RU2687527C1 - Method of rice cultivation with low-volume surface sprinkling - Google Patents

Abstract

FIELD: agriculture.SUBSTANCE: invention relates to the field of agriculture, in particular to rice growing. Method comprises autumn peeling of precursor culture stems at depth of 0.06–0.10 m, application of preset doses of phosphorus, potassium to autumn plowing and up to 40–60 % of calculated dose of nitrogen, under-winter ploughing of soil, spring cover harrowing of soil, presowing cultivation of soil at depth of 0.06–0.08 m, treatment of seeds with biopreparation, continuous sowing of culture at depth of 0.06–0.08 m with heating of said layer to 12–14 °C, post-sowing soil packing and application of soil herbicide, care for culture during vegetation period, containing irrigation with maintenance of required level of soil moisture, introduction of herbicides, biopreparations and crop removal. Under-winter ploughing of soil is carried out at different depths with alternation by years – in the first year at depth of 0.20–0.24 m with formation rotation at the same depth, and in the second year at a depth below the plow foot by 0.08–0.10 m and formation rotation by 0.20–0.24 m. Irrigation is carried out periodically by method of low-volume surface sprinkling with placement of sprinkler stands at height of 0.8–1.0 m from day surface and 25–35 % crossing of rain torches with maintenance of differentiated water regime of soil at moisture content of 70–80–70 % of minimum moisture-holding capacity (MMHC) in layer 0.4 and 0.6 m. At the same time from soil till tillage beginning soil moisture content is maintained at least of 70 % MMHC in layer of 0.4 m, in tillering, tubing, brooming and milk ripening the preliminarily soil moisture content is increased to 80 % MMHC. At that, in tillering phase in layer 0.4 m, and from tubing phase in layer of 0.6 m, in phase from wax to complete ripeness of grain, pre-limb moisture in layer of 0.6 m is reduced to 70 % of MMHC, wherein value of total water consumption of culture determined by formula E=618⋅Y+2,580, where E is total water consumption, m/ha; Y – planned crop capacity, t/ha.EFFECT: method ensures increase of rice yield capacity on irrigated lands of the Volga-Don interfluve.1 cl, 1 tbl

Description

The invention relates to agriculture, in particular to methods of rice cultivation.

By its ecological nature, rice belongs to hygrophytes, obtaining stable and sufficient yields of this crop is possible only on artificially irrigated lands, in conditions with rainfall of more than 1500-2000 mm per year, or on periodically flooded territory.

In the cultivation of rice, three irrigation methods are known that maintain the required water regime of the soil: surface irrigation (flooding of checks, along lanes and furrows), sprinkling and drip irrigation.

There are known methods for cultivating rice in checks, including preparing the soil, applying mineral fertilizers, sowing seeds and flooding checks with water with a layer of different depth taking into account the phases of plant development (Patent for the invention of the Russian Federation No. 2019082, IPC A01G 16/00, A01G 25/00. Method of cultivation rice. Publ. 15.09.1994; Patent for the invention of the Russian Federation No. 2099934, IPC A01G 16/00, AV B 79/02. Method of rice cultivation. Publ. 12.27.1997).

The reasons that impede the achievement of a given technical result include the insufficiently high efficiency of rice production due to the high costs of financial and labor resources, which is caused by the need to use expensive specialized equipment on crawler tracks, large amounts of planning work, high water consumption for flooding, the use of drainage systems, including drainage pumps. In addition, the cultivation of rice in checks leads to waterlogging of adjacent territories due to the rise of groundwater. Known methods are applicable in a humid climate.

Known methods of rice cultivation, including soil preparation, mineral fertilization, seed treatment with drugs, sowing of seeds, periodic watering of the bands and / or furrows and / or sprinkling, fertilizing with fertilizers, application, as necessary, of herbicides, biologics, fungicides and / or insecticides , and crop harvesting (Kruzhilin, IP, Water-saving technology for irrigating rice with periodic irrigation), Vestnik of the RAAS. 2009. No. 3. P. 39-41; Kruzhilin, IP, Ganiev, MA, Rodin, K.A. , Lyubushkin SN Cultivation of rice under irrigation by sprinkling // M lioratsiya and water management. 2009. №1. pp 28-31).

The reasons that impede the achievement of a given technical result include the insufficiently high efficiency of rice production in the conditions of the Volga-Don interfluve, which is caused by the soil and climatic features of the region. In particular, the soil surface is characterized by a relief inhomogeneity, manifested in multidirectional slopes, lowlands and elevations, a low content of water-resistant soil aggregates, a tendency to compaction and the formation of a surface crust. The climate is characterized by aridity due to high temperatures (daytime air temperatures in the sun can reach 50-70 ° C), duration of sunshine and low relative humidity with dry winds, accompanied by strong heat and dry wind with a speed of 7-10 m / s with possible gusts up to 25 m / s.

Periodic irrigation in lanes and / or furrows, as already noted, is accompanied by high costs of irrigation water - 6-8 thousand m ³ / ha and more, the need to perform planning work, and so on. In the case of irrigation in strips and / or furrows, it is also necessary to take into account the limited impact on the mitigation of the microclimate, which significantly affects the neutralization of drought stress and increases the bioproductive potential of the crop in a dry climate.

Uniform irrigation with medium and long-range sprinkling is achieved in calm weather, which is not typical of the conditions of the Volga-Don interfluve. In addition, sprinkling is limited to the irrigation rate of 250 m ³ / ha, a further increase in the irrigation rate is accompanied by the formation of surface runoff due to a mismatch of the absorption rate due to the consistently decreasing soil absorbency and, as a result, soil erosion. It is necessary to take into account the fact that when sprinkling in order to prevent possible injury to rice plants and to avoid drip-rain erosion, it is necessary to recreate a drizzling rain with drops of 0.4-0.9 mm in diameter and an intensity of not more than 1.5 mm / min. on existing sprinkler devices difficult to reach.

The closest technical solution for the combination of features to the claimed method and adopted for the prototype is the method of rice cultivation, including autumn peeling of the stubble of the precursor culture to a depth of 0.06-0.10 m, depositing the calculated doses of phosphorus, potassium and up to 40- 60% of the estimated dose of nitrogen, plowing the soil for autumn, spring-covering soil harrowing, pre-sowing cultivation of the soil to a depth of 0.06-0.08 m, seed treatment of a culture with a given dose of a biological product, continuous sowing of the culture to a depth of 0.06-0.08 m when warmed up and the specified layer up to 12-14 ° C, postseeding soil rolling and applying a given dose of a soil herbicide, caring for the crop during the vegetation period, containing watering to maintain the required soil moisture level, feeding with equal doses of nitrogen remaining in the beginning of tillering and booting phase and, as necessary, the introduction of the recommended doses of herbicides, biologics, fungicides and / or insecticides, and crop harvesting (Dubenok N.N., Kruzhilin I.P., Abdu N.M., Ganiev M.A., Rodin K. BUT. Productivity of dry rice with drip irrigation // Izvestiya TSCA. 2015. Vol. 6. P. 92-100).

The reasons that impede the achievement of a given technical result are the insufficiently high efficiency of rice production due to the high costs of financial and labor resources, due to the cost of the drip irrigation system and the associated assembly and dismantling works. To close the humidification contours and, accordingly, to achieve effective watering with the standard layout of dropping ribbons through 0.6-0.7 m, it is necessary that the distance between the outlets is no more than 0.6 m, and this imposes additional costs. In addition, the drip irrigation method has little effect on the improvement of the microclimate in the agrocenosis, which in the Volga-Don interfluve due to climatic features leads to a decrease in crop yield.

The task, which the proposed technical solution is aimed at, is to increase the efficiency of rice production in the Volga-Don interfluve.

The result of the proposed technical solution is an increase in the yield of rice on the irrigated lands of the Volga-Don interfluve, while reducing the unit cost of irrigation water per unit area and marketable products.

The technical result is achieved by the fact that in the method of rice cultivation with low-volume surface sprinkling, including autumn peeling of the stubble of the precursor culture to a depth of 0.06-0.10 m, introduction of calculated doses of phosphorus, potassium and up to 40-60% of the calculated nitrogen doses, autumn plowing of the soil, spring cover harrowing of the soil, pre-sowing cultivation of the soil to a depth of 0.06-0.08 m, seed treatment of the culture with a given dose of a biological product, continuous sowing of the culture to a depth of 0.06-0.08 m when the specified layer is heated up to 12 14 ° C, post-sowing rolling in of the soil and applying a given dose of a soil herbicide, caring for the crop during the growing season, containing watering to maintain the required level of soil moisture, feeding with equal doses of remaining nitrogen in the beginning tillering phase and the booting phase and, as necessary, introduction of the recommended doses of herbicides, biological products, fungicides and / or insecticides, and harvesting of the crop, with the autumn plowing of the soil being carried out to different depths with alternating years - in the first year to a depth of 0.20-0.24 with a reservoir turnover at the same depth, and in the second year at a depth below the plow base by 0.08-0.10 m and a reservoir turnover at 0.20-0.24 m, irrigation is carried out periodically by the method of low-volume surface sprinkling with the placement of spray arms at a height of 0.8-1.0 m from the day surface and 25-35% intersection of rain torches with the maintenance of a differentiated water regime of the soil at a humidity of 70-80-70% HB in a layer of 0.4 and 0.6 m, while from Sowing and prior to the beginning of the tillering phase, the soil moisture is maintained not lower than 70% HB in a layer of 0.4 m, in the tillering stage, booting, spraying and milky I ripened the pre-irrigation soil moisture rises to 80% HB, and in the tillering stage in the 0.4 m layer, and from the booting phase in the 0.6 m layer, in the wax phase to full grain ripeness, the pre-irrigation humidity in the 0.6 m layer decreases to 70% of HB, while the value of the total water consumption of the culture is determined by the formula:

E = 618⋅Y + 2580,

where E is the total water consumption, m ³ / ha;

Y - planned yield, t / ha.

Dredging of different depths with alternation by year - in the first year to a depth of 0.20-0.24 m with a reservoir turnover to the same depth, and in the second year to a depth below the plow base by 0.08-0.10 m and a reservoir turn at 0.20-0.24 m, ensures the creation of the water-physical properties of the soil of the Volga-Don interfluve, which are optimal for rice cultivation. Plowing the soil to a depth of 0.20-0.24 m with a turn of the reservoir to the same depth is due to the low-humus soil, an increase in the depth will be accompanied by the removal of the subsurface low-fertile layer to the surface. In this treatment, crop residues are mixed with the soil, and the organic matter accumulates mainly in the upper part of the arable layer, thereby intensifying microbiological processes. In the arable layer more moisture accumulates, it dries out less. Loosening below the arable horizon contributes to the decompaction of the soil sole, the entry of air and moisture into the lower layers, the activation of redox processes caused by the reduced activity of water-air exchange, and the intensification of chemical and microbiological processes.

The method of low-volume ground sprinkling combines the advantages of irrigation with sprinkling and drip irrigation. The artificial small-drop artificial rain produced with water sprays with low intensity is closest to the natural drizzling rain. The creation of a microclimate in rice crops is ensured by installing sprayers at a height of 0.8-1.0 m from the day surface (taking into account the height of the plants). Thereby, the temperature of the soil is reduced, and the air in the surface layer is moistened. The distance between the racks of sprayers is selected based on their technical characteristics and the need for overlapping torches of rain. Advantages of the low-volume sprinkling method:

1) low operating pressure - up to 0.3 MPa;

2) water supply - 20-240 l / h;

3) irrigation radius - 1.5-18.5 m;

4) rain intensity - 0.03-0.1 mm / min;

5) droplet diameter - up to 0.4 mm;

6) water use efficiency - 70-85%;

7) uniform distribution of rain over the irrigated area - ≈90%;

8) use on land with a relief with direct and reverse slopes, and with the wind;

9) application, together with irrigation, of water-soluble fertilizers;

10) a high level of automation and regulation of operating modes;

11) quick and easy installation, mobility;

12) the service life is more than 10 years.

The method of rice cultivation with low-volume surface sprinkling is implemented as follows.

After harvesting in the autumn of the precursor culture, the soil is prepared, which includes stubble stubbing to a depth of 0.06-0.10 m and the main (autumn) soil treatment. In the first year to a depth of 0.20-0.24 m with a turn of the reservoir to the same depth, and in the second year to a depth below the plow base by 0.08-0.10 m and a turn of the reservoir to 0.20-0.24 m and making for plowing the estimated doses of phosphorus, potassium and up to 40-60% of the estimated dose of nitrogen. The following year, in spring, soil preparation includes surface harrowing to cover moisture and pre-sowing soil cultivation to a depth of 0.06-0.08 m. Before sowing, if necessary, rice seeds are treated with growth regulators and microbiological preparations with appropriate doses, for example, Emistim, Flavobacterin, etc. When the optimum temperature (12-14 ° C) is reached in the sown layer of the soil, continuous sowing of rice seeds is performed at a rate of 4.5-5.5 million viable seeds per 1 ha, followed by rolling and treating the field with a soil herbicide. As a herbicide, use is made, for example, of Stump, prepared at the rate of 5.5-6.5 liters of the preparation per 300-400 liters of water per hectare.

A further task of the technology is the installation of a low-volume surface sprinkling system. To ensure uniform irrigation, the distance between the drains of water dispensers is selected taking into account the radius of spraying of rain with 25-35% overlap of the area to be moistened. Water dispensers are mounted on a rack at a height of 0.8-1.0 m from the day surface, which is caused by the height of rice plants and the need to create a microclimate in the agrocenosis.

Care of the crop during the growing season is mainly reduced to watering, feeding, weed control, pests and diseases. As feedings, the remaining part of the calculated dose of nitrogen is used, which is divided into equal parts and the beginning of tillering and the stage of booting are introduced into the phase. For weed control, herbicides of contact action are used, for example, Cambio tank mixture (2.5 l / ha) and Topic (0.5 l / ha), etc.

Watering with a low-volume surface sprinkling system is carried out periodically with maintaining a differentiated water regime of the soil at a humidity of 70-80-70% HB in a layer of 0.4 and 0.6 m. Moreover, from sowing to the beginning of the tillering stage, the soil moisture is maintained not lower than 70% HB 0.4 m layer, tillering, bubbling, spudding and milky ripeness phases; the pre-irrigation soil moisture rises to 80% HB, while in the tillering phase in the layer is 0.4 m, and from the bobbing phase in the layer is 0.6 m; wax to full ripeness of grain pre-irrigation moisture in a layer of 0.6 m is reduced to 70% HB. Such a water regime of the soil, created by a system of low-volume surface sprinkling, provides favorable conditions and microclimate for the formation of plant biomass corresponding to the photosynthetic parameters and for obtaining sustainable planned yields. The level of rice crop yield is linearly related to the total water consumption. So, to obtain rice yields at the level of 3 to 6 t / ha (the possible bioproductive potential of the crop for the conditions of the Volga-Don interfluve), the total water consumption is determined by the dependence:

E = 618⋅Y + 2580,

where E is the total water consumption, m ³ / ha;

Y - planned yield, t / ha.

Testing of the proposed method was carried out in the Volga-Don interfluve in comparison with the known classical methods of rice cultivation, including annual basic (autumn) soil tillage with a land plow PN-4-35 to a depth of 0.20-0.24 m. Research results are presented in the table.

Analysis of the results of the data in the table shows that while maintaining the soil water regime not lower than 70-80-70% HB in the soil layer of 0.4 and 0.6 m, the best conditions for the formation of plant biomass are achieved by the method of low-volume surface sprinkling (PAR efficiency 1.31% ) and yield (5.25 t / ha) in comparison with the soil water regime options not lower than 70% HB in the soil layer 0.4 m, 80% HB in the soil layer 0.4 m, 70% HB in the soil layer 0 , 6 m, 80% of HB in the soil layer of 0.6 m, as well as 70-80-70% of HB in the soil layer of 0.4 and 0.6 m with classical irrigation methods.

The proposed method of rice cultivation with low-volume surface sprinkling in comparison with the classical methods of rice cultivation provides increased yields while reducing the unit cost of irrigation water per unit area and marketable products. For example, while maintaining the soil water regime not lower than 70-80-70% HB in the soil layer of 0.4 and 0.6 m, the yield is increased at the level of 5-9%, the cost of irrigation water is reduced by 7-28% and the increase water consumption ratio by 3-29%.

Thus, increasing the yield of rice on the irrigated lands of the Volga-Don interfluve while reducing the unit cost of irrigation water per unit area and marketable products is achieved in a way that

Note: h - soil layer, m.

including autumn peeling of stubble precursor culture to a depth of 0.06-0.10 m, introduction of estimated doses of phosphorus, potassium for autumn plowing and up to 40-60% of the estimated dose of nitrogen, autumn plowing of soil, spring cover harrowing of soil, pre-sowing cultivation of soil depth of 0.06-0.08 m, treatment of seeds of a culture with a given dose of a biological product, continuous sowing of the culture to a depth of 0.06-0.08 m when the specified layer is warmed up to 12-14 ° C, post-sowing rolling in of the soil and applying a given dose of soil herbicide care for the crop during the growing season Nogo period containing glaze maintaining the required level of soil moisture, fertilizing equal doses remaining nitrogen in the beginning phase and the phase of tillering booting and, where necessary, introduction of the recommended doses of herbicides, biologics, fungicides and / or insecticides, and harvesting the culture. Moreover, the autumn plowing of the soil is carried out at different depths with alternating years - in the first year to a depth of 0.20-0.24 m with a turn of the reservoir to the same depth, and in the second year to a depth below the plow sole by 0.08-0. 10 m and a reservoir turnover of 0.20-0.24 m, irrigation is carried out periodically by the method of low-volume surface sprinkling with the placement of sprayers racks at a height of 0.8-1.0 m from the surface and 25-35% intersection of rain plumes with maintaining differentiated water regime of the soil at a humidity of 70-80-70% HB in a layer of 0.4 and 0.6 m, while from sowing to the beginning of the phase tillering soil moisture is maintained not lower than 70% HB in the 0.4 m layer, in the tillering stage, booting, spudding and milky ripeness, the pre-irrigation soil moisture rises to 80% HB, and in the tillering phase in the layer 0.4 m, and from the bobbing phase in a layer of 0.6 m, in the wax phase to full ripeness of grain, the pre-irrigation moisture in a layer of 0.6 m is reduced to 70% HB, while the total water consumption of the culture is determined by the formula:

E = 618⋅Y + 2580,

where E is the total water consumption, m ³ / ha;

Y - planned yield, t / ha.

Claims (4)

The method of rice cultivation with low-volume surface sprinkling, including autumn peeling of the stubble of the precursor culture to a depth of 0.06-0.10 m, introduction of estimated doses of phosphorus, potassium and up to 40-60% of the calculated dose of nitrogen, autumn plowing of soil, spring surface harrowing of the soil, pre-sowing cultivation of the soil to a depth of 0.06-0.08 m, seed treatment of the culture with a biological product, continuous sowing of the crop to a depth of 0.06-0.08 m when the specified layer is heated to 12-14 ° C, post-sowing soil rolling and making soil herbicide, uh one crop during the growing season, containing irrigation with maintaining the required level of soil moisture, application of herbicides, biological products and crop harvesting, characterized in that autumn plowing of the soil is carried out at different depths with alternating years - in the first year to a depth of 0.20- 0.24 m with a turn of the reservoir to the same depth, and in the second year to a depth below the plow base by 0.08-0.10 m and a turn of the reservoir by 0.20-0.24 m, irrigation is carried out periodically by the method of low-volume surface sprinkling with the placement of racks sprayers at height 0.8-1.0 m from the day surface and 25-35% intersection of rain plumes with maintaining a differentiated water regime of the soil at a humidity of 70-80-70% HB in a layer of 0.4 and 0.6 m, while from sowing and prior to the beginning of the tillering stage, the soil moisture is maintained not lower than 70% HB in the 0.4 m layer, in the tillering stage, booting, brooding and milky ripeness, the over-irrigation soil moisture rises to 80% HB, and in the tillering phase in the 0.4 m layer, from the stage of bubbling in a layer of 0.6 m, in the phases of wax to full ripeness of grain, the pre-irrigation humidity in a layer of 0.6 m decreases to 70% HB, while the amount of sums Ary water culture is determined by the formula E = 618⋅Y + 2580, where E is the total water consumption, m ³ / ha; Y - planned yield, t / ha.