水分传感器埋设位置对温室基质栽培番茄生长特性的影响

doi:10.3969/j.issn.1004-1524.2017.06.11

浙江农业学报 ›› 2017, Vol. 29 ›› Issue (6): 933-942.DOI: 10.3969/j.issn.1004-1524.2017.06.11

水分传感器埋设位置对温室基质栽培番茄生长特性的影响

曹少娜¹, 李建设^1,2,*, 高艳明^1,2, 吴素萍³, 刘梦锦¹, 李娟¹

1.宁夏大学农学院,宁夏银川 750021;
2.宁夏现代设施园艺工程技术研究中心,宁夏银川 750021);
3.宁夏大学信息工程学院,宁夏银川 750021

收稿日期:2016-11-23 出版日期:2017-06-20 发布日期:2017-09-07
通讯作者: 李建设,E-mail: jslinxcn@163.com
作者简介:曹少娜(1989—),女,宁夏固原人,硕士研究生,研究方向为蔬菜栽培生理与生态。E-mail: 1099034545@qq.com
基金资助:
国家科技支撑计划项目(2014BAD05B02); 宁夏科技支撑计划项目(2015BN03)

Effects of embedding position of moisture sensors on growth characteristics of tomato in substrate culture in greenhouse

CAO Shaona¹, LI Jianshe^1,2,*, GAO Yanming^1,2, WU Suping³, LIU Mengjin¹, LI Juan¹

1. School of Agriculture, Ningxia University, Yinchuan 750021, China;
2. Ningxia Modern Facilities Horticultural Engineering Technology Research Center, Yinchuan 750021, China;
3. College of Information Engineering, Ningxia University, Yinchuan 750021, China

Received:2016-11-23 Online:2017-06-20 Published:2017-09-07

摘要/Abstract

摘要： 为研究实时控制灌溉系统下水分传感器埋设位置对温室基质栽培番茄生长特性的影响,提高温室基质栽培水分管理的精准化、智能化。以京番301为试验材料,采用单因素随机区组试验设计,共设6个处理,每处理重复3次,共需18个水分传感器。采用相同的水分上下限指导灌溉,分析不同处理对番茄的生长指标、光合指标、品质、产量、干物质、灌溉指标及植株养分的影响。结果表明,T3(距滴头水平距离10 cm,距滴头垂直距离10 cm)处理生长指标较好,根系发达,净光合速率和蒸腾速率累计值均最大,植株鲜质量最大,干物质积累最多,根冠比也最大。T1(距滴头水平距离5 cm,距滴头垂直距离10 cm)处理植株养分积累最多,T4(距滴头水平距离10 cm,距滴头垂直距离15 cm)处理光能捕获效率最高。但T3处理番茄果实口感较好,Vc含量最高,产量最大为59 749.21 kg·hm^-2,显著高于其他处理;水分生产效率也最高为9.58 kg·m^-3,并显著优于T2(距滴头水平距离5 cm,距滴头垂直距离15 cm)处理。综上,对于基质槽栽培番茄来说,在采用1个水分传感器监测水分的条件下,将其埋设在距滴头水平距离10 cm,距滴头垂直距离10 cm位置更合理。

关键词: 番茄, 基质, 传感器, 埋设位置

Abstract: In order to study the effects of moisture sensor embedded position of real-time control irrigation system on growth characteristics of tomato in greenhouse, and to improve the precision and intelligence of water management in greenhouse substrate culture, the variety of Jingfan 301 was selected as the tested tomato, and single factor randomized block design of experiment was carried out with a total of 6 treatments and 3 replicates in each treatment. Using the same water upper and lower control irrigation, the effect of different treatments on growth indicators, photosynthetic indexes, quality, yield, dry matter, irrigation indicators and plant nutrients of tomato were analyzed. The results showed that T3 treatment (horizontal distance of 10 cm, vertical distance of 10 cm) had stronger root system, higher root to shoot ratio; and the accumulated values of net photosynthetic rate and transpiration rate were the highest, as well as the biggest plant fresh weight. T1 treatment (horizontal distance of 5 cm, vertical distance of 10 cm) had biggest plant nutrient accumulation. T4 treatment (horizontal distance of 10 cm, vertical distance of 15 cm) had highest light energy conversion. But, T3 treatment (horizontal distance of 10 cm, vertical distance of 10 cm) showed the highest ratio of sugar to acid and Vc content, and the production was up to 59 749.21 kg·hm^-2, significantly higher than other treatments. Water production efficiency in T3 treatment (horizontal distance of 10 cm, vertical distance of 10 cm) was the highest, which was up to 9.58 kg·m^-3 and better than that of T2 treatment (horizontal distance of 5 cm, vertical distance of 15 cm). According to the comprehensive analysis, for greenhouse tomatoes, the matrix moisture sensor at 10 cm from horizontal distance and 10 cm below the dripper was the suggested treatment.

Key words: tomato, matrix, sensor, position

中图分类号:

S626.5

曹少娜, 李建设, 高艳明, 吴素萍, 刘梦锦, 李娟. 水分传感器埋设位置对温室基质栽培番茄生长特性的影响[J]. 浙江农业学报, 2017, 29(6): 933-942.

CAO Shaona, LI Jianshe, GAO Yanming, WU Suping, LIU Mengjin, LI Juan. Effects of embedding position of moisture sensors on growth characteristics of tomato in substrate culture in greenhouse[J]. , 2017, 29(6): 933-942.

参考文献

[1] 徐丹华, 戴景双. 传感技术的发展及在现代农业中的应用[J]. 农业工程,2011,1(3):33-36.
XU D H, DAI J S. Development of sensing technology and its application in modern agriculture[J]. Agricultural Engineering ,2011,1(3):33-36.(in Chinese)
[2] COELHO E F, OR D. Flow and uptake patterns affecting soil water sensor placement for drip irrigation management [J]. Transactions of the ASAE ,1996,39(6):2007-2016.
[3] 赵伟霞, 李久生, 王珍,等. 土壤含水率监测位置对温室滴灌番茄耗水量估算的影响[J]. 中国生态农业学报,2014,22(1):37-43.
ZHAO W X, LI J S, WANG Z, et al. Estimation of water consumption as affected by measurement locations of soil water content in drip irrigated tomato in solar greenhouses[J]. Chinese Journal of Eco-Agriculture , 2014, 22(1): 37-43. (in Chinese with English abstract)
[4] 樊军, 王全九, 汪羽宁. 质地和根系深度对水分探头埋设的仿真模拟[J]. 排灌机械工程学报,2013,31(1):70-74.
FAN J, WANG Q J, WANG Y N. Simulated effects of texture and rooting depth on soil moisture sensor placement[J]. Journal of Drainage and Irrigation Machinery Engineering , 2013,31(1):70-74.(in Chinese with English abstract)
[5] 汪羽宁, 樊军, 李世清,等,小麦实时控制灌溉的土壤水分含量探头合理埋设深度研究[J]. 灌溉排水学报,2009,28(5):10-12.
WANG Y N, FAN J, LI S Q. Experiment research on infiltration and drainage in layered soil under furrow irrigation[J]. Journal of Irrigation and Drainage , 2009, 28(5):10-12.(in Chinese with English abstract)
[6] HAMAN D Z, ROSS D S, GRABOW G, et al. Critical management issues for SDI systems in North Carolina[EB/OL].(2008-06-25)[2016-09-29]. https://www.bae.ncsu.edu/topic/go_irrigation/docs/695-4.pdf.
[7] 刘浩,马富裕,崔静,等.棉花膜下滴灌农田单点墒情监测模拟模型的建立与检验[J].石河子大学学报(自然科学版),2010,28(6):761-766.
LIU H, MA F Y, CUI J, et al. Establishment and cultivation with drip irrigation under mulch[J]. Journal of Shihezi University ( Natural Science ),2010,28(6):761-766. (in Chinese with English abstract)
[8] 申孝军,孙景生,张寄阳,等. 滴灌棉田土壤水分测点最优布设研究[J].干旱地区农业研究,2012,30(3):91-95.
SHEN X J,SUN J S,ZHANG J Y,et al. Study on the placement of sensors for moisture content in soil profile for cotton under mulched drip irrigation condition[J]. Agricultural Research in the Arid Areas ,2012,30(3):90-95. (in Chinese with English abstract)
[9] 王峰,孙景生,刘祖贵,等.膜下滴灌棉田测墒点布设位置试验研究[J].灌溉排水学报,2016,35(2):29-34.
WANG F,SUN J S,LIU Z G,et al. Sensor placement of soil water monitoring in cotton field using drip irrigation under plastic film mulch[J]. Journal of Irrigation and Drainage ,2016,35(2):29-34. (in Chinese with English abstract)
[10] 余荣,汪小旵.滴灌条件下黄棕壤土水分运动规律研究[J].节水灌溉,2010(10):1-4.
YU R, WANG X C. Experimental study on yellow brown soil water movement under drip irrigation[J]. Journal of Water Saving Irrigation ,2010(10):1-4.(in Chinese)
[11] 卢佳骏. 草莓高架基质栽培的基质水分扩散和草莓胜利特性及滴管控制系统研究[D]. 镇江:江苏大学,2016:10-16.
LU J J. Study on water transport, physiology drip and irrigation control system of strawberry elevated substrate cultivation[D]. Zhenjiang: Jiangsu University,2016:10-16.(in Chinese with English abstract)
[12] 闫华. 典型作物设施农业灌溉决策系统研究与实现[D].北京:中国农业大学,2016:10-12.
YAN H. Study and implementation of irrigation decision system for typical crop in facility agriculture[D]. Beijing:China Agricultural University, 2016:10-12.(in Chinese with English abstract)
[13] 蒋卫杰.设施蔬菜生态基质无土栽培技术[EB/OL]. (2013-07-03). http://www.caas.net.cn/zt/bxzdtgcg/xjz/74253.shtml.
[14] 张艳玲,欧阳竹,郭建青,等.作物根层土壤水分动态监测最佳测量深度研究[J].中国农村水利水电, 2010(9):102-104.
ZHANG Y L,OUYANG Z,GUO J Q, et al. Research on the best measurement depth for determining the dynamic soil moisture content of root layer soil moisture[J]. China Rural Water and Hydropower , 2010(9):102-104. (in Chinese with English abstract)
[15] 魏恒文,陈希东,尹明玉. 智能滴灌系统中土壤水分传感器埋设深度研究[J]. 灌溉排水学报,2010,29(4):16-20.
WEI H W, CHEN X D, YIN M Y. Burying depth of soil moisture sensors in intelligent drip irrigation system[J]. Journal of Irrigation and Drainage ,2010,29(4):16-20. (in Chinese with English abstract)
[16] 韩玉国,武亨飞,杨培岭,等. 番茄种植地土壤水分传感器最佳埋设深度试验[J]. 水土保持通报,2013,33(4):260-263.
HAN Y G, WU H F, YANG P L, et al. Optimal burial depth of soil moisture sensors for tomato planting field[J]. Bulletin of Soil and Water Conservation , 2013,33(4):260-263. (in Chinese with English abstract)
[17] 吕剑,颉建明,郁继华,等.灌水下限对基质栽培番茄生长、水分利用效率及果实品质的影响[J].甘肃农业大学学报,2013, 48(1):37-41.
LV J, JIE J M, YU J H, et al. Effects of irrigation lower limit on growth, utilization efficiency of water and quality of tomato under substrate culture[J]. Journal of Gansu Agricultural university , 2013, 48(1):37-41.(in Chinese with English abstract)
[18] 吴远藩.量叶片长和宽计算番茄叶面积[J].农业科技通讯,1980(12):21-22.
WU Y F.Calculate leaf area of tomato through measure length and width [J]. Agricultural Science and Technology ,1980(12): 21-22.(in Chinese)
[19] 邹琦. 植物生理学实验指导[M].北京:中国农业出版社,2000: 22-22, 173-174, 161-162, 110-112.
[20] 鲁如坤. 土壤农业化学分析方法[M]. 北京: 中国农业科技出版社, 2000:302-316.
[21] 王绍辉,张福墁. 不同水分处理对日光温室黄瓜叶片光合特性的影响[J]. 植物学通报,2002,19(6):727-733.
WANG S H, ZHANG F M. Effects of different water treatments on photosynthetic characteristics of cucumber leaves in solar greenhouse[J]. Bulletin of Botany , 2002,19(6):727-733.(in Chinese with English abstract)
[22] 方栋平. 温室黄瓜对不同灌水量和滴灌施肥方式的响应机制研究[D]. 杨凌:西北农林科技大学,2015:50-51.
FANG D P. Response mechanism of cucumber to different irrigation quantity and drip irrigation and fertilization in greenhouse[D]. Yangling: Northwest A&F University,2015:50-51.(in Chinese with English abstract)
[23] 武慧平,朱铭强,张盼盼,等.土壤含水量对温室樱桃番茄生长发育及果实品质的影响[J].干旱地区农业研究,2012,30(4):32-36.
WU H P, ZHU M Q, ZHANG P P, et al. Effects of soil moisture on growth and fruit quality of greenhouse cherry tomato[J]. Agricultural Research in the Arid Areas , 2012,30(4):32-36.(in Chinese with English abstract)
[24] BASCLGA Y J J, PRIETO LMH,RODRIGUEZ D R A. Response of processing tomato to three different levels of water and nitrogen applications[J]. Acta Horticulturae , 1993,335:149-156.
[25] 袁丽萍,米国全,赵灵芝,等. 水氮耦合供应对日光温室番茄产量和品质的影响[J]. 中国土壤与肥料,2008(2):69-73.
YUAN L P, MI G Q, ZHAO L Z, et al. Effects of water and nitrogen supply on yield and quality of tomato in solar greenhouse[J]. Soil and Fertilizer Sciences in China , 2008(2):69-73. (in Chinese with English abstract)

水分传感器埋设位置对温室基质栽培番茄生长特性的影响

Effects of embedding position of moisture sensors on growth characteristics of tomato in substrate culture in greenhouse

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