J, et al. Design and operation of nitrifying trickling filters in recirculating aquaculture:a review[J].Aquacultural Engineering,2006,34(3):234-260. [24]ASIRI F, CHU K H. A novel recirculating aquaculture system for sustainable aquaculture:enabling wastewater reuse and conversion of waste-to-immune-stimulating fish feed[J].ACS Sustainable Chemistry & Engineering,2020,8(49):18094-18105. [25]NAYLOR R L, HARDY R W, BUSCHMANN A H, et al. A 20-year retrospective review of global aquaculture[J].Nature,2021,591(7851):551-563. [26]VAN RIJN J. Waste treatment in recirculating aquaculture systems[J].Aquacultural Engineering,2013,53:49-56. [27]GONÇALVES A A, GAGNON G A. Ozone application in recirculating aquaculture system:an overview[J].Ozone:Science & Engineering,2011,33(5):345-367. [28]CRAB R, AVNIMELECH Y, DEFOIRDT T, et al. Nitrogen removal techniques in aquaculture for a sustainable production[J].Aquaculture,2007,270(1/2/3/4):1-14. [29]LINDHOLM-LEHTO P, PULKKINEN J, KIURU T, et al. Water quality in recirculating aquaculture system using woodchip denitrification and slow sand filtration[J].Environmental Science and Pollution Research,2020,27(14):17314-17328. [30]LEPINE C, CHRISTIANSON L, SHARRER K, et al. Optimizing hydraulic retention times in denitrifying woodchip bioreactors treating recirculating aquaculture system wastewater[J].Journal of Environmental Quality,2016,45(3):813-821. [31]REJISH KUMAR V J, JOSEPH V, PHILIP R, et al. Nitrification in brackish water recirculating aquaculture system integrated with activated packed bed bioreactor[J].Water Science and Technology,2010,61(3):797-805. [32]ZHU S M, DENG Y L, RUAN Y J, et al. Biological denitrification using poly(butylene succinate) as carbon source and biofilm carrier for recirculating aquaculture system effluent treatment[J].Bioresource Technology,2015,192:603-610. [33]LEPINE C, CHRISTIANSON L, DAVIDSON J, et al. Woodchip bioreactors as treatment for recirculating aquaculture systems' wastewater:a cost assessment of nitrogen removal[J].Aquacultural Engineering,2018,83:85-92. [34]SANTOS F A C, COSTA JULIO G S, LUZ R K. Stocking density in Colossoma macropomum larviculture, a freshwater fish, in recirculating aquaculture system[J].Aquaculture Research,2021,52(3):1185-1191. [35]WILLIAMS A S, DAVIS D A, ARNOLD C R. Density-dependent growth and survival of Penaeus setiferus and Penaeus vannamei in a semi-closed recirculating system[J].Journal of the World Aquaculture Society,1996,27(1):107-112. [36]WASIELESKY W Jr, ATWOOD H, STOKES A, et al. Effect of natural production in a zero exchange suspended microbial floc based super-intensive culture system for white shrimp Litopenaeus vannamei[J].Aquaculture,2006,258(1/2/3/4):396-403. [37]MARTINS P, CLEARY D F R, PIRES A C C, et al. Molecular analysis of bacterial communities and detection of potential pathogens in a recirculating aquaculture system for Scophthalmus maximus and Solea senegalensis[J].PLoS One,2013,8(11):e80847. [38]PULKKINEN K, SUOMALAINEN L R, READ A F, et al. Intensive fish farming and the evolution of pathogen virulence:the case of columnaris disease in Finland[J].Proceedings.Biological Sciences,2010,277(1681):593-600. [39]PULKKINEN J T, ERIKSSON-KALLIO A M, AALTO S L, et al. The effects of different combinations of fixed and moving bed bioreactors on rainbow trout (Oncorhynchus mykiss) growth and health, water quality and nitrification in recirculating aquacul-ture systems[J].Aquacultural Engineering,2019,85:98-105. [40]DAVIDSON J, GOOD C, WELSH C, et al. The effects of ozone and water exchange rates on water quality and rainbow trout Oncorhynchus mykiss performance in replicated water recirculating systems[J].Aquacultural Engineering,2011,44(3):80-96. [41]VAN DEN HENDE S, CLAESSENS L, DE MUYLDER E, et al. Microalgal bacterial flocs originating from aquaculture wastewater treatment as diet ingredient for Litopenaeus vannamei (Boone)[J].Aquaculture Research,2016,47(4):1075-1089. [42]DALSGAARD J, LUND I, THORARINSDOTTIR R, et al. Farming different species in RAS in Nordic countries:current status and future perspectives[J].Aquacultural Engineering,2013,53:2-13. [43]TURCIOS A, PAPENBROCK J. Sustainable treatment of aquaculture effluents—what can we learn from the past for the future?[J].Sustainability,2014,6(2):836-856. [44]AN D, HAO J, WEI Y G, et al. Application of computer vision in fish intelligent feeding system—a review[J].Aquaculture Research,2021,52(2):423-437. [45]WANG C, LI Z, WANG T, et al. Intelligent fish farm—the future of aquaculture[J].Aquaculture International,2021,29(6):2681-2711. [46]李道亮,傅泽田,马莉,等.智能化水产养殖信息系统的设计与初步实现[J].农业工程学报,2000,16(4):135-138. [47]BADIOLA M, BASURKO O C, PIEDRAHITA R, et al. Energy use in Recirculating Aquaculture Systems (RAS):a review[J].Aquacultural Engineering,2018,81:57-70. [48]MIRZOYAN N, TAL Y, GROSS A. Anaerobic digestion of sludge from intensive recirculating aquaculture systems:review[J].Aquaculture,2010,306(1/2/3/4):1-6. [49]CAO L, WANG W M, YANG Y, et al. Environmental impact of aquaculture and countermeasures to aquaculture pollution in China[J].Environmental Science and Pollution Research-International,2007,14(7):452-462. [50]PORRELLO S, LENZI M, TOMASSETTI P, et al. Reduction of aquaculture wastewater eutrophication by phytotreatment ponds system:Ⅱ.Nitrogen and phosphorus content in macroalgae and sediment[J].Aquaculture,2003,219(1/2/3/4):531-544. [51]罗国芝,孙大川,冯是良,等.闭合循环水产养殖系统生产过程中生物过滤器功能的形成[J].水产学报,2005,29(4):574-577. [52]RUIZ P, VIDAL J M, SEPÚLVEDA D, et al. Overview and future perspectives of nitrifying bacteria on biofilters for recirculating aquaculture systems[J].Reviews in Aquaculture,2020,12(3):1478-1494. [53]NOOTONG K, NURIT S, POWTONGSOOK S. Control of inorganic nitrogen and suspended solids concentrations in a land-based recirculating aquaculture system[J].Engineering Journal,2013,17(1):49-60. [54]CRISTIAN S, BENONE P, NECULAI P, et al. Preliminary research on the anammox process and control of nitrogen compounds in a recirculating aquaculture system[J].AACL Bioflux,2013,6:27-33. [55]SCHUMANN M, UNGER J, BRINKER A. Floating faeces:effects on solid removal and particle size distribution in RAS[J].Aquacultural Engineering,2017,78:75-84. [56]LAZA E A, LADISLAU CABA I, OLAN M, et al. Biological water treatment in a recirculating aquaculture system[J].E3S Web of Conferences,2021,286:03013. [57]BÖGNER D, SCHMACHTL F, MAYR B, et al. Sludge pre-treatment through ozone application:alternative sludge reuse possibilities for recirculating aquaculture system optimization[J].Ozone:Science & Engineering,2019,41(2):105-117. [58]ATTRAMADAL K J K, TRUONG T M H, BAKKE I, et al. RAS and microbial maturation as tools for K-selection of microbial communities improve survival in cod larvae[J].Aquaculture,2014,432:483-490. [59]YANG L, ZHOU H D, MOCCIA R. Membrane filtration coupled with chemical precipitation to treat recirculating aquaculture system effluents[J].Journal of Environmental Quality,2006,35(6):2419-2424. [60]SUMMERFELT S T, SHARRER M J, TSUKUDA S M, et al. Process requirements for achieving full-flow disinfection of recirculating water using ozonation and UV irradiation[J].Aquacultural Engineering,2009,40(1):17-27. [61]程启云,韩世成,曹广斌,等.工厂化水产养殖中的悬浮物处理技术[J].水产学杂志,2014,27(2):61-67. [62]朱明瑞,曹广斌,蒋树义,等.工厂化水产养殖水体的pH值在线自动控制系统[J].水产学报,2007,31(3):335-342. [63]LINDHOLM-LEHTO P C, PULKKINEN J T, KIURU T, et al. Efficient water treatment achieved in recirculating aquaculture system using woodchip denitrification and slow sand filtration[J]. Environmental Science and Pollution Research,2021,28(46):65333-65348. [64]TANIKAWA D, NAKAMURA Y, TOKUZAWA H, et al. Effluent treatment in an aquaponics-based closed aquaculture system with single-stage nitrification-denitrification using a down-flow hanging sponge reactor[J].International Biodeterioration & Biodegradation,2018,132:268-273. [65]XIAO R C, WEI Y G, AN D, et al. A review on the research status and development trend of equipment in water treatment processes of recirculating aquaculture systems[J].Reviews in Aquaculture,2019,11(3):863-895. [66]CALDERINI M L, STEVČIĆ Č, TAIPALE S, et al. Filtration of Nordic recirculating aquaculture system wastewater:effects on microalgal growth, nutrient removal, and nutritional value[J].Algal Research,2021,60:102486. [67]SÁNCHEZ-ORTIZ I A, CÁRDENAS-CALVACHI G L. Recirculating aquaculture system with three phase fluidized bed reactor:carbon and nitrogen removal[J].Revista Facultad De Ingeniería Universidad De Antioquia,2020,97:93-102. [68]DENG M, DAI Z L, SENBATI Y, et al. Aerobic denitrification microbial community and function in zero-discharge recirculating aquaculture system using a single biofloc-based suspended growth reactor:influence of the carbon-to-nitrogen ratio[J].Frontiers in Microbiology,2020,11:1760. [69]HITZFELDER G M, HOLT G J, FOX J M, et al. The effect of rearing density on growth and survival of cobia, Rachycentron canadum, larvae in a closed recirculating aquaculture system[J].Journal of the World Aquaculture Society,2006,37(2):204-209. [70]DEDIU L, DOCAN A, CRETU M, et al. Effects of stocking density on growth performance and stress responses of bester and bester ♀ × Beluga ♂ juveniles in recirculating aquaculture systems[J].Animals:an Open Access Journal from MDPI,2021,11(8):2292. [71]LI X, LIU Y, BLANCHETON J P. Effect of stocking density on performances of juvenile turbot (Scophthalmus maximus) in recirculating aquaculture systems[J].Chinese Journal of Oceanology and Limnology,2013,31(3):514-522. [72]马从国,赵德安,秦云,等.基于现场总线技术的水产养殖过程智能监控系统[J].农业机械学报,2007,38(8):113-115. [73]史兵,赵德安,刘星桥,等.基于无线传感网络的规模化水产养殖智能监控系统[J].农业工程学报,2011,27(9):136-140. [74]王峰,雷霁霖.工厂化循环水养殖模式放养密度对半滑舌鳎成鱼生长和肌肉营养成分的影响[J].中国工程科学,2015,17(1):19-26. [75]RICHE M A, WEIRICH C R, WILLS P S, et al. Stocking density effects on production characteristics and body composition of market size cobia, Rachycentron canadum, reared in recirculating aquaculture systems[J].Journal of the World Aquaculture Society,2013,44(2):259-266. [76]齐巨龙,赖铭勇,王茂元,等.鳗鲡循环水高密度养殖试验研究[J].上海海洋大学学报,2012,21(2):212-217. [77]任华,蓝泽桥,王一明,等.循环水养殖系统中放养密度对杂交鲟仔鱼摄食行为、生长和存活的影响[J].渔业现代化,2013,40(2):12-16. [78]SAHOO S K, GIRI S S, SAHU A K. Effect of stocking density on growth and survival of Clarias batrachus (Linn.) larvae and fry during hatchery rearing[J].Journal of Applied Ichthyology,2004,20(4):302-305. [79]PENA HERREJON G, SANCHEZ VELAZQUEZ J, GARCIA TREJO J, et al. Effect of stocking density on growth and survival of the prawn Macrobrachium tenellum, cultured in a recirculating aquaculture system[J].Latin American Journal of Aquatic Research,2019,47(2):342-348. [80]张曦文,吴垠,贺茹靖,等.循环水养殖模式下养殖密度对青石斑鱼生长及生理指标的影响[J].大连海洋大学学报,2012,27(6):518-522. [81]GJURČEVIĆE, KUIR S, MAK L, et al. A case of mycobacteriosis in farmed pikeperch (Sander lucioperca) cultured in a recirculating aquaculture system[J].Aquaculture Research,2020,51(11):4824-4827. [82]朱挺兵,吴兴兵,朱永久,等.封闭循环水系统和船体网箱驯养圆口铜鱼幼鱼的效果比较[J].淡水渔业,2015,45(6):97-101. [83]ARUETY T, BRUNNER T, RONEN Z, et al. Decreasing levels of the fish pathogen Streptococcus iniae following inoculation into the sludge digester of a zero-discharge recirculating aquaculture system (RAS)[J].Aquaculture,2016,450:335-341. [84]ORELLANA J, WALLER U, WECKER B. Culture of yellowtail kingfish (Seriola lalandi) in a marine recirculating aquaculture system (RAS) with artificial seawater[J].Aquacultural Engineering,2014,58:20-28. [85]DUARTE L N, COELHO F J R C, OLIVEIRA V, et al. Characterization of bacterioplankton communities from a hatchery recirculating aquaculture system (RAS) for juvenile sole (Solea senegalensis) production[J].PLoS One,2019,14(1):e0211209. [86]CHEN F D, DU Y S, QIU T L, et al. Design of an intelligent variable-flow recirculating aquaculture system based on machine learning methods[J].Applied Sciences,2021,11(14):6546. [87]MUSTAFA F H. A review of smart fish farming systems[J].Journal of Aquaculture Engineering and Fisheries Research,2016:193-200. [88]STEICKE C, JEGATHEESAN V, ZENG C. Recirculating aquaculture systems-a review[J]. Water and Wastewater Treatment Technologies,2009,2:149-179. [89]ZHOU C, XU D M, LIN K, et al. Intelligent feeding control methods in aquaculture with an emphasis on fish:a review[J].Reviews in Aquaculture,2018,10(4):975-993. [90]HUANG B, LIU B, LIE J L, et al. The research on key technology and intelligent equipment of aquaculture welfare in industrial circulating water mode[J].Journal of Fisheries of China,2013,37(11):1750. [91]VO T T E, KO H, HUH J H, et al. Overview of solar energy for aquaculture:the potential and future trends[J].Energies,2021,14(21):6923. [92]ZHAO S L, ZHANG S, LIU J C, et al. Application of machine learning in intelligent fish aquaculture:a review[J].Aquaculture,2021,540:736724. [93]SERGALIEV N K, KAKISHEV M G, GINAYATOV N S, et al. Microbiome structure in a recirculating aquaculture system and its connection to infections in sturgeon fish[J].Veterinary World,2021,14(3):661-668. [94]张宇雷,吴凡,王振华,等.超高密度全封闭循环水养殖系统设计及运行效果分析[J].农业工程学报,2012,28(15):151-156. |
[1] |
韩佳民, 苏胜齐. 生物絮团技术研究进展与应用概述[J]. 水产科学, 2022, 41(3): 491-503. |
[2] |
于宇, 李冰, 郭广鑫, 任贻超. 不同食物组分对大红海参生长和脂肪酸组成的影响[J]. 水产科学, 2022, 41(1): 85-91. |
[3] |
陈晓庆, 罗国芝, 谭洪新, 吴慧芳, 蒙浩焱, 黎爽. 絮体粒径对生物絮团系统中硝化作用的影响[J]. 水产科学, 2021, 40(6): 860-869. |
[4] |
关晓燕, 王摆, 蒋经伟, 田甲申, 董颖, 周遵春, 王旭达. 仿刺参—中国明对虾—斑节对虾混养下水体微生物组成和多样性[J]. 水产科学, 2020, 39(6): 796-803. |
[5] |
吕可, 赵前程, 刘婧懿, 马子祯, 徐永平, 马永生. 噬菌体在水生动物病害防治中的应用问题和解决策略[J]. 水产科学, 2020, 39(6): 964-971. |
[6] |
吴甘林, 邓玉婷, 姜兰, 谭爱萍, 赵飞, 张瑞泉. 水产动物源细菌质粒介导的喹诺酮类耐药研究概况[J]. 水产科学, 2020, 39(4): 631-638. |
[7] |
郭睿, 张莺脐, 张羡宇, 刘述颖, 吴子曾, 张倩, 刘鹰, MD MOSTAFIZUR Rahman. 氟苯尼考在海水鱼循环水养殖系统中的迁移转化规律[J]. 水产科学, 2020, 39(3): 332-340. |
[8] |
杨静, 白璐, 马红丽, 王一婷, 郭思聪, 叶仕根. 聚β-羟基丁酸酯来源及其在水产养殖中的应用[J]. 水产科学, 2020, 39(2): 292-298. |
[9] |
谭凤霞, 裴梦婷, 柴毅, 杨代勤. 抗菌肽与鱼类肠道健康研究进展[J]. 水产科学, 2020, 39(1): 135-142. |
[10] |
刘艳莉,胡毅,钟蕾,石勇,顾宇,李雅敏. 丁酸对动物肠道健康的影响及水产应用前景[J]. 水产科学, 2019, 38(2): 276-281. |
[11] |
刘盼,贾成霞,杨慕,曲疆奇,张楠,张清靖. 2种微藻对养殖水体中氨氮和亚硝态氮的净化作用[J]. 水产科学, 2018, 37(3): 389-393. |
[12] |
孟彬,孙敬锋,吕爱军. 发酵中草药在水产养殖中的应用[J]. 水产科学, 2018, 37(3): 421-426. |
[13] |
陈康勇,钟为铭,高志鹏. 蛭弧菌在水产养殖中应用研究进展[J]. 水产科学, 2018, 37(2): 283-288. |
[14] |
孙成渤,李建国,赵冬艳,李崇文,武君君,危立坤. 多级生物净化在封闭循环水养殖系统中的水质调控效果[J]. 水产科学, 2017, 36(5): 577-584. |
[15] |
李敏佳,郭衍彪,吴冰,韩红操,蔡俊鹏. 蛭弧菌(类群)研究现状及最新进展[J]. 水产科学, 2017, 36(3): 377-382. |
|
|
|
|