Screening of the Water Drainage and Salt Control Mode of Subsurface Pipe and Shaft on the Secondary Salinization Soil and Its Effect Evaluation

doi:10.6048/j.issn.1001-4330.2022.03.022

Xinjiang Agricultural Sciences ›› 2022, Vol. 59 ›› Issue (3): 716-724.DOI: 10.6048/j.issn.1001-4330.2022.03.022

• Prataculture·Forestry·Soil Fertilizer·Water Saving Irrigation·Agroecological Environment • Previous Articles Next Articles

Screening of the Water Drainage and Salt Control Mode of Subsurface Pipe and Shaft on the Secondary Salinization Soil and Its Effect Evaluation

SHI Lei¹^,²(), LÜ Ning¹^,³, HE Shuai¹^,², YIN Feihu¹(), GAO Zhijian¹^,², TAN Rongxin⁴

1. Institute of Farmland Water Conservancy and Soil-fertilizer, Xinjiang Academy of Agricultural Reclamation Sciences, Shihezi Xinjiang 832000, China
2. Experimental Station for Crop Water Use of Ministry of Agriculture, Shihezi Xinjiang 832000, China
3. College of Economics and Management, Shihezi University, Shihezi Xinjiang 832003, China
4. The 38th Regiment of the Second Division, Xinjiang Production and Construction Corps, Korla Xinjiang 841900, China

Received:2021-08-12 Online:2022-03-20 Published:2022-03-28
Correspondence author: YIN Feihu
Supported by:
Major Scientific and Technological Project of XPCC(2015AA001);Major Project of National Natural Science Fund(51790533)

次生盐渍土暗管+竖井排水控盐技术模式筛选及效果评价

石磊¹^,²(), 吕宁¹^,³, 何帅¹^,², 尹飞虎¹(), 高志建¹^,², 谭荣欣⁴

1.新疆农垦科学院农田水利与土壤肥料研究所,新疆石河子 832000
2.农业部作物高效用水石河子科学观测实验站,新疆石河子 832000
3.石河子大学经济与管理学院,新疆石河子 832003
4.新疆生产建设兵团第二师38团,新疆库尔勒 841900

通讯作者: 尹飞虎
作者简介:石磊(1983-),男,新疆乌鲁木齐人,助理研究员,研究方向为农业资源高效利、水肥一体化,(E-mail) nkyshilei0315@163.com
基金资助:
兵团重大科技计划(2015AA001);国家自然科学基金重大项目(51790533)

Abstract

Abstract:

【Objective】 The aim of this project is to evaluate the salt drainage effect by subsurface pipe and shaft technology on secondary salinized soil in southern Xinjiang and select out the suitable layout spacing of subsurface pipe project.【Methods】 The paper took the secondary salinized soil of the 38th regiment of the second division in Southern Xinjiang as an experimental area, and the field test of water and salt drainage by shaft (vertical drainage) + subsurface pipe (horizontal drainage) was carried out from 2016 to 2019. The 3 adjacent plots were selected and the layout spacing of subsurface pipe was set to 6, 8, 10 m (marked as T₁, T₂, T₃), respectively; the buried depth of subsurface pipe was set to 1.2 m and the depth and spacing of shaft was set to 20 and 120 m in each treatment. 【Results】 The results showed that (1) the soil salinity significantly decreased after 2 years salt drainage and the soil electrical conductivity (EC) in root layer of T₁, T₂ and T₃ was decreased by 31.83%, 50.35% and 46.09%, respectively; the varies of soil pH was not significant but was decreased with the salt drainage time increase, generally; (2) the soil EC was decreased with the soil depth increase, and the decrease rate of salt content in the 0-0.8 m soil layer was significantly higher than that in deep soil layers; moreover, the effect of salt drainage was more obvious when the distance was closer to the shaft; (3) the salinity of drainage water was increased after 1 year salt drainage, however which of T₁, T₂ and T₃ was decreased by 21.41%, 33.24% and 18.57% after 2 years salt drainage, respectively; the underground water level dropped down year by year and decreased by 1.5 m on the average; (4) the average maize yield of different treatments was 329.70 kg/667m², and the yield was T₂>T₁>T₃, which indicated that the salt drainage effect was in proportion to the maize yield.【Conclusion】 According to the effect of water and salt drainage and maize yield, the layout spacing of 8 m (T₂) was the suitable parameter for subsurface pipe project; it is suggested to apply the model of shaft and subsurface pipe drainage in in areas of southern Xinjing, which could effectively reduce groundwater level and salt content and maintain the stability and sustainability of the improvement effect of salinization soil.

Key words: secondary salinization soil; subsurface pipedrainage; shaft drainage; soil desalination effect; maize yield

摘要：

【目的】评价暗管、竖井工程在新疆南疆次生盐渍化土上的排盐效果,筛选出适宜的暗管布设间距。【方法】以新疆南疆垦区兵团第二师38团撂荒地次生盐渍化土为对象,于2016~2019年设置暗管+竖井田间排水控盐试验,选取3个相邻地块,暗管布设间距分别为6、8和10 m(依次记为T₁、T₂、T₃),每个地块暗管埋深1.2 m,竖井井深20 m、间距120 m。【结果】 (1)各处理土壤盐分在排水2年后均显著降低,T₁、T₂、T₃根层土壤电导率较排盐前分别下降了31.83%、50.35%、46.09%;(2)垂直方向上土壤电导率随土层深度增加而降低,各排盐处理0~0.8 m根层土壤电导率降低幅度显著高于深层土壤,水平方向上距离竖井越近脱盐效果越明显;(3)各处理排水矿化度在排盐1年后均升高,但在排盐2年后T₁、T₂ 、T₃处理分别下降了21.41%、33.24%、18.57%,排盐后地下水位深度平均降低了1.5 m;(4)脱盐2年后种植玉米,各处理平均籽粒单产达到329.70 kg/667m²,单产水平T₂>T₁>T₃,降盐效果与玉米产量呈正相关。【结论】优选出布设间距8 m(T₂)为试验区暗管排盐工程适宜参数。采用竖井+暗管排水控盐模式,通过降低地下水位和排水控盐共同作用,以维持南疆灌区盐渍土改良效果的稳定性和持续性。

关键词: 次生盐渍化土, 暗管排水, 竖井排水, 脱盐效果, 玉米产量

CLC Number:

S156.4
S513

SHI Lei, LÜ Ning, HE Shuai, YIN Feihu, GAO Zhijian, TAN Rongxin. Screening of the Water Drainage and Salt Control Mode of Subsurface Pipe and Shaft on the Secondary Salinization Soil and Its Effect Evaluation[J]. Xinjiang Agricultural Sciences, 2022, 59(3): 716-724.

石磊, 吕宁, 何帅, 尹飞虎, 高志建, 谭荣欣. 次生盐渍土暗管+竖井排水控盐技术模式筛选及效果评价[J]. 新疆农业科学, 2022, 59(3): 716-724.

Figures/Tables 7

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建设内容 Construction items	数量 Number	规格及技术参数 Specification and technical parameter
暗管Underground pipe	47道	1.7×10⁴ m、Ф50 mm、平均埋深1.2 m,间距6、8、10 m,自流坡度3.5‰
竖井Shaft	9个	Ф60 cm、深20 m,管壁带孔有过滤层包裹
观察井 Observation well	3个	上Ф0.8 m、下Ф1.5 m、深2.4 m,承接竖井排水,内设爬梯
集水井 Water-collection well	1个	Ф1.2 m、深13 m,承接所有排水,设在监测泵房中
集水管 Water-collection pipe	1.4 km	主集水管:PE材质螺纹管、Ф200 mm、埋深2.1 m、坡度2‰,竖井集水管:160 mm PVC管、埋深1.4 m、坡度2.5‰
自动水泵系统 Automatic water pump control system	10套	1套集水井水泵(4 kw、25 m、25 m³/h)、9套竖井水泵(1.5 kw、20 m、10 m³/h)
供电设施 Power supply facility	1套	变压器(20 kw)、电缆、配电箱、电表等
水盐监测系统 Water and salt monitoring system	1套	3个土壤温湿盐传感器(20、40、60 cm)、土壤pH、水体pH及电导率各1个、1套数据传输及展示系统
监测泵房 Monitoring pump room	1个	30 m²、含配电箱、墙插、照明及水盐监测服务器等

建设内容 Construction items	数量 Number	规格及技术参数 Specification and technical parameter
暗管Underground pipe	47道	1.7×10⁴ m、Ф50 mm、平均埋深1.2 m,间距6、8、10 m,自流坡度3.5‰
竖井Shaft	9个	Ф60 cm、深20 m,管壁带孔有过滤层包裹
观察井 Observation well	3个	上Ф0.8 m、下Ф1.5 m、深2.4 m,承接竖井排水,内设爬梯
集水井 Water-collection well	1个	Ф1.2 m、深13 m,承接所有排水,设在监测泵房中
集水管 Water-collection pipe	1.4 km	主集水管:PE材质螺纹管、Ф200 mm、埋深2.1 m、坡度2‰,竖井集水管:160 mm PVC管、埋深1.4 m、坡度2.5‰
自动水泵系统 Automatic water pump control system	10套	1套集水井水泵(4 kw、25 m、25 m³/h)、9套竖井水泵(1.5 kw、20 m、10 m³/h)
供电设施 Power supply facility	1套	变压器(20 kw)、电缆、配电箱、电表等
水盐监测系统 Water and salt monitoring system	1套	3个土壤温湿盐传感器(20、40、60 cm)、土壤pH、水体pH及电导率各1个、1套数据传输及展示系统
监测泵房 Monitoring pump room	1个	30 m²、含配电箱、墙插、照明及水盐监测服务器等

处理 Treatments	排盐前 (2016.12) Before salt draining		排盐1年后 (2017.10) 1 year after salt draining		排盐2年后 (2018.10) 2 year after salt draining		2017较2016 增减比例 Percentage variation(%)	2018较2016 增减比例 Percentage variation(%)
T₁	6.68+0.15^bA		7.10+0.45^aAB		5.25+0.09^cA		6.19	-21.41
T₂	6.84+0.05^bA		7.39+0.33^aA		4.57+0.41^cB		7.94	-33.24
T₃	6.27+0.35^bB		7.12+0.19^aAB		5.10+0.03^cA		13.61	-18.57
显著性比较 Variance analysis
P		0.032		0.054		0.030
显著性 Variance		*		NS		*

处理 Treatments	排盐前 (2016.12) Before salt draining		排盐1年后 (2017.10) 1 year after salt draining		排盐2年后 (2018.10) 2 year after salt draining		2017较2016 增减比例 Percentage variation(%)	2018较2016 增减比例 Percentage variation(%)
T₁	6.68+0.15^bA		7.10+0.45^aAB		5.25+0.09^cA		6.19	-21.41
T₂	6.84+0.05^bA		7.39+0.33^aA		4.57+0.41^cB		7.94	-33.24
T₃	6.27+0.35^bB		7.12+0.19^aAB		5.10+0.03^cA		13.61	-18.57
显著性比较 Variance analysis
P		0.032		0.054		0.030
显著性 Variance		*		NS		*

处理 Treatments	种植面积 Planting area (667m²)	株数 Plant density (株/667m²)	玉米单产 Maize yield per area (kg/667m²)	总产值 Total output value (元)
T₁	57.60	4 500	313.45^b	32 498.50
T₂	63.21	5 500	366.50^a	41 699.64
T₃	56.11	4 200	303.75^b	30 678.14
平均 Average	58.97	4 733	327.90	34 807.24

Screening of the Water Drainage and Salt Control Mode of Subsurface Pipe and Shaft on the Secondary Salinization Soil and Its Effect Evaluation

次生盐渍土暗管+竖井排水控盐技术模式筛选及效果评价

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