RU2159029C1 - Method of cultivating amaranth in irrigated agriculture - Google Patents

Abstract

FIELD: agriculture. SUBSTANCE: method involves selecting and harvesting precursor; applying lime of phosphorous and other fertilizers; shelling stubble; applying organic fertilizers; providing plowing with full turning of soil layer, leveling soil relief, early spring plowing, presowing cultivation, sowing; performing interrow care, vegetative irrigation and harvesting. Upon harvesting of precursor, preplowing strip ripping of plowing and subsurface horizons is performed, with width of uncultivated strips between them being equal to width of plowing unit track. Upon plowing, provocative off-season irrigation is performed at irrigation rate of 50-150 sq.m/hectare for creating favorable growing conditions for annual and perennial weed seeds, as well as root sucker plant seeds. Method further involves harrowing for removing weed plants; combining presowing cultivation and formation of gentle and steep slopes next year in spring, with ridge spacing being equal to width of row spacing; orienting ridge gentle slopes so that they are exposed to maximum intensity of illumination. Steep slopes are formed with physico-mechanical properties of soil being taken into account. Amaranth seeds are sown on gentle slope with following local rolling of rows. Care procedures are effectuated without usage of herbicides. First interrow cultivation is conducted at 2-3 stable leaves stage of plant vegetation, with the usage of shielding houses. Row spacings are ripped with shaving hoes and simultaneously row soil relief is leveled by means of harrows. Second cultivation is combined with formation of water-absorbing slits. At third cultivation stage, soil is hilled to plant stem base. Vegetative drop irrigation and finely dispersed irrigation are provided on the basis of programmed green mass and grain productivity. EFFECT: reduced production cost and provision for obtaining high-protein roots on base free from herbicides. 10 cl, 8 dwg, 2 tbl

Description

 The invention relates to agriculture, in particular to the technology of cultivation of light and heat-loving crops in irrigated agriculture.

A known method of cultivating the eastern goatskin, including its simultaneous sowing with a cover crop, in which a two-year culture is used as a cover crop (see RU, patent, N 2055459, C1, IPC ⁶ A 01 B 79/00. The method of cultivating eastern goatskin // Geiberekht I.P., Dridiger V.R., Announced on 11/05/1992, published on 03/10/1997).

 Amaranth is a thermophilic and photophilous culture. However, the joint sowing of the integumentary culture - clover and amaranth is impossible. Amaranth cultivation should be carried out on clean, weed-free fields.

There is also known a method of cultivating row crops, including the tape application of herbicides on the cut surface of the ridge and sowing seeds, in which the top of the ridge is cut to the depth of the upper boundary of the moist soil layer, the surface of the cut is loosened to a depth of 3-4 cm and the seeds are sown in the section of the ridge with simultaneous application herbicide under a pressure of 3.5 atm (RU, patent, N 2082293, C1, IPC ⁶ A 01 B 79/00. The method of cultivating row crops // Bzikov MA Declared June 23, 1994, published June 27, 1997).

Sowing amaranth seeds in a moist layer gives a positive effect on plant growth, but only when the soil is heated to a depth of 10-12 cm at a temperature above 10 ^o C. However, the presence of even minimal doses of herbicides leads to the death of amaranth seedlings.

There is also known a method of cultivating soybeans for grain on irrigated lands, including fertilizing for plowing, sowing intermediate crops, vegetative irrigation, mowing green masses, plowing, preparing the soil, sowing soybean seeds, caring for crops, harvesting, in which they use as an intermediate crop alfalfa seed crops, which are used annually for three years for green fodder, while in the third year of use of alfalfa, the first mowing is harvested in the phase of the beginning of budding for fodder purposes, then plowing, Preparations soil and crop in the same year, the seeds of soybean maturing varieties with aisles 45 cm and a seeding rate of 400-450 thousand. germinating seeds per m 2, and the irrigation rate is soybean irrigation 1023 ^m3 / ha (RU, patent, N 2054229, C1 , IPC ⁶ A 01 B 79/00. Method for cultivating soybeans for grain on irrigated lands // Chaika AK, Declared September 2, 1991, published February 2, 1996).

 The disadvantages of the described method in relation to amaranth include the different ripening dates of the mentioned crops. The cultivation of both crops requires large irrigation rates of irrigation water.

 Closest to the claimed method of cultivating amaranth is the known technology for cultivating it, including the selection of the predecessor and the timing of its harvesting, applying lime and phosphate fertilizers, stubble cultivation, applying organic fertilizers, plowing with a complete turnover of the reservoir, leveling the relief, early spring harrowing, pre-sowing cultivation and harvesting (see Chernov I.A., Zemlyanoy B.Ya. Amaranth - protein factory // Kazan: Kazan University Press. - 1991. - 92p. - S. 68-74).

 The disadvantages of the described method include the instability of the growth of amaranth plants to conditions in sharply continental natural and climatic zones of southern Russia with frost in the spring, moisture deficiency in the upper soil layer, rapid increase in soil and air temperature and rapid growth of heat-loving weeds, coinciding with the sowing dates , as well as poor conditions for the development of the rod and subordinate roots of amaranth.

 The invention consists in the following.

 The problem to which the claimed invention is directed, is to ensure a stable crop of grain and green mass of amaranth in the extremely arid climate of the Lower Volga region.

 The effect and technical result that can be obtained by carrying out the invention are expressed in increasing productivity per unit area while reducing unit costs of material, energy and labor resources, obtaining high protein nutritionally valuable fodder and high-quality seeds on a non-herbicidal basis.

The specified effect and technical result in the implementation of the invention is achieved by the fact that in the known method of cultivating amaranth, including the selection of the predecessor and the timing of its harvest, the application of lime, potash and phosphorus fertilizers, peeling stubble, the introduction of organic fertilizers, plowing with a full turn of the reservoir, leveling the relief, early spring harrowing, pre-sowing cultivation, sowing, interrow care, vegetative irrigation and harvesting, the following technological operations are included in the claimed method: after making the lime These and phosphoric fertilizers carry out pre-arable loosening of arable and subsurface horizons with a width of untreated strips between them equal to the rut of those engaged in the most energy-intensive process of the agricultural arable unit, after plowing, water-charging (provocative) irrigation is carried out, presowing cultivation is combined with the cultivation of crests with different heights slopes with a step between the ridges equal to the row spacing, while the gentle slopes are oriented in the direction of maximum illumination, sowing they are carried out on a gentle slope and combined with local post-sowing row rolling, the first row-row treatment is carried out in the phase of 2-3 real leaves using house shields, and at the same time, the row-spacings are aligned with the harrows, the second cultivation is combined with the work of water-absorbing cracks, during the third cultivation, the appendages are cultivated roots, while vegetative irrigation is carried out by drip and / or fine irrigation, taking into account the programmed productivity of the green mass of vegetative dressings and grains; the depth of pre-arable loosening is determined by calculation from the expression a ₃ = (KB _k ) / 2 • tan θ / 2, where K is the track of an aggregated tractor engaged in an energy-intensive technological operation, such as plowing; B _k is the width of the track or tire of the tractor aggregated with an agricultural machine; θ is the cleavage angle of the arable layer;
the step between the ridges is determined by the formula h _gr = b _g sinφsinγ / (sinφ + sinγ), where b _g is the step between the ridges; φ is the angle of repose of the upper humus layer of the soil; γ is the angle between the horizon and the surface of the hollow slope of the ridge;
the shift of the axis of the row of amaranth plants from the intercostal depression is determined by the calculation according to the formula d = a ₄ / cos γ + b _p / 2, where a ₄ is the depth of seed placement in the soil on a gentle slope of the ridge; γ is the angle between the horizon and the surface of the hollow slope of the ridge; b _p - the width of the flanges on the left and right coulter discs;
crafts of water-absorbing cracks are carried out to a depth of 0.10-0.25 m with a width of not more than 0.02 m; the hilling of the additional roots on the butt of the stalks of amaranth is carried out in the phase of 12-16 leaves to a height determined by the calculation from the formula h ₀ = (b _c • tgφ) / 2, where b _c is the row spacing; φ is the angle of repose of the upper soil layer;
vegetative irrigation is carried out with norms of 200-500 m ³ / ha to maintain soil moisture in the root layer in the range of 70-80% HB; during a stable drought, irrigation is combined with fine sprinkling with norms of 50-80 m ³ / ha with an interval between humidifications of 1.5-2 hours; nitrogen fertilizers are applied fractionally with irrigation water at the rate of 10-30 kg a.m. when cultivating silage species of amaranth; nitrogen fertilizers and microelements are introduced during the first watering at the rate of 5-10 kg ai. when cultivating amaranth on seeds.

Due to the fact that the bulk of cold-resistant and heat-loving weeds are destroyed in three stages, the work of crests with a gentle slope ensures soil heating to a depth of 6-10 cm to + 10-12 ^o C and, accordingly, shifts the beginning of sowing dates by 5-6 days to more early period, this ensures the intensive development of amaranth plants in comparison with heat-loving weeds and the above technical result.

 An analysis of the level of technologies (methods) and technology by the applicants, including a search by patent and scientific and technical sources of information and identification of sources containing information about analogues of the claimed invention, made it possible to establish that the applicants did not find analogues as part of the method, characterized by features identical to all the essential features of the claimed invention. The proposed closest analogues made it possible to identify a set of significant distinguishing features in relation to the technical result perceived by the applicants in the claimed method set forth in the claims.

 Therefore, the claimed invention meets the requirement of "novelty" under applicable law.

 To verify the conformity of the claimed invention to the requirements of the inventive step, the applicants conducted an additional search for known methods and technical solutions in order to identify signs that match the distinctive features of the claimed invention from the closest analogue. The results of the verification show that the claimed invention does not follow for the specialist explicitly from the known level of technology and technology, in particular, the claimed invention does not provide for known transformations.

 Therefore, the claimed invention meets the requirement of "inventive step" under applicable law.

 The invention is illustrated by diagrams and drawings.

 In FIG. 1 shows a cross section of an old plow horizon with a stubble background of its predecessor.

 In FIG. 2 - the same, but after performing two technological operations: the pre-arable strip loosening of the old plow layer and the subsurface horizon and the surface continuous disking (peeling) of the stubble of the predecessor.

 In FIG. 3 - a cross section of the upper soil horizon after integumentary harrowing and cultivation of the upper layer with a craft of complex profile: ridges with gentle and steep slopes.

 In FIG. 4 is a cross section of a field after sowing amaranth seeds and local row compaction.

 In FIG. 5 - a ridge fragment after sowing amaranth seeds on a gentle slope of the southern exposure.

 In FIG. 6 - profile of the field under the crops of amaranth after the first inter-row cultivation.

 In FIG. 7 - profile of the field after the second combined cultivation and crafts of narrow slots.

 In FIG. 8 - profile of row-spacing after the third cultivation, hilling of the stem and additional (air) roots of amaranth.

 Information confirming the possibility of implementing the claimed invention are as follows.

 Amaranth is an annual plant, belongs to the Amaranth family, the genus Amaranth. Amaranth is a herbaceous plant with a height of 1.7 to 2.5 m. The stem is straight, branched, 1.6-3 cm thick. Leaves with long stalks, oblong-elliptical, acute at the apex, wedge-shaped at the base. Inflorescence is a large panicle of various shapes up to 40-60 cm long. Seeds are small, shiny, white, black and pale pink. The weight of 1000 seeds, depending on the species, is 0.45-0.90 g. The foliage of the plants in the mowing ripeness is 25-35%, and the dry matter content is 16-18%.

Amaranth is a light and heat-loving plant. The optimum air temperature for its growth is + 20-35 ^o C. Seeds of all types of amaranth germinate when the soil is warmed up at a depth of 6-8 cm to 8-10 ^o C. At a soil temperature of up to 16 ^o C and sufficient moisture, seedlings appear at 4 -5 day.

 Amaranth sprouts are very small, pink or light green in color, experiencing a high need for light and heat. At the initial stage, plants develop slowly. But during this period there is an active growth of the root system. Then overhead shoots intensively develop.

At an air temperature of 30-40 ^o C and sufficient soil moisture, the average daily growth is 6.5-7.5 cm.

 Amaranth is resistant to summer drought, but grows better with good moisture supply. Drought tolerance is due to the economical use of water. Amaranth refers to photophilous plants, especially these requirements are strict in the initial period of growth. Subsequent phases of development require good lighting.

The duration of the growing season of amaranth depends on the type of plant, cultivation zone and is 90-130 days. To obtain complete seeds you need the sum of positive temperatures in the range of 1900-2800 ^o C.

 Amaranth is a high-yielding fodder plant. The yield of its green mass in the main soil and climatic zones of the country exceeds the yield of green mass of corn by 20-30% and amounts to 50-80 t / ha. In every 100 kg of green mass contains 15-18 ke At 1 ke in the green mass of amaranth, there are 180-280 g of digestible protein, the gross yield of which is 1.5-2.0 t / ha.

 The best predecessor of amaranth are annual herb mixtures, perennial legumes and cereals, as well as row crops and crops of early ripening varieties. It is advisable to place amaranth in feed crop rotations. Amaranth does not impose strict requirements on the predecessor.

After harvesting the precursor, the arable horizon 1 has the form shown in FIG. 1. Long-term tillage - plowing with plows with dump hulls or racks of the SibIME design led to the formation of a stable moisture-proof and difficult to pass plant roots plow sole 2 3-4 cm thick at a depth of a ₁ . The depth of the arable horizon a ₁ depends on the type of soil and fodder or grain crop rotation. The average value of a ₁ varies between 25-29 cm. For the extremely arid zone of the south of the Russian Federation, the plow sole 2 has a harmful effect on the development of the amaranth root system and on the diet when using soil moisture and when sprinkling. For this reason, before performing all necessary agrotechnical measures after harvesting the predecessor, strip loosening of the arable and subsurface horizons is carried out. The loosening depth a _{3 is} set within 30-35 cm. The loosening step K is chosen so that between the adjacent loosening zones 3 and 4 there remains an untreated (un loosened) strip B _k with a width equal to or the width of the drive wheel of the T-150K or BT- tractor 130, or the width of the caterpillar branch of the T-150, BT-100, DT-175C and other tractors. After passing through the racks of cultivators produced by agricultural machinery of the Russian Federation, 1 loose strips 12-15 cm high remain above the arable horizon. The width of two adjacent untreated strips B _k is a tramline for the passage of the trail aggregates.

The depth of pre-arable loosening is established by calculation from the expression a ₃ = (KB _k ) / 2 • tan θ / 2, where K is the track of an aggregated tractor engaged in an energy-intensive technological operation, for example, plowing;
B _k is the width of the track or tire of the tractor aggregated with an agricultural machine;
θ is the cleavage angle of the arable layer.

 This condition requires rigorous implementation for high-quality performance of all subsequent technological operations.

Before stubble 5, taking into account the pH of the soil, lime is introduced in 2-3 decades of August, and at the end of August - mineral fertilizers, mainly phosphorus, less often potash. The stubble peeling is carried out on the same track with an aggregate including a DT-75M tractor and an LDG-10 disk cultivator. The depth of peeling a ₂ within 8-10 cm set by changing the angle of attack of the disk batteries. Then make organic fertilizers. The dose of organic fertilizers is calculated taking into account previously introduced organics under the predecessor. Agricultural units: MTZ-80/82 + ROU-6 or T-150K + PRT-10.

Plowing with termination of crop residues and organics is carried out by general-purpose plows with the obligatory installation of skimmers and a circular knife in front of the last building. Plowing is carried out to a depth of a ₁ within 25-29 cm.

 In conditions of irrigated agriculture, provocative irrigation is carried out with multi-support sprinkler machines DMU Fregat or EDM Kuban-LK on the third or fourth day after the completion of plowing the entire site. Perpendicular to the plowed field, 10-12 days after plowing, the plot is cultivated with steam cultivators with lancet cultivating paws with a width of 270 + 330 mm. The cultivation is carried out to a depth of 6-8 cm. For each cultivator KPS-4 set four sections of the middle tooth harrows BZSS-1,0. This operation achieves the leveling of the terrain and the destruction of heat-loving weeds.

 In September, there are still plenty of warm days, and for this reason perennial root shoots and annual weeds intensively develop, as well as the seeds of the predecessor that remain on the surface of the plowed field. Perpendicular to the direction of the first autumn cultivation, two-track harrowing of the upper layer is carried out with BZSS-1,0 harrows in an aggregate with a DT-75M tractor through an SP-11 coupler. The depth of cultivation of the harrow teeth should not be less than 5-6 cm. The loosened top layer eliminates moisture loss from the arable horizon. A large amount of precipitation in the autumn leads to the accumulation of soil moisture in the arable and in the arable horizons. Due to loosening zones 3 and 4, part of the accumulated moisture penetrates into the lower soil horizons. At the same time, chemical reactions of fertilizers with soil aggregates, decomposition of organic residues and soil-forming processes occur.

 In the spring of next year, early spring harrowing is carried out to close the moisture and destroy the germinated weeds. After that, immediately, as necessary, make surface potash and nitrogen fertilizers. The application of mineral fertilizers is carried out by the MTZ-80 tractor and the uniaxial spreader of mineral fertilizers 1 RMG-4.

 Next, a surface pre-sowing preparation of the soil is carried out by an aggregate equipped with cultivating paws and crest formers. The unit contains a tractor DT-75M and a cultivator KPS-4 with added combing agents.

When embedding mineral fertilizers at the same time form a complex profile. The ridges 6 and 7 (see Figs. 3 and 5) are formed with different slopes. Gently sloping ridges 6 are oriented towards the highest illumination. Steep ridges 7 form the slopes of the northern exposure. The step between the ridges b _{g is} taken equal to the row spacing b _s . From the practice of cultivating amaranth, the width b _s under irrigation conditions is taken to be 0.45 or 0.6 m.

The height of the ridges h _gr is determined by the calculation of the expression h _gr = b _g sinφsinγ / (sinφ + sinγ), where b _g is the step between the ridges;
φ is the angle of repose of the upper humus layer of the soil;
γ is the angle between the horizon and the surface of the hollow slope of the ridge.

Solar energy is maximally captured by the southern exposure of the hollow 6 ridge. The temperature of the soil in a layer of 0-10 cm is warmed up to 10-12 ^o C. With the maximum preservation of soil moisture reserves, sowing seeds of 8 amaranth is carried out at the same time as corn hybrids.

The seeds are sown with wide-seeders of the applicants' design with a row spacing of 0.45 (0.60) m. The seeders are equipped with disc coulters with restrictive flanges mounted on the sides of the coulter flat disks. The sowing depth a _{4 is} set by selecting the diameter of the flange rings and the diameter of the flat coulter disc. The width of the supporting surface (b _p ) is 5-6 cm.

To obtain stable seedlings of seeds 8, the axis of the row 9 of amaranth plants is shifted from the intercostal hollow. The displacement value d is determined by the formula d = a ₄ / cos γ + b _p / 2, where a ₄ is the depth of seed placement in the soil on a gentle slope of the ridge; γ is the angle between the horizon and the surface of the hollow slope of the ridge; b _p - the width of the flanges on the left and right coulter discs.

 After sowing, immediate post-sowing local rolling of rows of 9 is carried out immediately. This operation is carried out by discs with a diameter of 300-500 mm mounted pivotally in the alignment of disc coulters (see Fig. 5).

 When stable seedlings appear in the phase of 2-3 amaranth leaves, the first inter-row processing is carried out using shields - houses of the KRN-5.6 cultivator-plant feeder and a row harvester for leveling the relief of 10 rows between rows (see Fig. 6).

 The second cultivation is carried out with the craft of water-absorbing slots 11 (see Fig. 7). The craft of water-absorbing slots 11 is carried out to a depth of 18-20 cm with a width of not more than 2 cm.

Amaranth plants have a root type of root. The lateral roots of the plant are superficial. As in corn, additional roots are formed in the lower part of the amaranth stem. The bulk of the root system develops in the arable layer a ₁ . The main root has a conical shape. The length of its thickened part does not exceed 20 cm. By the flowering phase of amaranth, its root penetrates to a depth of 60 cm. This is facilitated by deep strip loosening to a depth of a ₃ . The lateral roots of amaranth are located in a horizontal direction in a radius of up to 0.8 m. The proportion of the root mass is about 15-18% of the total mass of the plant (aerial parts). For this reason, the third cultivation is performed with the earthing up of the root part of amaranth plants with its air (subordinate) roots. The hilling of the additional roots on the butt of the stalks of amaranth is carried out in the phase of 12-16 leaves to a height determined by the calculation from the formula h ₀ = (b _c • tgφ) / 2, where b _c is the row spacing; φ is the angle of repose of the upper soil layer.

Vegetative irrigation is carried out by drip and fine irrigation, taking into account the programmed productivity of the green mass of vegetative shoots and grain. Vegetative irrigation is carried out with norms of 200-500 m ³ / ha to maintain soil moisture in the root-inhabited layer within 70-80% of HB. In the period of sustained drought, irrigation is combined with fine sprinkling with norms of 50-80 m ³ / ha with intervals between irrigation of 1.5-2.0 hours at an ambient temperature above + 30 ^o C.

 Amaranth is characterized by a special type of photosynthesis, which allows the highly efficient use of solar radiation and moisture. This ensures the rational use of soil and climatic conditions. Amaranth makes good use of solar energy. Amaranth leaves contribute to this. The leaves are alternate, whole, without stipules, whole-marginal, pointed at the apex with a wedge-shaped base. Upper leaves have shorter petioles than lower ones. This creates the opportunity for uniform illumination of plants and the use of solar energy.

 Nitrogen fertilizers are applied fractionally with irrigation water at the rate of 10-30 kg d. when cultivating silage species. Harvesting for green top dressing of silage species is carried out by the KSK-100 forage harvester in the phase of the beginning of flowering. The mass is ground with a cutting length of 3-4 cm. The ground mass is delivered to feed the animals.

 Harvesting for silage is carried out in the flowering phase until milky-wax ripeness of seeds by the KSK-100 combine. The green mass is delivered by a tractor dump truck 2PTS-4 in aggregate with a tractor MTZ-80. The mass is crushed and delivered to silage. Silos in a mixture of 1: 1-1.5 with the green mass of corn or grasses.

 When cultivating amaranth on seeds, nitrogen fertilizers and trace elements are introduced during the first watering at the rate of 5-10 kg a.a.

 Depending on the type of amaranth and the maturity of the panicle, they are harvested either by direct combining or separately. For direct combine harvesting, combine harvesters of the Don-1200 (Don-1500), Yenisei and other families are used. Combines are subjected to sealing. This eliminates over 103 channels of seed loss. This operation is carried out with full ripening of seeds and, as a rule, after frosts. The stalks dry out. The seeds are immediately threshed, cleaned and dried to a moisture content of 10-12%.

 Separate combine harvesting is carried out by the sorghum harvesting machine SM-2.6 and the KSS-2.6 forage harvester. The first machine is aggregated with a MTZ-80 tractor, and KSS-2.6 combines with a DT-75M tractor. A sorghum harvesting machine SM-2.6 cuts panicles at a given height from six rows when sowing a row spacing of 0.45 m. Cut panicles are carried out in the fully ripening phase. The panicles of the SM-2.6 sorghum truck are unloaded into the 2PTS-4 tractor dump trailer. The trailer body is sealed. Panicles are delivered to the site of primary part-time and threshing. Threshing panicles lead on a specially equipped site. Combine harvesters Don or Yenisei are installed on a site covered with a canvas canopy. Amaranth bunker grain is subjected to drying and cleaning by seed machines available in the farm.

 Purified and dried seeds at a moisture content of 10-12% are packed in bags weighing up to 50 kg. Bags are stored in stacks of 4-5 bags in a dry, ventilated area. Calibration of the seeds is required.

 The effectiveness of the claimed method is confirmed by the three-year data presented in tables 1 and 2.

 Thus, the above information indicates the fulfillment of the following conditions when using the claimed invention: the claimed method is intended for use in agriculture (crop production) when cultivating a heat-loving crop, amaranth for seeds (grain) and silage; the possibility of carrying out the invention is achieved using known methods and means; the proposed method of cultivation has high efficiency, achieved at all stages of the life cycle of plants, from soil preparation, destruction of weeds, sowing seeds, their growth and ending with the final phases of development; The cultivation method relates to intensive farming and at the same time favorably affects the soil. The proposed method is characterized by wide capabilities.

 Therefore, the claimed invention meets the requirement of "industrial applicability" under applicable law.

Claims (10)

 1. A method of cultivating amaranth in irrigated agriculture, including the selection of the predecessor and the timing of its harvesting, the application of lime and phosphorus fertilizers, stubble cultivation, the application of organic fertilizers, plowing with a full turn of the reservoir, leveling the terrain, early spring harrowing, pre-sowing cultivation, sowing, inter-row care , vegetation irrigation and harvesting, characterized in that after harvesting the predecessor, pre-arable strip loosening of arable and subsurface horizons with a width of untreated between them is carried out Olos, equal to the track occupied by the most energy-intensive process of the agricultural unit, after plowing, provocative irrigation is carried out, presowing cultivation is combined with the work of the ridges with sloping sloping and steep slopes and with a step between the ridges equal to the row spacing, while the gentle slopes are oriented in the direction of highest illumination, sowing is carried out on a gentle slope and combined with local post-sowing row rolling, the first inter-row treatment is carried out in a phase of 2-3 stable foxes b GB using flaps, houses and simultaneously align harrows relief row spacing, combined with a second cultivation crafts water-absorbent slits in the third cultivation operate ridging adventitious roots, while vegetative irrigations performed droplets and particulate sprinkling with the programmed productivity of green mass of vegetative shoots and grains. 2. The method according to claim 1, characterized in that the depth of arable tillage is read from the expression a ₃ = (K - B _k ) / 2tgθ / 2, where K is the track of an aggregated tractor engaged in an energy-intensive technological operation, for example, plowing; In _to - the width of the tracks or tires of a tractor aggregated with an agricultural machine; θ is the cleavage angle of the arable layer. 3. The method according to p. 1, characterized in that the height of the ridges is determined by the formula h _gr = b _g sinφsinγ / (sinφ + sinγ), where b _g is the step between the ridges; φ is the angle of repose of the upper humus layer of the soil; γ is the angle between the horizon and the surface of the hollow slope of the ridge. 4. The method according to p. 1, characterized in that the displacement of the axis of the row of amaranth plants from the intercostal cavity is determined by the formula d = a ₄ / cosγ + b _p / 2, where a ₄ is the depth of seed placement in the soil on the gentle slope of the ridge; γ is the angle between the horizon and the surface of the hollow slope of the ridge; b _p - the width of the flanges on the left and right coulter discs.  5. The method according to claim 1, characterized in that the craft of water-absorbing slots is carried out to a depth of 0.10 - 0.25 m with a width of not more than 0.02 m. 6. The method according to claim 1, characterized in that the hilling of the adventitious roots on the butt of the stalks of amaranth is carried out in a phase of 12 to 16 leaves to a height determined by the formula h ₀ = (b _s • tgφ) / 2, where b _s is the width row spacing; φ is the angle of repose of the upper soil layer. 7. The method according to claim 1, characterized in that the vegetation irrigation is carried out with norms of 200-500 m ³ / ha to maintain soil moisture in the root layer within 70 - 80% of the humidity norm. 8. The method according to claim 1, characterized in that during a period of sustained drought, irrigation is combined with fine sprinkling with norms of 50 - 80 m ³ / ha with an interval of 1.5 - 2.0 hours  9. The method according to claim 1, characterized in that the nitrogen fertilizer is applied fractionally with irrigation water at the rate of 10-30 kg of the active substance when cultivating amaranth on a silo.  10. The method according to claim 1, characterized in that nitrogen fertilizers and microelements are applied during the first watering at the rate of 5-10 kg of active substance when cultivating amaranth for seeds.

Images