|本期目錄/Table of Contents|

[1]蒲寶山,鄭回勇,黃語燕,等.我國溫室農業設施裝備技術發展現狀及建議[J].江蘇農業科學,2019,47(14):13-18.
 Pu Baoshan,et al.Development status and suggestions of Chinas greenhouse agricultural facilities and equipment technology[J].,2019,47(14):13-18.
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我國溫室農業設施裝備技術發展現狀及建議(PDF)
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《江蘇農業科學》[ISSN:1002-1302/CN:32-1214/S]

卷:
第47卷
期數:
2019年第14期
頁碼:
13-18
欄目:
專論與綜述
出版日期:
2019-08-10

文章信息/Info

Title:
Development status and suggestions of Chinas greenhouse agricultural facilities and equipment technology
作者:
蒲寶山 鄭回勇 黃語燕 吳敬才
福建省農業科學院數字化研究所,福建福州 350001
Author(s):
Pu Baoshanet al
關鍵詞:
現代化溫室設施裝備發展現狀建議
Keywords:
-
分類號:
S625
DOI:
-
文獻標志碼:
A
摘要:
現代化溫室設施裝備發展狀況是設施農業工程發展水平的重要體現,是實現農産品生産高産、高效、高品質的有效保障,也是我國現代都市型農業發展的關注重點。我國農業設施裝備雖經曆近30年跌宕起伏的發展,但仍存在許多問題。因此,總結國外先進的農業設施裝備的發展與研究狀況,綜述目前國內溫室設施裝備的發展存在若幹問題並提出幾點建議。
Abstract:
-

參考文獻/References:

[1]齊飛,周新群,張躍峰,等. 世界現代化溫室裝備技術發展及對中國的啓示[J]. 農業工程學報,2008,24(10):279-285.
[2]齊飛,朱明,周新群,等. 農業工程與中國農業現代化相互關系分析[J]. 農業工程學報,2015,31(1):1-10.
[3]van Henten E J.Greenhouse mechanization:state of the art and future perspective[C].International Symposium on Greenhouses,Environmental Controls and Inhouse Mechanization for Crop Production in the Tropics and Sub-Tropics, 2006:55-70.
[4]農業部南京農業機械化研究所. 中國農業機械化年鑒[M]. 北京:中國農業科學技術出版社,2013.
[5]Sinaia N.Water development for Israel:challenges and opportunities[M]//Lipchin C,Pallant E,Saranga D,et a1.Integrated water resources management and security in the middle east.Dordrecht:Springer Netherlands,2007:65-72.
[6]Katsoulas N,Sapounas A,Zwart F,et al.Reducing ventilation requirements in semi-closed greenhouses increases water use efficiency[J]. Agricultural Water Management,2015(15):690-699.
[7]Flores-Velazquez J,Villarreal-Guerrero F.Design of a forced ventilation system for a zenithal greenhouse using CFD[J]. Revista Mexicana de Ciencias Agricolas,2015,6(2):303-316.
[8]Srdic S,Koleska I,Mihajlovic D,et al.Irrigation and fertilization control trial using two different drip irrigation systems (autoagronom and conventional drip) in greenhouse cucumber production in Israel[J]. Agroznanje- Agro- Knowledge Journal,2015:16(3):311-323.
[9]Khoshimkhujaev B,Kwon J K,Park K S,et al.Optical characteristics of three woven plastic films[J]. Acta Horticulturae,2014(1037):939-944.
[10]Alsadon A A,Al-Helal I M,Ibrahim A A.Growth response of cucumber under greenhouses covered with plastic films[J]. Journal of Animal and Plant Sciences,2016,26(1):139-148.
[11]Abdullah A,Al-Helal I,Abdullah I,et al.The effects of plastic greenhouse covering on cucumber (Cucumis sativus L.) growth[J]. Ecological Engineering,2016(87):305-312.
[12]Alsadon A A,Al-Helal I M,Ibrahim A A.Growth response of cucumber under greenhouses covered with plastic films[J]. Journal of Animal and Plant Sciences,2016,26(1):139-148.
[13]Tamimi E,Kacira M,Choi C Y S,et al.Analysis of microclimate uniformity in a naturally vented greenhouse with a high-pressure fogging system[J]. Transactions of the ASABE,2013,56(3):1241-1254.
[14]Kroggel M,Kubota C.Controlled environment strategies for tipburn management in greenhouse strawberry production[J]. Acta Horticulturae,2017(1156):529-536.
[15]Buckhn R A.Florida greenhouse design[EB/OL]. (2008-09-10)[2008-04-20]. http://edis. ifas.un.edu.
[16]Rovira-Mas F,Chatterjee I,Saiz-Rubio V.The role of GNSS in the navigation strategies of cost-effective agricultural robots[J]. Computers and Electronics in Agriculture,2015,112:172-183.
[17]Lichtenberg E,Majsztrik J,Saavoss M.Profitability of sensor based irrigation in greenhouse and nursery crops[J]. Hort Technology,2013,23(6):770-774.
[18]Hoshi T,Yasuba K,Kurosaki H.Present situation and prospects of Japanese protected horticulture and ubiquitous environment control systems[J]. Journal of Science and High Technology in Agriculture,2016,28(4):163-171.
[19]Sato M,Sakamoto T.Development of energy-saving plant cultivation system suitable for Hokuriku region in Japan[J]. Seibutsu-Kogaku Kaishi,2015,93(9):542-546.
[20]Kawashima H.Development of a new energy-saving pipe-framed greenhouse[J]. Japan Agricultural Research Quarterly,2015,49(3):235-243.
[21]Kempkes F L K,Janse J,Hemming S.Greenhouse concept with high insulating double glass with coatings and new climate control strategies;from design to results from tomato experiments[J]. Acta Horticulturae,2014(1037):83-92.
[22]Yang G S,Zhang Y L,Feng Y,et al.Development status of automated equipment systems for greenhouse vegetable seedlings production in Netherlands and its inspiration for China[J]. Transactions of the Chinese Society of Agricultural Engineering,2013,29(14):185-194.
[23]Zhang Z,Gates R S,Zou Z R,et al.Evaluation of ventilation performance and energy efficiency of greenhouse fans[J]. International Journal of Agricultural and Biological Engineering,2015,8(1):103-110.
[24]Maican E,Dutu I C.CFD validation of a novel heat generation equipment for greenhouses and hothouses[C]. Proceedings of the 45th International Symposium on Agricultural Engineering,Actual Tasks on Agricultural Engineering,2017:481-489.
[25]Grisey A,Brajeul E.Energy in tomato and cucumber greenhouse production:developments in greenhouses and heating equipment[J]. Infos-Ctifl,2013(289):35-40.
[26]Bjugstad N.Inspection of spraying equipment in use in greenhouses in Norway[C]. Proceedings of the 25th NJF Congress(Nordic View to Sustainable Rural Development),2015:375-380.
[27]Harbick K,Albright L D,Mattson N S.Electrical savings comparison of supplemental lighting control systems in greenhouse environments[C]. 2016 ASABE Annual International Meeting,2016:162460478.
[28]Iersel M W,van Gianino D.An adaptive control approach for light-emitting diode lights can reduce the energy costs of supplemental lighting in greenhouses[J]. HortScience,2017,52(1):72-77.
[29]Voltan D S,Barbosa R Z,Martins J E M P,et al.Development of technologies and methods for monitoring the spatial variability of air temperature in greenhouse environment[J]. Brazilian Journal of Applied Technology for Agricultural Science,2013,6(3):7-16.
[30]Markovic D B,Pavlovic R M,Pesovic U M,et al.System for monitoring microclimate conditions in greenhouse[J]. Acta Agriculturae Serbica,2014,19(38):105-114.
[31]Sudduth K A.Curent status and future directions of precision agricuture in the USA[R]. Pyeongtaek:Proceedings 2nd Asian Conference on Precision Agriculture,2007.
[32]Yazg A,Degirmencioglu A.Optimization of the seed spacing uniformity of a vacuum type precision seeder using spherical materials[J]. Ege Universitesi Ziraat Fakultesi Dergisi,2015,52(3):277-286.
[33]Macedo D X S,de Nicolau F E A,do Nascimento H C F,et al.Operational performance of a tractor-seeder according to the velocity and working depth[J]. Revista Brasileira de Engenharia Agricola e Ambiental,2016,20(3):280-285.
[34]Kokuryu T,Ohshita Y,Takayama S,et al. Development of a no-till seeder with a chisel at each row-performance of the seeder for soybean seeding after harvesting wheat on upland paddy[J]. Journal of the Japanese Society of Agricultural Machinery and Food Engineers,2016,78(2):154-163.
[35]Hayashi S,Yamamoto S,Tsubota S.Automation technologies for strawberry harvesting and packing operations in Japan[J]. Journal of Berry Research,2014,4(1):19-27.
[36]Yang G S,Zhang Y L,Feng Y.Development status of automated equipment systems for greenhouse potted flowers production in Netherlands[J]. Transactions of the Chinese Society of Agricultural Engineering,2012,28(19):1-8.
[37]Shivmurti S,Joshi D C.Mathematical model for design and development of double drum rotary screen cleaner-cum-grader for cumin seed[J]. Agricultural Mechanization in Asia,Africa and Latin America,2013,44(3):70-74.
[38]Xia C L,Chon T S,Ren Z M. Automatic identification and counting of small size pests in greenhouse conditions with low computational cost[J]. Ecological Informatics,2015,29(2):139-146.
[39]Ueka Y,Arima S.Development of multi-operation robot for productivity enhancement of intelligent greenhouses:for construction of integrated pest management technology for intelligent greenhouses[J]. Environmental Control in Biology,2015,53(2):63-70.
[40]Osakabe M.Spider mite management using UVB in greenhouse[J]. IOBC/WPRS Bulletin,2016(120)43-44.
[41]Vakilian K A,Massah J.A farmer-assistant robot for nitrogen fertilizing management of greenhouse crops[J]. Computers and Electronics in Agriculture,2017(139)153-163.
[42]Berge T W,Utstumo T,Netland J.Field robots for research and developments in site-specific weed management Norwegian activities[J]. Applications of automated systems and robotics for crop protection in sustainable precision agriculture,2012(21)19:31-34.
[43]汪懋華. 工廠化農業的發展與工程科技創新[M]. 北京:北京出版社,2000.
[44]白人樸. 中國農業機械化與現代化——白人樸教授論文選集[M]. 北京:中國農業科學技術出版社,2012.
[45]Hu J P,Yan X Y,Ma J,et al.Dimensional synthesis and kinematics simulation of a high-speed plug seedling transplanting robot[J]. Computers and Electronics in Agriculture,2014(107)64-72.
[46]高國華,馮天翔,李福. 斜入式穴盤苗移栽手爪工作參數優化及試驗驗證[J]. 農業工程學報,2015,31(24):16-22.
[47]楊振宇,張文強,李偉,等. 利用單目視覺獲取缽苗移栽適合度信息的方法[J]. 農業工程學報,2014,30(3):112-119.
[48]楊振宇,張文強,李偉,等. 基于單目視覺的移栽缽苗葉片朝向的調整方法[J]. 農業工程學報,2014,30(14):26-33.
[49]王躍勇,于海業,劉媛媛. 基于雙目立體視覺的機械手移栽穴盤定位方法[J]. 農業工程學報,2016,32(5):43-49.
[50]趙鄭斌,王俊友,劉立晶,等. 穴盤育苗精密播種機的研究現狀分析[J]. 農機化研究,2015(8):1-5,25.
[51]胡建平,侯俊華,毛罕平. 磁吸式穴盤精密播種機的研制及試驗[J]. 農業工程學報,2003,19(6):122-125.
[52]張石平,夏靜,陳進. 氣吸振動式蔬菜穴盤育苗精密播種裝置的研究[J]. 農機化研究,2007(8):80-83,105.
[53]胡志新,翁淩霄,汪小志. 氣吸式自動穴盤育苗精量播種機設計——基于PLC控制[J]. 農機化研究,2016(10):87-91.
[54]朱盤安,李建平,樓建忠,等. 便攜式蔬菜穴盤自動播種機設計與試驗[J]. 農業機械學報,2016,47(8):7-13.
[55]周長吉. 溫室灌溉[M]. 北京:化學工業出版社,2005.
[56]楊仁全,王剛,周增産,等. 精密施肥機的研究與應用[J]. 農業工程學報,2005,21(增刊2):197-199.
[57]孫宜田,李青龍,孫永佳,等. 基于模糊控制的水肥藥一體化系統研究[J]. 農機化研究,2015(8):203-207.
[58]劉永華,俞衛東,沈明霞,等. 精准灌溉施肥自動控制系統的研發[J]. 節水灌溉,2014(12):80-83.
[59]劉永華,沈明霞,蔣小平,等. 水肥一體化灌溉施肥機吸肥器結構優化和性能試驗[J]. 農業機械學報,2015,46(11):76-81,48.
[60]袁洪波,李莉,王俊衡,等. 溫室水肥一體化營養液調控裝備設計與試驗[J]. 農業工學報,2016,32(8):27-32.
[61]房俊龍,宋金龍,張馨,等. 通用智能灌溉施肥機控制器研發[J]. 節水灌溉,2015(10):78-82.
[62]李堅,劉雲骥,王丹丹,等. 日光溫室小型水肥一體灌溉機設計及其控制模型的建立[J]. 節水灌溉,2017(4):87-91.
[63]沈明衛,郝飛麟. 內外遮陽對連棟塑料溫室內光環境的影響[J]. 農業機械學報,2004,35(5):110-116.
[64]周偉,王小旵. 基于CFD的Venlo溫室夏季組合降溫措施模擬研究[J]. 農機化研究,2015(3):20-24.
[65]Lin J B,Zhou Z K,Qin C,et al. Development of energy-storing high pressure spray cooling system[J]. Agricultural Engineering and Agricultural Machinery,2015,16(1):167-171.
[66]吳霞,王世榮,王小虎,等. 枸杞育苗溫室自動噴霧降溫控制器設計與應用[J]. 農業網絡信息,2015(8):67-70.
[67]胥芳,蔡彥文,陳教料,等. 濕簾-風機降溫下的溫室熱/流場模擬及降溫系統參數優化[J]. 農業工程學報,2015,31(9):201-208.
[68]張樹閣,宋衛堂,滕光輝,等. 濕簾風機降溫系統安裝高度對降溫效果的影響[J]. 農業機械學報,2006,37(3):91-94.
[69]郝允志,陳建,薛榮生,等. 小型扭矩回差式兩擋自動變速器[J]. 中國機械工程,2015,26(16):2249-2253.
[70]王元傑,劉永成,楊福增,等. 溫室微型遙控電動拖拉機的研制與試驗[J]. 農業工程學報,2012,28(22):23-29.
[71]盧毅,楊福增,劉永成,等. 微型電動拖拉機的研究與設計[J]. 機械設計,2013,30(3):82-85.
[72]曾晨,李兵,王小勇,等. 基于NSGA-Ⅱ算法的微耕機變速箱多目標優化設計[J]. 機械傳動,2016,40(7):87-91.
[73]高輝松,朱思洪,史俊龍,等. 溫室大棚用電動微耕機研制[J]. 機械設計,2012,29(11):83-87.
[74]曹峥勇,張俊雄,耿長興,等. 溫室對靶噴霧機器人控制系統[J]. 農業工程學報,2010,26(增刊):228-233.
[75]李東星. 自適應升降噴杆施藥系統的研發[J]. 農機化研究,2017(8):97-101.
[76]常澤輝,賈檸澤,侯靜,等. 聚光回熱式太陽能土壤滅蟲除菌裝置光熱性能[J]. 農業工程學報,2017,33(9):211-217.
[77]隋俊傑. 土壤電消毒滅蟲機在設施農業中的應用[J]. 農業工程,2012,2(增刊1):35-38.
[78]紀超,馮青春,袁挺,等. 溫室黃瓜采摘機器人系統研制及性能分析[J]. 機器人,2011,33(6):726-730.
[79]魏忠彩,李學強,孫傳祝,等. 馬鈴薯收獲與清選分級機械化傷薯因素分析[J]. 中國農業科技導報,2017,19(8):63-70.
[80]徐鵬,吳玉月,劉勐. 我國果蔬氣調保鮮技術及裝備的現狀及發展趨勢[J]. 包裝與食品機械,2016,34(6):51-54.
[81]高德,谷吉海,董靜,等. 臭氧果蔬保鮮包裝技術及試驗[J]. 農業機械學報,2006,37(8):190-193.
[82]齊飛. 論溫室産品的“低質-低價”趨向對溫室行業的影響[C]//2002年中國農業工程學會設施園藝工程學術年會.北京:中國農業工程學會,2002:13-15.

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備注/Memo

備注/Memo:
收稿日期:2018-03-16
基金項目:福建省科技重大專項(編號:2014NZ0002-2);福建省農業科學院科技創新團隊項目(編號:STIT2017-2-12);福建省農業科學院院管A類項目(編號:A2017-34)。
作者簡介:蒲寶山(1986—),男,福建漳州人,碩士,工程師,從事智慧農業、數字化制造等研究。E-mail:920253768@qq.com。
更新日期/Last Update: 2019-07-20