Progress in research and application of soil steam disinfection technology

doi:10.13733/j.jcam.issn.20955553.2022.06.026

Abstract

Abstract: In recent years, the problem of soil continuous cropping obstacles has attracted widespread attention from scholars worldwide. This problem has severely restricted the sustainable development of the agricultural economy. Soil steam disinfection technology that is important for preventing and controlling soilborne diseases can effectively alleviate the problems caused by continuous cropping obstacles. This technology has the advantages of high efficiency, environmental protection, and cleanliness. This paper first introduces the basic principles and research status of soil steam disinfection technology. Secondly, it discusses the research progress of soil steam disinfection technology from the aspects of disinfection methods and terminal disinfection mechanism parameters. It points out the existing problems of the soil steam disinfection technology and its equipment, that is, not only failed to select a reasonable disinfection method and optimize the design of terminal disinfection mechanism according to the soil type but also lacked the research on the relationship between soil temperature field and harmful bacteria and viruses, the causes of continuous cropping obstacles caused by different crops, and the application of soil steam disinfection technology in facility agriculture. Finally, this paper points out the key research directions of soil steam disinfection technology in the future, that is, developing new disinfection methods, optimizing terminal disinfection mechanism, carrying out the research on the relationship between soil temperature field and harmful bacteria killing rate, deepening the research on continuous cropping obstacles in different crops, and carrying out the application of soil steam disinfection technology in facility agriculture.

Key words: steam disinfection technology, continuous obstacle, steam sterilizer, soil

摘要： 近年来，土壤连作障碍问题引起国内外学者广泛关注，该问题严重制约农业经济的可持续发展，而土壤蒸汽消毒技术可以有效地缓解土壤连作障碍问题，该技术具有高效、环保和清洁等优点。首先介绍土壤蒸汽消毒技术的基本原理和研究现状；其次，从土壤蒸汽消毒方式和末端蒸汽消毒机构的参数方面论述土壤蒸汽消毒技术的研究及应用进展，从而指出土壤蒸汽消毒技术及其机具现存的问题，即不仅未能根据土壤类型选择合理的消毒方式和优化设计末端消毒机构，而且缺乏对土壤温度场与有害菌和病毒之间关系、不同作物引起连作障碍原因的研究，同时也缺乏对土壤蒸汽消毒技术在设施农业中的应用；最后，指出未来土壤蒸汽消毒技术的重点研究方向，即研发新型消毒方式、优化末端消毒机构、开展土壤温度场和有害菌灭杀率二者关系的研究，并且要加深针对不同作物中连作障碍问题的研究和开展土壤蒸汽消毒技术在设施农业中的应用。

关键词: 蒸汽消毒技术, 连作障碍, 蒸汽消毒机, 土壤

CLC Number:

S472

Song Yue, Wang Shengbei, Zhang Yiijie, Li Long, Zhang Yuqian, Yang Zhenjie.. Progress in research and application of soil steam disinfection technology[J]. Journal of Chinese Agricultural Mechanization, 2022, 43(6): 199-206.

宋悦, 王生北, 张毅杰, 李龙, 张宇乾, 杨振杰. 土壤蒸汽消毒技术研究与应用进展[J]. 中国农机化学报, 2022, 43(6): 199-206.

References

［1］徐丽慧, 曾蓉, 高士刚, 等. 土壤真菌多样性对土传病害影响的研究进展［J］. 上海农业学报, 2017, 33（3）: 161-165.
Xu Lihui, Zeng Rong, Gao Shigang, et al. Review on the effect of soil fungal communities on soilborne diseases ［J］. Acta Agriculturae Shanghai, 2017, 33（3）: 161-165.
［2］ Nishimura A, Asai M, Shibuya T, et al. A steaming method for killing weed seeds produced in the current year under untilled conditions ［J］. Crop Protection, 2015, 71: 125-131.
［3］马薇薇. 分析作物土传病害的危害及防治技术［J］. 花卉, 2020（8）: 263-264.
［4］李荷衣, 刘文钰. 作物土传病害的危害及防治技术探析［J］. 南方农机, 2019, 50（2）: 51.
［5］袁承志, 张定祥, 刘黎明, 等. 近10年中国耕地变化的区域特征及演变态势［J］. 农业工程学报, 2021, 37（1）: 267-278.
Yuan Chengzhi, Zhang Dingxiang, Liu Liming, et al. Regional characteristics and spatialtemporal distribution of cultivated land change in China during 2009—2018 ［J］. Transactions of the Chinese Society of Agricultural Engineering, 2021, 37（1）: 267-278.
［6］方文山, 曹坳程, 王秋霞, 等. 新型土壤消毒一体机提高棉隆土壤分布均匀性［J］. 中国农业科学, 2021, 54（12）: 2570-2580.
Fang Wenshan, Cao Aocheng, Wang Qiuxia, et al. A new integrated soil disinfection machine improves the uniformity of dazomet in soil ［J］. Scientia Agricultura Sinica, 2021, 54（12）: 2570-2580.
［7］李明, 詹鹏杰. 大棚蔬菜连作障碍发生原因及应对措施［J］. 农业技术与装备, 2016（6）: 56-58.
Li Ming, Zhan Pengjie. Causes for continuous cropping obstacles of greenhouse vegetables and solutions ［J］. Agricultural Technology & Equipment, 2016（6）: 56-58.
［8］张庭发, 杨进波, 易小光, 等. 土壤消毒方法综述［J］. 云南农业, 2017（12）: 43-45.
［9］杨明慧. 连作对土壤性质和植物生长的影响以及缓解措施［J］. 农村实用技术, 2021（3）: 94-95.
［10］曹坳程, 刘晓漫, 郭美霞, 等. 作物土传病害的危害及防治技术［J］. 植物保护, 2017, 43（2）: 6-16.
Cao Aocheng, Liu Xiaoman, Guo Meixia, et al. Incidences of soilborne diseases and control measures ［J］. Plant Protection, 2017, 43（2）: 6-16
［11］王宁堂, 张宁, 张阿宁, 等. 草莓连作障碍及当前常用的几种综合防治措施［J］. 陕西农业科学, 2021, 67（5）: 78-81.
Wang Ningtang, Zhang Ning, Zhang Aning, et al. Continuous cropping obstacles of strawberry and several comprehensive common measures for control ［J］. Shaanxi Journal of Agricultural Sciences, 2021, 67（5）: 78-81
［12］薛玉梅. 玉米土传病害的种类及防治措施［J］. 河南农业, 2021（10）: 46-47.
［13］苏琦, 黄欢. 从专利视角看全球土壤蒸汽消毒技术发展［J］. 安徽农学通报, 2016, 22（11）: 68-69.
Su Qi, Huang Huan. Technology development of global sterilizing soil by steam from the perspective of patent ［J］. Anhui Agricultural Science Bulletin, 2016, 22（11）: 68-69.
［14］许永福. 刺罩式土壤蒸汽除草消毒装置设计及试验［D］. 杨凌: 西北农林科技大学, 2020.
［15］ Melander B, Kristensen J K. Soil steaming effects on weed seedling emergence under the influence of soil type, soil moisture, soil structure and heat duration ［J］. Annals of Applied Biology, 2011, 158（2）.
［16］曹鹏, 付学鹏, 王绍娴, 等. 土壤高压蒸汽灭菌的条件优化及其对植物生长的影响［J］. 江苏农业科学, 2016, 44（9）: 456-458.
［17］胡学军, 孙海, 田蒙生, 等. 农艺措施及土壤消毒对设施草莓土传病害的防效［J］. 中国植保导刊, 2021, 41（5）: 65-68.
［18］杨陆强, 赵玉清, 朱加繁, 等. 栽培基质物理消毒技术研究现状概述与评析［J］. 中国农机化学报, 2017, 38（2）: 100-107.
Yang Luqiang, Zhao Yuqing, Zhu Jiafan, et al. Review and comment of the research status of physical disinfection technology for cultivation matrix ［J］. Journal of Chinese Agricultural Mechanization, 2017, 38（2）: 100-107.
［19］施新杭, 翁晓星, 黄赟, 等. 绿色环保高效的土壤消毒技术——火焰高温消毒分析［J］. 粮食科技与经济, 2019, 44（1）: 82-83, 92.
［20］宋樱. 土壤电处理消毒技术［N］. 中国农机化导报, 2014-03-17（008）.
［21］李长松. 土壤化学消毒剂及消毒技术［N］. 山东科技报, 2016-06-15（004）.
［22］王宁, 张锴, 郭建明. 国外土壤化学消毒研究介绍［J］. 农业工程技术（温室园艺）, 2014（5）: 28-29, 32.
［23］金娜, 王学艳, 刘倩, 等. 土壤生物熏蒸对蔬菜根结线虫及土壤线虫群落的影响［J］. 生物技术通报, 2021, 37（7）: 156-163.
Jin Na, Wang Xueyan, Liu Qian, et al. Effects of biofumigation on rootknot nematodes and soil nematode community ［J］. Biotechnology Bulletin, 2021, 37（7）: 156-163.
［24］张大琪, 颜冬冬, 方文生, 等. 生物熏蒸——环境友好型土壤熏蒸技术［J］. 农药学学报, 2020, 22（1）: 11-18.
Zhang Daqi, Yan Dongdong, Fang Wensheng, et al. Biofumigation—an environmentfriendly soil fumigation technology ［J］. Chinese Journal of Pesticide Science, 2020, 22（1）: 11-18.
［25］ Raffaellia M, Martelloni L, Frasconi C. A prototype bandsteaming machine: Design and field application ［J］. Biosystems Engineering, 2016, 144: 61-71.
［26］许永福. 刺罩式土壤蒸汽除草消毒装置设计及试验［D］. 杨凌: 西北农林科技大学, 2020.
［27］ Michuda A, Goodhue R E, Hoffmann M, et al. Predicting net returns of organic and conventional strawberry following soil disinfestation with steam or steam plus additives ［J］. Agronomy, 2021, 11（1）: 149-169.
［28］曹坳程, 郭美霞, 王秋霞, 等. 世界土壤消毒技术进展［J］. 中国蔬菜, 2010（21）: 17-22.
［29］龚宪成. 自控温室内土壤盐渍化防治措施［J］. 中国生态农业学报, 2002, 10（4）: 75-76.
Gong Xiancheng. The reason of forming salinized soil and its prevention in automatic greenhouse ［J］. Chinese Journal of EcoAgriculture, 2002, 10（4）: 75-76.
［30］陈实, 杨秀春. 石河子区域土壤盐渍化防治对策分析［J］. 中国农垦, 2015（3）: 37-38.
［31］陆燕雯. 浦东新区设施土壤盐渍化防治修复技术操作规程［J］. 上海蔬菜, 2011（2）: 60-61.
［32］曹力强, 张旦. 杏树温室栽培土壤盐渍化防治技术研究［J］. 林业科技通讯, 2017（6）: 52-53.
［33］葛涛, 国晓文. 辽西地区设施温室土壤连作障碍成因及综合防控对策［J］. 现代农村科技, 2021（2）: 34.
［34］ Gay P, Piccarolo P, Ricaud D, et al. A high efficiency steam soil disinfestation system, part I: Physical background and steam supply optimization ［J］. Biosystems Engineering, 2010, 107（2）: 74-85.
［35］ Gay P, Piccarolo P, Aimonino D, et al. A high efficiency steam soil disinfestation system, part II: Design and testing ［J］. Biosystems Engineering, 2010, 107: 194-201.
［36］ Fennimore S, Martin F. Mixing steam with soil increases heating rate compared to steam applied to still soil ［J］. Crop Protection, 2014, 64（12）: 47-50.
［37］杨振杰. 注入式蒸汽消毒传热机理研究与装备研制［D］. 南京: 南京农业大学, 2020.
［38］ Peruzzi A, Raffaelli M, Ginanni M, et al. An innovative selfpropelled machine for soil disinfection using steam and chemicals in an exothermic reaction ［J］. Biosystems Engineering, 2011, 110: 434-442.
［39］杨志林. 移动式蒸汽土壤灭菌设备的研究［J］. 机械工程与自动化, 2015（5）: 194-195.
Yang Zhilin. Research on mobile soil steam sterilization equipment ［J］. Mechanical Engineering & Automation, 2015（5）: 194-195.
［40］曹坳程, 郭美霞, 王秋霞, 等. 世界土壤消毒技术进展［J］. 中国蔬菜, 2010（21）: 17-22.
［41］张浩然, 杨宁, 温丹, 等. 土壤消毒技术在设施蔬菜生产中的研究进展［J］. 山东农业科学, 2020, 52（5）: 149-156.
［42］喻自荣. 移动式温室育苗基质蒸汽消毒机设计与研究［D］. 昆明: 云南农业大学, 2016.
［43］施印炎, 李成光, 汪小旵, 等. 可移动式土壤蒸汽消毒机的设计［J］. 中国农机化学报, 2017, 38（1）: 56-59.
Shi Yinyan, Li Chengguang, Wang Xiaochan, et al. Design of removable soil steam sterilization machine ［J］. Journal of Chinese Agricultural Mechanization, 2017, 38（1）: 56-59.
［44］刘兴达. 分体式深旋耕土壤消毒联合作业机研制与试验［D］. 镇江: 江苏大学, 2020.
［45］张庭发, 杨进波, 易小光, 等. 土壤消毒方法综述［J］. 云南农业, 2017（12）: 43-45.
［46］徐晓婕, 李纪周. 土壤蒸汽消毒机在日光温室的应用试验［J］. 天津农林科技, 2020（4）: 12-13, 16.
［47］汪小旵, 李成光, 杨振杰, 等. 移动式土壤旋耕蒸汽消毒机的研制［J］. 农业工程学报, 2018, 34（2）: 18-24.
Wang Xiaochan, Li Chengguang, Yang Zhenjie, et al. Development of mobile soil rotary tillage steam sterilizer ［J］. Transactions of the Chinese Society of Agricultural Engineering, 2018, 34（2）: 18-24.
［48］耿增超, 戴维. 土壤学［M］. 北京: 科学出版社, 2011.
［49］王凤花, 宋彦, 赖庆辉, 等. 三七土壤水蒸汽消毒针结构设计与试验［J］. 农业机械学报, 2019, 50（8）: 123-130.
Wang Fenghua, Song Yan, Lai Qinghui, et al. Structural design and test of soil steam disinfection needle in Panax notoginseng field ［J］. Transactions of the Chinese Society for Agricultural Machinery, 2019, 50（8）: 123-130.
［50］ Yang Zhenjie, Wang Xiaochan, Muhammad Ameen. Influence of the spacing of steaminjecting pipes on the energy consumption and soil temperature field for clayloam disinfection ［J］. Energies, 2019, 12（17）.
［51］孟天竹, 郭德杰, 王光飞, 等. 土壤消毒结合施用生物有机肥对西瓜病土改良效果的影响［J］. 土壤, 2020, 52（3）: 494-502.
Meng Tianzhu, Guo Dejie, Wang Guangfei, et al. Effect of combination of soil disinfestation and bioorganic fertilizer application on improving watermelon diseased soil ［J］. Soil, 2020, 52（3）: 494-502.
［52］刘亮亮, 周开胜, 黄新琦, 等. 低温茬口空闲期土壤强还原消毒对西瓜枯萎病的影响［J］. 应用生态学报, 2021, 32（8）: 2967-2974.
Liu Liangliang, Zhou Kaisheng, Huang Xinqi, et al. Effects of reductive soil disinfestation during lowtemperature stubble free period on the control of watermelon Fusarium wilt ［J］. Chinese Journal of Applied Ecology, 2021, 32（8）: 2967-2974.
［53］宋修超, 罗佳, 马艳, 等. 加热消毒设备处理西瓜重茬基质工艺优化及栽培效果［J］. 农业工程学报, 2019, 35（11）: 167-174.
Song Xiuchao, Luo Jia, Ma Yan, et al. Parameter optimization of heating disinfection machine handling watermelon continuous cultivation substrate and cultivation effect ［J］. Transactions of the Chinese Society of Agricultural Engineering, 2019, 35（11）: 167-174.
［54］王于璇, 王蕴辉, 王丹. 设施蔬菜土传病害的防治措施［J］. 天津农林科技, 2020（6）: 24-25, 28.
［55］郑磊. 设施农业生产中存在的问题及发展建议［J］. 河南农业, 2021（7）: 58-59.
［56］孟越. 设施农业土壤障碍因子分析及治理［J］. 农业与技术, 2016, 36（14）: 21.
［57］蔡群虎, 刘石磊, 袁敏惠, 等. 三七多糖含量测定方法比较［J］. 云南中医中药杂志, 2020, 41（8）: 59-62.
Cai Qunhu, Liu Shilei, Yuan Minhui, et al. Comparison of determination methods of polysaccharide content in Panax Notoginseng ［J］. Yunnan Journal of Traditional Chinese Medicine and Materia Medica, 2020, 41（8）: 59-62.
［58］杨馨, 孟鈺, 李梅蓉, 等. 云南三七病毒病的发生及病毒种类检测［J］. 植物病理学报, 2019, 49（4）: 456-464.
Yang Xin, Meng Yu, Li Meirong, et al. Occurrence and virus detection of Panax notoginseng viral diseases in Yunnan Province ［J］. Acta Phytopathologica Sinica, 2019, 49（4）: 456-464.
［59］张晋豪, 杨俊, 姬广海, 等. 云南三七根腐病病原细菌的鉴定［J］. 南方农业学报, 2020, 51（3）: 586-592.
Zhang Jinhao, Yang Jun, Ji Guanghai, et al. Bacterial pathogen identification of Panax notoginseng root rot in Yunnan Province ［J］. Journal of Southern Agriculture, 2020, 51（3）: 586-592.
［60］罗丽芬, 江冰冰, 邓琳梅, 等. 三七根系分泌物中几种成分对根腐病原菌生长的影响［J］. 南方农业学报, 2020, 51（12）: 2952-2961.
Luo Lifen, Jiang Bingbing, Deng Linmei, et al. Effects of some components in root exudates of Panax notoginseng （Bark） F. H. Chen on the growth of root rot pathogens ［J］. Journal of Southern Agriculture, 2020, 51（12）: 2952-2961.
［61］张加云, 陈瑶, 朱勇, 等. 基于相似气象年型和关键气象因子的云南一季稻动态产量预报［J］. 中国农学通报, 2020, 36（34）: 96-99.
Zhang Jiayun, Chen Yao, Zhu Yong, et al. Dynamic prediction of single cropping rice yield based on similar meteorological year type and key meteorological factors in Yunnan ［J］. Chinese Agricultural Science Bulletin, 2020, 36（34）: 96-99.
［62］陈林, 于英杰, 戈振扬, 等. 去除红壤土结皮与土壤深松对玉米生长的影响［J］. 江苏农业科学, 2015, 43（12）: 82-85.
［63］浦吉存, 黄中艳, 高敏. 云南气候特征与主要经济作物种植适宜性的关系［J］. 气象研究与应用, 2021, 42（1）: 53-57.
Pu Jicun, Huang Zhongyan, Gao Min. Relationship between climatic characteristics and planting suitability of main cash crops in Yunnan ［J］. Journal of Meteorological Research and Application, 2021, 42（1）: 53-57.
［64］叶长榄. 关于设施农业温室大棚发展的思考［J］. 福建农机, 2020（4）: 6-10, 17.
Ye Changlan. Thoughts on the development of greenhouse in facility agriculture ［J］. Fujian Agricultural Machinery, 2020（4）: 6-10, 17.
［65］徐磊. 福建设施农业温室大棚适用棚型集成推广［J］. 中国蔬菜, 2021（10）: 122-127.

[1]	Dai Zhiwei, Cheng Man, Yuan Hongbo, Cai Zhenjiang.. Review of irrigation control strategy for greenhouse [J]. Journal of Chinese Agricultural Mechanization, 2022, 43(9): 63-72.
[2]	Li Yiwei, Liu Xinping. . Analysis on the spatial differentiation characteristics of main nutrients in cultivated land quality: A case study of Yecheng County, Xinjiang Province [J]. Journal of Chinese Agricultural Mechanization, 2022, 43(7): 205-213.
[3]	Zhu Feiyu, Liu Muhua, Yuan Haichao, Zhao Jinhui, Yu Haojun. . Design of soil temperature and moisture monitoring system for vegetable field based on the Internet of Things [J]. Journal of Chinese Agricultural Mechanization, 2022, 43(6): 190-198.
[4]	Lin Hengchu, Wang Qi, Liao Peng, Zheng Wenxin, He Jincheng, Zhang Dehui.. Discrete element simulation parameter calibration for the interaction between vegetated sandy loam soil and soiltouching components [J]. Journal of Chinese Agricultural Mechanization, 2022, 43(5): 196-203.
[5]	Liu Dongxu, Ge Yiyuan, Yang Chuanhua, Wang Junfa, Chen Chao.. Simulation and experimental of scimitarstrawsoil interaction model based on discrete element method [J]. Journal of Chinese Agricultural Mechanization, 2022, 43(4): 1-6.
[6]	Zhang Baochang, Hu Peijie, Chen Weipeng, Qiu Tianyuan, Yang Shandong.. Design and experiment of notillage fertilizer planter for wheat with wide seedling belt [J]. Journal of Chinese Agricultural Mechanization, 2022, 43(2): 22-27.
[7]	Fang Xuefeng, Guo Guanzhu, Duan Qingsong, Zhang Yingchao, Chen Jie, Chen Lichang.. Design and test of insitu shearing device for underwater rootsoil complex [J]. Journal of Chinese Agricultural Mechanization, 2022, 43(10): 33-41.
[8]	Li Yuyao, Yang Hongguang, Wang Bing, Wu Feng, Gu Fengwei, Fan Jiali. . Study on technology and device of potato and soil separation in potato combined harvest [J]. Journal of Chinese Agricultural Mechanization, 2022, 43(10): 42-50.
[9]	Jin Wenting, Ge Yiyuan, Fan Wenwu, Ma Liuxuan, Li Wenlong, Yang Rongmin.. Virtual simulation and verification of inverted Vshaped interplant weeding device for paddy field [J]. Journal of Chinese Agricultural Mechanization, 2022, 43(10): 72-77.
[10]	Geng Yuanle, Zhong Xiaokang, Wang Xianliang, Zhang Xiangcai, Wei Zhongcai, Wu Dong.. Research on precise regulation of notillage seeder compaction pressure [J]. Journal of Chinese Agricultural Mechanization, 2022, 43(10): 141-148.
[11]	Wang Xiaoyang, Pan Rui, Qiang Hua, Zhang Zhihong, Wu Shihui, Xue Zhong.. Design and experiment of bionic geometric structure surface on the tip of subsoiler [J]. Journal of Chinese Agricultural Mechanization, 2022, 43(1): 1-6.
[12]	Niu Cong, Zeng Jian, Xu Liming, Ma Shuai, Yan Chenggong, Zhao Shijian.. Development of grapevine coldproof soil clearing machine with airblowing type and comb brush type [J]. Journal of Chinese Agricultural Mechanization, 2022, 43(1): 47-54.
[13]	Liu Kunyu, Su Hongjie, Li Feiyu, Jiao Wei.. Research on parameter calibration of soil discrete element model based on response surface method [J]. Journal of Chinese Agricultural Mechanization, 2021, 42(9): 143-149.
[14]	Wang Lianji, Liao Jinyang, Hu Hong, Liu Lu, Bai Xin, Chen Chunlin.. Research status and prospect of adhesion reduction and desorption technology for agricultural machinery parts touching soil [J]. Journal of Chinese Agricultural Mechanization, 2021, 42(8): 214-221.
[15]	Qin Jianming, Zhang Guiyun, Wang Dongdong, Zhao Mengdie. . Study on the change law of soil water content in a national reserve forest [J]. Journal of Chinese Agricultural Mechanization, 2021, 42(12): 150-154.