INTEGRATED ON-FARM DRAINAGE MANAGEMENT FOR DRAINAGE WATER DISPOSAL

Abstract The disposal of the excessive volume of degraded water coming from agricultural drainage systems is a serious environmental and economic issue, since a significant load of agrochemicals and salts contaminates water bodies downstream. An integrated on-farm drainage management (IFDM) system is an effective method of treatment by successively irrigating zones with drainage water. Each zone is cultivated with crops that have increasing tolerance to salinity, so that the drainage water effluents are minimized to an extent that the final drainage water volume is collected into an evaporation pond. The methodology of the system is proposed herein for a regional irrigation-drainage network (E1 in Agoulinitsa irrigation district in western Greece) as a method of reducing the disposal of agrochemicals in the coastal environment. Based on the design principles of an IFDM system, both the surface area of every irrigation zone and the costs of installing and operating the system are assessed. A scenario regarding the volume of drainage water that must be treated is examined as a sensitivity analysis. The results show that almost 15% of the cultivated area must be bounded for non-productive uses, resulting in a significant economic impact on the net present value of the investment.

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Disposal of Drainage Water from Irrigated Alluvial Plains

Water Science & Technology ◽

10.2166/wst.1984.0121 ◽

1984 ◽

Vol 16 (5-7) ◽

pp. 41-55 ◽

Cited By ~ 4

Author(s):

J F Robson ◽

R F Stoner ◽

J H Perry

Keyword(s):

Drainage Water ◽

Water Disposal

In this paper the problems associated with the drainage of irrigated alluvial plains are discussed with particular reference to the disposal of saline drainage water. The drainage problems within two specific regions are outlined, the Tigris-Euphrates plain in Iraq and the lower Indus plain in Pakistan. For both regions details are given of present and future drainage water disposal methods.

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The Technology of Hydrodedusting of Coal Pits’ Auto Roads Using Purified Wastewater and Drainage Water

Ecology and Industry of Russia ◽

10.18412/1816-0395-2020-1-30-33 ◽

2020 ◽

Vol 24 (1) ◽

pp. 30-33

Author(s):

K.V. Letuyev ◽

S.V. Kovshov ◽

E.B. Gridina

Keyword(s):

Water Treatment ◽

Irrigation System ◽

Sharp Decrease ◽

Drainage Water ◽

Treated Wastewater ◽

Cyclic Hydrocarbons ◽

Water Dispersion ◽

Mode Of Operation ◽

Water Disposal ◽

Clarified Water

The experience of the Arshanovsky coal pit in solving the problem of rational water disposal is presented. A wastewater and drainage water treatment system is proposed that can significantly reduce the content of suspended particles in clarified water discharged after settling and filtering – up to 1.5–5 mg/dm3, while the effect of water clarification is more than 95 % with a sharp decrease in the content of cyclic hydrocarbons and organics. In order to determine effective directions, in laboratory conditions, rational parameters of nozzle hydrodedusting were determined for varying degrees of water dispersion using treated wastewater and drainage water. It is established that the most effective mode of operation of the fine-dispersed irrigation system with a nozzle diameter of 1.0 mm. The obtained parameters of finely dispersed irrigation can be adapted for irrigation vehicles.

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Drainage Water Disposal, Jeddah, Saudi Arabia

Journal of Water Resources Planning and Management ◽

10.1061/(asce)0733-9496(1993)119:6(706) ◽

1993 ◽

Vol 119 (6) ◽

pp. 706-712 ◽

Cited By ~ 2

Author(s):

Omar S. Abu‐Rizaiza ◽

Hasan Z. Sarikaya

Keyword(s):

Saudi Arabia ◽

Drainage Water ◽

Water Disposal

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Real-time on-farm N loss measurement

Journal of New Zealand Grasslands ◽

10.33584/jnzg.2020.82.427 ◽

2020 ◽

Vol 82 ◽

pp. 35-43

Author(s):

Samuel J. Dennis

Keyword(s):

Real Time ◽

Computer Modelling ◽

Drainage Water ◽

Nutrient Loss ◽

Strongly Correlated ◽

Total N ◽

Loss Measurement ◽

Time Estimates ◽

A Site ◽

On Farm

Empirical measurements of nutrient-leaching losses on farms are required in order to allow validation of models used to assess nutrient losses from New Zealand farmland. However such on-farm measurements have, to date, been generally impractical. A new in-field leaching loss measurement system has been developed, based on well-established research methodologies. This system combines large strip lysimeters (10–20 m long) with largely automated, real-time leachate monitoring, which allows measurements to be taken over much larger areas for greatly reduced costs compared with other systems currently on the market. A spatial computer modelling simulation showed that one such lysimeter can generate results of equivalent accuracy to an array of 12 fluxmeters, three lysimeters are equivalent to an array of 64 suction cups, and a larger number of lysimeters can be used to obtain more accurate results. Nutrient loss is measured using off-site chemical analysis of flow-proportional subsamples of drainage water. In addition, electrical conductivity (EC) of the drainage water is measured continuously and correlated with past chemical analyses to provide real-time estimates of nutrient loss. Real-time EC measurements were strongly correlated with Total N concentration determined off site (R2 = 0.89), which suggests that EC can be used as a proxy for Total N. However, a site-specific regression of EC and N should be used for any actual estimation of N from EC.

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Geoecological Monitoring on the Territory of Underground Disposal Sites of Highly Mineralized Waters in Western Yakutia

Ecology and Industry of Russia ◽

10.18412/1816-0395-2019-4-58-63 ◽

2019 ◽

Vol 23 (4) ◽

pp. 58-63

Author(s):

Ya.B. Legostaeva ◽

M.I. Ksenofontova ◽

V.F. Popov

Keyword(s):

Surface Water ◽

Drainage Water ◽

Processing Plant ◽

Industrial Site ◽

Storage Tanks ◽

Ecological Situation ◽

Mineralized Water ◽

Underground Disposal ◽

Water Disposal ◽

Mine Workings

The safe disposal of highly mineralized runoff in the development of indigenous diamond deposits in Western Yakutia is the most important task of ensuring a favorable geo-ecological situation in the region. Using the example of a large experimental material collected at the industrial site of the Udachninsky mining and processing plant, PJSC ALROSA, the geoecological situation in the area of underground drainage water disposal sites was assessed. Under the conditions of a complex and dynamic cryohydrogeological situation on the background of an increase in the volume of water inflow into the mine workings, the excess of the capacitive capabilities of the reservoirs of the storage tanks of the brine can lead to serious geoecological problems. Markers that identify the effects of highly mineralized water on the main abiotic components of the region's ecosystems – soil, bottom sediments and surface water – are strontium and lithium.

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Performance analysis of on-farm irrigation tanks on agricultural drainage water reuse and treatment

Resources Conservation and Recycling ◽

10.1016/j.resconrec.2013.03.011 ◽

2013 ◽

Vol 75 ◽

pp. 1-13 ◽

Cited By ~ 11

Author(s):

Dongguo Shao ◽

Xuezhi Tan ◽

Huanhuan Liu ◽

Haidong Yang ◽

Chun Xiao ◽

...

Keyword(s):

Performance Analysis ◽

Water Reuse ◽

Drainage Water ◽

Agricultural Drainage ◽

Agricultural Drainage Water ◽

Drainage Water Reuse ◽

On Farm

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Nature of uranium contamination in the agricultural drainage water evaporation ponds of the San Joaquin Valley, California, USA

Canadian Journal of Soil Science ◽

10.4141/s96-083 ◽

1997 ◽

Vol 77 (3) ◽

pp. 459-467 ◽

Cited By ~ 11

Author(s):

Martine C. Duff ◽

C. Amrhein ◽

G. Bradford

Keyword(s):

Drainage Water ◽

San Joaquin Valley ◽

Water Evaporation ◽

Agricultural Drainage ◽

Wetting And Drying ◽

Evaporation Ponds ◽

High Carbonate ◽

Water Disposal ◽

Surrounding Areas ◽

Irrigation Drainage

Evaporation ponds used for agricultural subsurface drainage water disposal in the Tulare Lake Bed (TLB) of the San Joaquin Valley, California, USA, have elevated levels of U. Waterfowl which inhabit and forage the ponds and surrounding areas are threatened by exposure to U. The ponds, which receive irrigation drainage waters and seasonal rain, are subject to wetting and drying periods. The periods result in the accumulation of decaying algae and other organic material in surface sediments. Sediment and waters in the ponds were sampled to determine what factors control U solubility and sediment U concentrations. Data from a 1990 study conducted by Chilcott et al. in 1989 on the TLB ponds were used to help identify what factors may control U solubility. Pond sediment U concentrations decreased abruptly with depth and surface sediment U concentrations were related to dissolved Ca:HCO3 ratios. Pond algal U bioaccumulation was favored in waters with high Ca:HCO3 ratios, which had lower pH values and carbonate alkalinities than waters with low Ca:HCO3 ratios. Ponds with high salinities and high carbonate alkalinities contained the highest aqueous U concentrations relative to other TLB ponds. Sediment total organic carbon (TOC) was correlated with sediment U concentrations, suggesting that U is bound to organic matter. The source of TOC is most likely from algae deposition. Key words: Uranium, salinity, redox potential, carbonate alkalinity, bioaccumulation, algae

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