RU2663596C2 - Combined irrigation system - Google Patents

Abstract

FIELD: agriculture.SUBSTANCE: invention refers to the field of agriculture and will find application in irrigation of small areas due to the accumulation of local runoff and drainage water. Combined irrigation system contains a drainage network associated with the storage pond 5 of the drainage drain, pumping station 7 connected through fine water purifier 8 to a network of water distribution pipelines 9 connected to irrigation pipelines 10 with water outlets 11. Storage pond 5 is provided with protective screen 6 mounted on floats fixed to the cables connected to the drums of winches 12 located on two opposite sides of storage pond 5. Screen 6 is made of a series of panels of opaque membrane material, one end of which is fixed on the floats of adjacent cables, and the other is connected by quick-connect couplings with an adjacent panel. Through the quick-connect couplings, the panels are fastened with bayonet connections in the form of bolts with axial apertures and nuts.EFFECT: system allows to reduce losses of water for evaporation from the surface of the storage pond and to reduce the amount of dead water in it, and also to increase the reliability of the fine water filter.1 cl, 6 dwg

Description

The invention relates to the field of agriculture and will find application in the irrigation of small areas due to the accumulation of local flow and drainage water.

Known drainage and humidification system comprising a drain system associated with a drainage collector associated with a pond drainage drain and irrigation network. During operation of this system during the spring flood, water is accumulated in the pond from the drains to the collector. In the dry period of vegetation, water from the pond is fed through the irrigation network to the field (USSR Author's Certificate No. 1631121, IPC Е02В 11/00, 02/28/1991)

The disadvantages of this system are the high irrigation standards and the low utilization of accumulated water due to the need to spend it not only for irrigation, but also for evaporation from the surface of the pond and maintaining a dead water supply, as well as a significant area occupied by the pond.

Known water circulation system, including a drainage network, coupled to a pond with a drainage accumulator, a pumping station, connected through a fine filter of water to a network of water distribution pipelines connected to irrigation pipelines equipped with droppers, outlets. This system can significantly reduce irrigation and irrigation norms and accordingly reduce the area occupied by the pond (B.S. Maslov, BC Stankevich, V.Ya. Chernenok, Drainage and humidification systems, M. Kolos, 1981, p. 98, 129-130 ) This technical decision was made as a prototype.

The disadvantage of this system is also the low coefficient of water use due to the need to expend its reserve to compensate for evaporation from the surface of the pond. To prevent overgrowing and siltation of the pond, it is necessary to maintain a dead supply of water to a depth of 1.5-2 m. In addition, fertilizers washed from the fields and contained in the accumulated water contribute to the active development of green algae, which clog fine water filters, reducing the reliability of the system drip irrigation. Restoring the efficiency of the filters requires washing them with water purified from algae and removing the wash water from the pond.

The technical result of the invention is to reduce water losses due to evaporation from the surface of the storage pond and to reduce the volume of dead water in it, to increase the reliability of the fine filter.

The technical result is achieved by the fact that the drainage and humidification system comprises a drainage network interfaced with a storage pond of a drainage drain, a pumping station connected through a fine filter of water to a network of water distribution pipelines connected to irrigation pipelines with drip-outlets, while the storage pond equipped with a protective screen mounted on floats mounted on cables connected to the drums of winches located on two opposite sides of the storage pond, valve is made of a number of opaque webs of membrane material one end of which is mounted on floats of adjacent cables and other quick couplings connected to the adjacent material web and through a panel of quick couplings are attached bayonet connections in the form of bolts with axial holes and nuts.

A new technical result from the application of the proposed device is that the screen of the lightproof membrane cloth allows to reduce evaporation from the surface of the pond, while the cables with floats hold the cloth over its surface, and the implementation of them from the membrane material allows you to delay water vapor while maintaining gas exchange of the pond with atmospheric air. The opacity of the screen prevents the development of green algae, which prevents clogging of the filters of the drip irrigation system, in addition, the lack of lighting prevents the pond from overgrowing with aquatic vegetation, which reduces the amount of dead water in the storage pond. At the same time, quick disconnect connections provide rainfall runoff from the screen surface to the storage pond. Thus, an increase in the utilization rate of the accumulated water and the reliability of the fine filter is ensured.

The essence of the proposal is illustrated in the drawing, where in FIG. 1 presents a General view of the drainage and moisturizing system; in FIG. 2 - protective screen, top view; in FIG. 3 -. pond when fully filled, in a section along AA; in Fig 4. - a pond with a decrease in water level to a dead volume, in a section along AA; in FIG. 5 is a fragment of a section of a protective shield along the line of quick-disconnect connections of the type “Velcro” in FIG. 6 is a fragment of a section of the protective screen along the bayonet connection line.

The drainage and humidification system is located on site 1 and consists of closed drains 2 connected to collectors 3 connected to a collector 4 discharged into the storage pond 5 of the drainage drain. A protective screen 6 is placed on the surface of the storage pond 5. A pumping station 7 is installed on the shore of the storage pond 5 and connected through a filter 8 to a network of distribution pipelines 9, to which irrigation pipelines 10 are connected with drip-outlets 11. On the banks of the storage pond 5 are installed winches 12 with cables 13, on which the floats are mounted 14. Clips 15 are attached to the floats 14, interconnected by quick disconnect connections 16 made of Velcro material. Through a distance of 1-1.5 m along the connection line 16, quick-release bayonet connections 17 are mounted consisting of a bolt 18 with an opening 19 and a nut 20. In the upper part of the pond, a discharge pipe 21 is installed at the mark of its maximum level of filling, and the short sides of the pond 5 are made vertical , from gabion boxes 22.

The work of the proposed drainage and humidification system is performed in the following sequence.

Closed drains 2 are laid on the drained section 1 during the construction of the drainage system, pairing them with the collectors 3, connected by the collector 4, discharged into the drainage storage pond 5. This pond is arranged in the lowest part of the drained section 1. For the convenience of the screen 6 operation, the pond the drive 5 has a rectangular elongated shape. The dimensions of the pond are determined by the volume of collected runoff and the permissible depth, the nature of the soil. Moreover, its short sides are made in the form of vertical walls (for example, from gabion boxes). A pump station 7 is installed on the shore of the pond, the intake line of which is lowered into the pond to the level of dead volume. The pressure line of the pump is connected to a fine water filter 8, connected to a distribution pipe 9, to which flexible irrigation pipes 10 with water outlets-droppers 11 are connected. The protective screen 6 is assembled before filling the pond. On the long sides of the pond through a distance of 3-4 m, depending on the width of the membrane of the membrane material, winches 12 with cables 13 are installed, on which floats are mounted after a distance of 2-3 m 14. The length of the cables is fixed at the height of the dead water supply in the pond. For the manufacture of the screen 6 can be used panels 15 of the film, for example, "Isospan D" or "PVC membrane reinforced with synthetic mesh." One side of the web 15 is attached to the floats 14 using a stapler, and on its other side a quick-connect connection of the "Velcro" type 16 is attached. Two adjacent web panels are connected together by "Velcro" and fastened with a bayonet joint 17, passing the bolt 18 through the web 15 and screwing nut 20. The advantage of the bayonet connection is the speed and reliability of fastening. The edges of the screen 6 are fixed on the berm of the pond 5.

In spring, water flows from drains 2 through collectors 3 and pipeline 4 into pond 5, filling it. The floats 14 float and raise the screen 6, the cables 13 are wound on the drums of the winches 12. At the same time, the screen 6 on the shore near the winches 12 is folded. The pond is filled until the maximum level is reached, and the excess water flows through the pipe 21 outside the area 1. When precipitation occurs, water collects on the surface of the screen 6 and, seeping through connections 16, enters the storage pond 5. During rainfall, water flows into the pond -accumulator 5 also through holes 19 in bolts 18. The entry of this water into the pond compensates for filtration losses, and its excess flows down the pipe 21 outside section 1. The presence of screen 6 minimizes the consumption of water for evaporation from the surface of the pond a-drive 5, since water vapor condenses on the surface of the inner layer of the membrane material and flows in the form of droplets back into the water of the storage pond 5. In this case, air passes through the upper layer of the material, providing gas exchange of the pond with the atmosphere. The opacity of the membrane material prevents the development of green algae (such as chlorella, chlamydomonas, etc.). Lack of lighting prevents overgrowing of the pond by 5 sedges and other aquatic vegetation.

When a dry period occurs, when the supply of water in the pond with drainage water ceases and there is a need to start drip irrigation, turn on the pump station 7 and supply water to the filter 8, where it is cleaned from inclusions larger than 0.1 mm. The purified water enters the pipeline 9, from it to the irrigation pipelines 10 and the water outlets-droppers 11, and from them directly to the roots of the plants. Since the water in the pond settles for 1-2 months before irrigation, and screen 6 prevents the development of green algae in the pond water, the number of particles larger than 0.1 mm in it is sharply reduced. Accordingly, the duration of the filter 8 without flushing increases. For washing the filter 8, water from the pond is used with its return to the pond.

As water is taken for irrigation, its level in the storage pond 5 decreases, the floats 14 lower in accordance with the lowering level and drag the screen 6. The cables 13 are reeled off from the winch drums 12. The water decreases as it is pumped out by the pumping station 7 It continues until the end of the irrigation period or a decrease in the level to a dead stock. At the same time, part of the screen 6, gathered in folds when filling the pond, is expanded, forming a lightproof coating of the shore, preventing the growth of aquatic vegetation. Overlapping the water area of the storage pond 5 with a lightproof screen prevents the coastal zone from overgrowing with aquatic vegetation and reduces the amount of dead water in the storage pond 5 to the minimum acceptable level. After the termination of the dry period with precipitation, replenishment of water in the storage pond 5, and, if necessary, the continuation of irrigation. The dismantling of the screen 6 is carried out after the completion of the irrigation season and emptying the pond or after freezing water in the pond on ice.

To assess the effectiveness of the proposed technical solution, we give an approximate calculation of the results of its application compared to sprinkling in central Russia, in a small farm with an area of 100 hectares. Such a farm, in the absence of natural water sources for irrigation, is forced to rely on the use of local runoff water collected within its own land holdings. Under the rugged relief of the Central Russian Upland, the real area suitable for irrigation of vegetables in the scale of such a farm can be 10-15 hectares. As a rule, this field needs irrigation in July - August, when the outflow of drainage water stops, the groundwater level drops, and the humidity of the arable layer drops below 60% of HB. Such a dry period can last 30-50 days and have a significant impact on productivity. To prevent this effect, 4-5 irrigations are carried out on the plot using sprinkler technology. Watering is carried out at a rate of 200-250 m ³ / ha. The irrigation rate will be 800-1200 m ³ / ha.

For a plot of 10 ha in the pond, it is necessary to accumulate 12,000 m ^{3 of} water. With a minimum pond depth of 2 m necessary to prevent aquatic vegetation from overgrowing the pond and subsequent waterlogging, its area will be 6000 m ² with a width of 30 m and a length of 200 m. However, taking into account the average amount of evaporation of water from the surface of the pond, its depth should be increased by 0.5 m and, accordingly, a water supply of 3000 m ³ . Losses on filtration, even on poorly permeable soils, also take 3000 m ³ , which requires an increase in the depth of the pond by another 0.5 m. After selecting the irrigation norm, a dead sanitary volume should be left in the pond, preventing siltation and overgrowing. Its dimensions in this case are 2 m or 12000 m ³ . Thus, the total depth of the pond should be 5 m, and the water supply should be 30,000 m ³ .

With drip irrigation, only strips along rows of plants from 30 to 50% of the total field area are moistened. Watering is carried out at small rates with an interval of 2-3 days. Due to this, the irrigation rate can be reduced by 50% to 600 m ³ / ha. Accordingly, the water supply in the pond can be reduced by 6000 m ³ , and the use of a screen preventing evaporation can reduce this stock by another 3000 m ³ . Reducing the illumination of the pond water area prevents it from overgrowing with aquatic vegetation, which reduces the depth of the dead supply from 2.0 m to 1.0 m and reduces the required water supply by another 6000 m ³ . As a result, the total volume of water in the pond is reduced to 15,000 m ³ , and its depth can be reduced to 2.5 m.

Due to the suppression of the activity of green algae and the settling of water in the pond for 1-2 months preceding the irrigation period, the water is significantly clarified and, when taken from a depth of the upper mark of the dead stock, creates favorable conditions for the filter and drip irrigation system to work. At the same time, fertilizers removed from the field by drainage water, during irrigation, return through droppers directly to the root system of plants.

Thus, the application of the proposed drainage and humidification system improves the reliability of the fine water filter, increases the utilization rate of water accumulated in the pond by reducing water losses due to evaporation from the surface of the pond and reducing the amount of dead water in the pond.

Claims (1)

A drainage and humidification system comprising a drainage network interfaced with a drainage pond, a pumping station connected through a fine water filter to a network of water distribution pipelines connected to irrigation pipelines with drip outlets, characterized in that the storage pond is provided with a protective screen mounted on floats mounted on cables connected to the drums of winches located on two opposite sides of the storage pond, while the screen is made of p yes opaque webs of membrane material one end of which is mounted on floats of adjacent cables and other quick couplings connected to the adjacent material web and through a panel of quick couplings are attached bayonet connections in the form of bolts with axial holes and nuts.

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