水箱大小和供水量对华北寒冷干旱地区雨水灌溉温室芸豆的影响

Agronomy Pub Date : 2024-08-12 DOI:10.3390/agronomy14081767
Mengmeng Sun, Jizong Zhang, Zhihui Wang, Jingxin Ran, Yunjie Han, Jianheng Zhang, Huibin Li, Lifeng Zhang
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引用次数: 0

摘要

河北省西北部是中国北方寒冷干旱地区,为应对该地区缺水问题,并解决抽水灌溉导致地下水位不断下降的问题,本研究调查了不同降水情景下雨水槽大小和供水量对温室芸豆产量的影响,以确定区域降水资源的生产潜力和开发策略。在年平均降水量背景下,芸豆产量随着蓄水池容积的增加和灌溉周期的缩短而增加。在 4 天灌溉周期内,当雨水蓄水池容积为 15.7 立方米时,芸豆的需水满足率达到 100%。针对 1992 年至 2023 年区域多年降水量的巨大差异,利用 20 年来的降水数据模拟了雨水收集的年效应,降水保证率为 80%。得出的平均最小减产率为 9.4%,相应的最小雨水箱容积为 29.5 立方米。通过叠加棚区和非棚区收集的雨水,不减产的蓄水池容积可减少到 20.0 立方米。排放水量和库存水量之和远大于各种供水情况下的缺水量。模拟和分析雨水蓄水池大小与供水量之间的关系对区域农田雨水收集的影响,为区域雨水蓄水设施的建设和供水效率提供了重要的影响数据。华北地区棚膜和棚区集雨温室种植的芸豆要实现高产稳产,每年生长季节仍需补充地下水灌溉 2.6 立方米。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Effect of Water Tank Size and Supply on Greenhouse-Grown Kidney Beans Irrigated by Rainwater in Cold and Arid Regions of North China
In response to water scarcity in the Bashang area of northwest Hebei Province, a cold and arid region in north China, and to address the diminishing groundwater levels caused by pumping irrigation, this study investigated the impact of rainwater tank size and water supply on kidney beans production in greenhouses under various precipitation scenarios to determine the production potential and development strategies for regional precipitation resources. Under the background of average annual precipitation, kidney bean yield increased with increasing reservoir volume and shorter irrigation cycles. Under a 4-day irrigation cycle, the water demand satisfaction rate of kidney beans reached 100% water demand when the rainwater tank size was 15.7 m3. Against the wide variation in multi-year regional precipitation from 1992 to 2023, the annual effect of rainwater harvest was simulated using precipitation data collected 20 years with an 80% precipitation guarantee rate. The average minimum yield reduction rate obtained was 9.4%, and the corresponding minimum rainwater tank size was 29.5 m3. By superimposing the rainwater harvested in the shed and nonshed areas, the volume of the reservoir without yield reduction could be reduced to 20.0 m3. The sum of discharged and inventory water was much greater than the water scarcity in each water supply situation. Simulating and analyzing the effect of the relationship between rainwater tank size and water supply on rainwater harvesting in regional farmland by year provides important data affecting the construction of regional rainwater storage facilities and water supply efficiency. To achieve a high, stable yield of kidney beans grown in a greenhouse with shed film and shed area rainwater harvesting in north China, 2.6 m3 supplementary groundwater irrigation is still needed during the annual growing season.
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