RU2130242C1 - Method for cultivating grain sorghum on light-chestnut soil and seeding unit - Google Patents

Abstract

FIELD: agriculture. SUBSTANCE: method involves harvesting precursor and preparing soil in accordance with agricultural procedures aimed at elimination of cold-resistant and warm-loving weeds; combining seeding of sorghum grains at row spacing of 70 cm and band application of herbicides onto cut surface at working pressure of 0.020-0.035 MPa by forming furrows offset with respect to seed bed axis and having inclined and vertical walls; compacting inclined furrow walls faced toward seed bed; applying herbicides on vertical mellow walls; covering furrows with mellow soil to form seed bed. Vertical and inclined walls formed in protective zones are offset with respect to seed bed by distance of 1/4-3/8 of width of protective zone. Seeding unit has tractor, mounted drill and herbicide applying device. Drill has frame, hitch brackets, carrier wheels, markers and seeding sections. Herbicide applying device has herbicide reservoir, drive pump, boom, flexible hoses and sprayers. Each seeding section has device for forming furrows with vertical mellow walls and inclined compacted walls. Furrow forming device has pole with shaft mounted within pole for rotation. Disks with conical flanges on facing disk surfaces are fixed in opposed relation to shaft. Disks are interconnected by shifting mechanisms made in the form of threaded sleeves mounted on threaded part of shaft. Disk is mounted on outer part of threaded sleeve and fixed on it. Conical flanges are detachably mounted on disks. Pole is fixed on seeding section bracket. Furrow forming device is positioned forward of furrow cutter and herbicide sprayers are positioned between disks and furrow cutter. EFFECT: increased efficiency and provision for obtaining high-quality, ecologically clean grain sorghum product. 7 cl, 12 dwg, 17 tbl, 2 ex

Description

 The invention relates to agricultural production, mainly to the technology of cultivating grain sorghum on light chestnut soils of the Lower Volga region in non-irrigated and irrigated agriculture.

The known technology of cultivating grain sorghum on light chestnut soils in conditions of insufficient moisture, including harvesting the predecessor, stubble cultivation, plowing with a turnover of the formation to a depth of 25-27 cm, early spring cover harrowing, pre-sowing cultivation when the soil temperature reaches 15 - 17 ^o C and 25 - 27 ^o C, sowing to a depth of 8 cm with a sowing rate of 450 thousand pieces per hectare, post-sowing rolling, pre- and post-emergence harrowing, row-spacings on wide-row crops (see Information sheet N225-96 of Volgogradsky CSTI Features of technology, cultivation of grain sorghum on light chestnut soils of the Volgograd region // Compiled by V.N. Churzin and T.A. Lyubimenko. - Volgograd, 1996.- P. 4).

 The disadvantage of the described technology is the large weediness of grain sorghum crops on light chestnut soils by early and heat-loving weeds. At the initial stage of organogenesis, sorghum plants cannot compete with the growth rate of weeds. Sorghum stalks are shaded and suppressed. The yield loss of zoned sorghum varieties can reach more than 45%. The described technology does not provide for the application of mineral fertilizers and herbicides.

The closest method to the claimed technology relates to a method of cultivating heat-loving field crops, mainly corn, sorghum, Sudan grass, millet in areas with high temperatures during the growing season, including autumn main and spring pre-sowing soil preparation, sowing with subsequent rolling, post-harvest harrowing and post-emergence care for crops, in which in addition to spring pre-sowing treatment after a steady increase in average daily soil temperature of at least 14 - 16 ^o C to a depth of 10 cm wasp soil rolling with an increase in the bulk density of the surface layer by 30–40%. After germination of late heat-loving weeds in the seed layer in the “strand” stage, the germinated weeds are destroyed and sowing in the wet layer is carried out (see RU, patent, N 2073398. The method of cultivating heat-loving field crops. IPC ⁶ A 01 B 79/02 // I. D. Shishlyannikov and A. M. Saldaev. Declared October 14, 1994, published February 20, 1997).

 The disadvantages of the described method of cultivation, in particular, sorghum, should include a large number of mechanized operations, stretched in space and time. Despite the fact that most of the early cold-resistant and heat-loving weeds are destroyed before sowing, heat-loving competing weeds remain in the protective zones and suppress the whimsical plants of grain sorghum. The described technology does not involve the use of herbicides. However, the destruction of weeds in the protective zones mechanically leads to damage to the stems and roots of sorghum at the initial stage of development.

There is also known a method of cultivating row crops, including applying the herbicides in a tape to 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 cut surface is loosened to a depth of 3-4 cm and the seeds are sown into the ridge cut with simultaneous application herbicide under a pressure of 3.5 atm (see RU, patent, N 2082293. IPC ⁶ A 01 B 79/00. Method for cultivating row crops // MA Bzikov. Declared June 23, 1994, published June 27, 1997 .)
The herbicide is applied superficially to a section of the ridge and to the moist soil layer. However, the effectiveness of the described method of applying the herbicide is very small. When sowing after applying the herbicide with keeled openers of a pneumatic seeder, for example SUPN-8, the soil layer is shifted on the ridge towards its slopes. After laying sorghum seeds on the seed bed, the seeds are sprinkled with soil untreated with the herbicide. With the growth of sorghum plants, heat-loving weeds grow favorably in the protective zone, which, together with weeds on the slopes of ridges and inter-ridge space, inhibit the growth of cultivated plants. Surface application of the herbicide at a soil temperature above 15 ^o C reduces its effectiveness, and at a wind speed of more than 5 m / s leads to environmental pollution.

 A precision seeder is also known, which contains a frame, support wheels, linkage bracket, left and right markers, eight seed sections with vertically arranged discs. Each sowing section contains a bracket, a four-link parallelogram mechanism, a housing, a seed box, a furrow cutter, a coulter, a coulter coulter, support and packer rollers, section covers (see, for example, the textbook Agricultural and Land Reclamation Machines edited by academician VASKHNIL, professor G.E. Listopada.-2nd ed., Revised., Supplement // -M .: Agropromizdat. -1986. - 688 p., -Il. -S. 85-86, Fig. 1.50, SU 1473728 A1, 04/23/89).

 Despite the fact that the seeder provides accurate and high-quality sowing of grain sorghum seeds at a given sowing depth, it is not suitable for narrow-band application of soil herbicides, which exclude a negative effect on seed sprouts.

 Also known is a universal feed dresser-sprayer POU, designed for chemical weed control. The POU kit includes two tanks with a capacity of 300 l each, a drive pump, a control panel, an ejector, a suction and pressure lines, a universal bar and mounting devices for mounting on various tractors (see Agricultural and reclamation machines / G.E. Listopad, G. K. Demidov, B.D. Zonov and others; Under the general editorship of G.E. Listopad. - M.: Agropromizdat, 1986. - 688 pp., Ill. - (Textbooks and study guides for higher education institutions.) - S. 112-114, Fig. 1.64).

 The POU universal feed-sprayer boom is not intended for local application of the herbicides in a narrow strip and does not exclude the dispersal of sprayed herbicides by the wind over the surface of the sown field. This leads to environmental pollution.

 The invention consists in the following.

 The problem to which the invention is directed is to produce environmentally friendly products of grain sorghum on light chestnut soils of the Lower Volga region in rainfed and irrigated agriculture with extremely arid climate during the growing season with intensive growth of heat-loving weeds during germination.

 EFFECT: guaranteed production of grain sorghum seeds in the range of 4.0-8.0 t / ha.

 The specified technical result in the implementation of the invention is achieved by the fact that in the known method of cultivating grain sorghum on light chestnut soils, including, in addition to known agricultural techniques, the tape application of herbicides on the cut surface under pressure and sowing the seeds, form grooves with the offset from the axis of the seed bed vertical and inclined walls, while the inclined walls facing the seed bed are compacted, herbicides are applied to the vertical loose walls, and the grooves are covered with loose the soil before the formation of the seed bed; vertical and inclined walls are formed in the protective zones with a shift from the seed bed to a distance of 1 / 4-3 / 8 of the width of the protective zone.

 For the implementation of this method, a sowing unit is provided in which a mounted seeder, tractor and a universal feeding sprayer (POU) are connected, the seeder comprising a frame, a hitch bracket, support wheels, markers, sowing sections, herbicide tanks, a drive pump, a rod, flexible pipelines and sprays, each sowing section is equipped with a device for making grooves with vertical and inclined sealed walls in the form of a rack with mounted disks with conical flanges facing each other in planes, the wheels on the axles are interconnected offset mechanisms; the displacement mechanism of each disk of the device for making grooves is made in the form of a threaded foot placed on the threaded part of the axis of the device, while the disk is mounted on the outer part of the threaded foot and fixed on it; conical flanges on disks are installed with the possibility of dismantling; the device rack is mounted on the bracket of the seed section; a device for making grooves is placed in front of the groove cutter, and herbicide nebulizers are installed between the disks with conical flanges and the groove cutter.

 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 (both in part of the method and in part devices for implementing the method), characterized by features identical to all the essential features of the claimed invention. The proposed closest analogues for the method and for the device (unit) made it possible to identify the totality of distinctive features existing in relation to the technical result perceived by the applicants in the claimed method and sowing unit for implementing the 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 ones from the closest analogue of the claimed invention. 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.

In FIG. 1 shows a fragment of a sown field with seeds of grain sorghum sowing unit with eight sowing sections, plan view;
in FIG. 2 is a section AA in FIG. 1, a cross section of a row with vertical and inclined sealed walls;
in FIG. 3 - sowing combination unit for sowing seeds of grain sorghum, plan view;
in FIG. 4 - sowing section, left view;
in FIG. 5 - same, plan view;
in FIG. 6 is a section BB in FIG. 4, a device for making grooves with vertical and inclined sealed walls;
in FIG. 7 - increase in air temperature in the initial period of plant growth;
in FIG. 8 - growth rate of heat-loving weeds;
in FIG. 9 - actual weediness of grain sorghum crops during cultivation according to the basic technology;
in FIG. 10 - the same, according to the claimed method;
in FIG. 11 - weediness of grain sorghum under irrigation during cultivation according to the basic technology;
in FIG. 12 - the same, according to the claimed method.

 The proposed method is implemented as follows.

Example 1. The cultivation of zoned varieties of grain sorghum in the conditions of dry farming on light chestnut soils of the Lower Volga. After harvesting the precursor, preferably winter wheat, double stubble cultivation is carried out by the LDG-10 cultivator in combination with the DT-75M tractor in two mutually perpendicular directions. The angle of attack of the disk batteries is set equal to 20 ... 22 ^o to the direction of movement. Depth of processing 5 ... 6 cm. Weed seeds are planted to this depth, where they germinate. The main processing is carried out with dump plow plows equipped with circular knives and skimmers, for example Ш1Н-5-35 in an aggregate with a caterpillar tractor of class 3 tf DT-75M or a plow, for example, PLN-8-35, in an aggregate with a tractor of draft class 5tc K - 701.

The selected field for cultivating grain sorghum was characterized by light chestnut soil. The mechanical composition of the soil is medium and heavy loam. The capacity of soil absorption in the arable horizon is high - 26-30 mg. eq. per 100 g of soil. The content of absorbed Ca is 62%, Mg is up to 30% of the amount of absorbed bases, and Na is 2.5-3.2%. The reaction of the soil solution is slightly alkaline, varies from 7-7.5, and the alkalinity increases with the deepening of the arable and subsurface layer. The humus content in the root-inhabited layer is low - 1.5-2.0%. According to the content of basic nutrients, the horizon is characterized by the following indicators: hydrolyzable nitrogen - 4.8- 16.8 mg / 100 g of soil, available phosphorus - 2.7-5.3 mg / 100 g of soil, exchange potassium -41.3 - 53 , 0 mg / 100 g of soil. The density of addition over soil horizons varies from 1.1 to 1.64 g / cm ³ . The soil density on average for a layer of 0-100 cm is 1.33 g / cm ³ . The specific mass of the soil layer 0-100 cm does not exceed 2.72 t / m ³ . The effectiveness of the claimed method of cultivating grain sorghum was tested on the example of cultivating two recommended varieties: zoned in the Volgograd region Volgograd 20 and promising varieties - Skorospeloe 98.

 The selected field for the subsequent sowing of grain sorghum after the main tillage was not subjected to other types of cultivations. In the extremely arid conditions of the Lower Volga region of the Russian Federation, the task is to accumulate the maximum amount of moisture in the arable and root-inhabited horizons in the autumn-winter period.

 After the snow cover is removed, an early spring closing of the moisture of the plowed field is carried out by an aggregate including a caterpillar tractor of draft class 3 tf DT-75, coupler SP-16 and 3BZS-1 middle tooth harrows installed in 2 tracks. Harrowing is carried out across the direction of the ridges after autumn plowing by a plow. When harrowing with teeth, the top layer is loosened, soil blocks are cut into agronomically valuable lumps, and the field surface is leveled. This minimizes moisture loss in the arable layer.

 The preparation of grain sorghum seeds is carried out in accordance with the recommendations for cultivating sorghum crops in the Volgograd region or the instructions set out in the recommendations (see, for example, Intensive technology for growing grain sorghum on irrigated lands. Recommendations // Compiled by IP Kruzhilin, V. M. Ivanov, Yu.P. Danilenko and V. M. Kireev. - Volgograd. - 1990. - 13 pp. - S. 6-7 or Recommendations for the cultivation of sorghum crops in the Volgograd region // Compiled by E.Ya. Seredintsev , V.V. Doronin, V.V. Melikhov et al. - Volgograd. - 1988. - 22 p. - S. 9).

When warming the soil to 5-6 ^o C by plowing, the first cultivation is carried out to a depth of 5-6 cm by KPS-4 cultivators with lancet paws with a working width of each 270 mm and additional loosening by single sections of 3BZSS-1 tooth harrows. The first cultivation is carried out at operating speeds not higher than 7-8 km / h across the direction of plowing. In this case, intensive crumbling of the upper layer and complete destruction of the early cold-resistant weeds are carried out. The species composition of weeds on crops of grain sorghum in the Lower Volga region is presented in Table 1. The presence of a loosened upper mulching layer eliminates the loss of moisture from the soil.

Upon reaching a steady increase in the average daily soil temperature of not less than +14 ... + 16 ^o C at a depth of 10 cm, surface rolling of the soil is carried out. Soil rolling is carried out by ZKVG-1.4 smooth water-filling rollers or ZKKSh-6A ring-spur rollers connected by an SP-16 hitch. The rollers and hitch together with a tractor of draft class 3 those DT-75M (VT-100) form an aggregate. The cavity of the ZKVG-1.4 rollers is filled as much as possible with water, and the ballast boxes of the ZKKSh-6A rollers are filled with soil. The specific pressure per square centimeter increases to 0.030-0.035 MPa. With the passage of the described aggregate, the soil density in the layer of 0-10 cm increases by 25-30%. After rolling the surface of the field, the thermal regime of the soil changes dramatically. Due to the increase in soil density, moisture from the underlying layers rises to the upper layers by capillaries. At the same time, an increase in soil temperature occurs. Late in terms of germination, malicious weeds, presented in table 2, begin to sprout together.

 After 4-6 days after rolling on, the seedlings of these weeds appear on the day surface of the field. Emerging weed shoots are destroyed by subsequent pre-sowing cultivation. For this, the steam cultivator KPS-4.0 is adjusted at the technological site to a cultivation depth of 6-8 cm. This cultivation is carried out in the orthogonal direction of the previous passage of the unit. Following the cultivating unit, the sowing unit moves.

Sorghum is a thermophilic culture. Its sowing begins at soil temperature at a depth of 10 cm not lower than +15 ... + 17 ^o C. The best way to sow grain sorghum is dashed with 70 cm row spacing. The sowing rate of zoned varieties when cultivated according to the basic technology (control) Kamyshinskoe 75 - 280 ... 300 thousand units / ha. Volgograd 20 - 350 ... 400 thousand germinating seeds per hectare. When using herbicides, the most progressive method under irrigation conditions is ordinary ordinary sowing at a rate of 1.0 ... 1.2 million germinating seeds per hectare. Sowing is carried out by pneumatic six- or eight-row seeders SPCh-6 or SUPN-8. In the basic version, the following operations were carried out in the early spring: cover harrowing in two tracks, early spring cultivation to a depth of 4-6 cm at a soil temperature of 6-8 ^o C in a layer of 0-10 cm, presowing cultivation to a depth of 6-8 cm at a soil temperature +14 ... + 16 ^o C in a layer of 0-10 cm, presowing application of ramrod herbicides, 65% sp, oleogesaprim, 40% mms at a dose of 2-5 l / ha and zeapos-10 (mayazine), 15 % mms at a dose of 5.3-13.3 l / ha, applied by spraying the soil with POU, OH-400, Kerkitoks and other sprayers, sowing seeds to a depth of 6-7 cm at a soil temperature of 14- 16 ^o C and post-sowing rolling ring-spur rollers ZKKSH-6A in the aggregate with a crawler tractor DT-75M (VT-100) at operating speeds of 7-8 km / h.

 The claimed method of cultivating grain sorghum on light chestnut soils on dry lands is implemented as follows. On the prepared field described above, field 1 before sowing the seeds of grain sorghum (see Fig. 1 and 2) with an offset from the axis 2 of the seed bed 3 form grooves 4 and 5 with vertical 6 and inclined 7 walls. Inclined walls 7 facing the seed bed 3 are sealed. Herbicides for controlling late heat-loving weeds in the protective zones 8 and 9 are applied with a fine spray at a pressure of 0.030-0.035 MPa with a droplet size of 300-500 μm onto vertical walls 6, the density of which is 6-8 times less than the compacted inclined walls 7. Grooves 4 and 5 are covered with loose soil until seedbed 3 is formed. This eliminates the accidental ingress of the herbicide onto the surface of the seeds of grain sorghum. Vertical 6 and inclined 7 walls of grooves 4 and 5 are formed in the protective zones 8 and 9 with an offset from the seed bed 3 at a distance of 1/4 - 3/8 of the width of the protective zone. The width of the protective zone b is taken to be 1/3 of the row spacing B. With the row spacing B = 70 cm, the value b = 23 cm. Vertical walls 6 from the axis 2 of the seed bed are shifted by a distance t = (1/4 -3/8) b = 6 ... 9 cm. When sowing grain sorghum in an ordinary way of sowing with a row spacing of 15 cm, vertical walls 6 are formed in the middle between two adjacent rows.

 The implementation of the claimed method is carried out by the sowing unit shown in FIG. 3. The sowing unit contains a wheeled tractor of 10 thrust class 1.4 tf MTZ-80/82, a mounted eight-row seeder 11 of the SST-8A brand of precision seeding, a mounted universal feeding machine sprayer 12 with the POU brand. The mounted seeder 11 comprises a frame 13, a hitch bracket 14, support wheels 15 and 16, multi-stage chain gears 17 and 18, markers 19 and 20, fertilizer devices 21 and sowing sections 22.

 The hinged universal feeder 12 includes two tanks 23 with a capacity of 300 l, a drive pump, a control panel, a rod located on the frame 13 of the seeder 14, flexible pipelines and standard sprayers. The sowing section 22 (see Fig. 3-5) contains a bracket 24, clamps 25 for mounting the bracket 24 on the frame 13 of the seeder 11, a four-link parallelogram mechanism 26, a seed box 27, a keeled opener 28, a furrow cutter 29, a front support wheel 30 of the sowing section 22, rear support wheel 31, sowing units 32 and 33 of the sowing section 22, a vertically mounted disc sowing unit 34, a mechanism 35 for changing the depth of the keel opener 28 and a device 36 for making grooves 4 and 5 with vertical and inclined sealed walls 6 and 7.

 The device 36 (see Fig. 4-6) is made in the form of a rack 37 with an axis 38 mounted therein with rotation possibility with opposed disks 39 and 40 with conical flanges 41 and 42 on the planes 43 and 44 facing each other. Disks 39 and 40 on axis 38 are interconnected by displacement mechanisms 45 and 46.

 The biasing mechanism 45 (46) is made in the form of a threaded foot placed on the threaded part 47 (48) of the axis 38 of the device 36. The disk 39 is mounted on the outer part of the threaded foot and secured to it by a nut 49 through a spring washer 50. The foot of the mechanism 45 on the threaded part 47 is fixed by a lock nut 51. The disk 40 on the threaded part 48 of the axis 38 is locked by a similar fastening of the disk 39.

The axis 38 in the rack is installed with the possibility of free rotation. This is facilitated by two sealed deep groove ball bearings 52 and 53 of a one-time lubrication. Ball bearings 52 and 53 are installed in the cup 54 and are fixed therein from axial displacement by the locking ring 55. The cup 54 is located in the lower part of the strut 37 of the device 35 and is connected to it by a closed annular seam. The taper flanges 41 and 42 are made of three standard sizes, respectively, for standardized sizes of flat disks 39 and 40. The size of disks 39 and 40 can be taken equal to 310, 290 or 270 mm. The thickness of the disks 39 and 40 is 2.5 mm. The peripheral part 56 of each disc 39 and 40 has an annular cutting edge with a sharpening angle of 12-15 ^o . With offset from the cutting edge, square holes are made to accommodate bolts 57 (M8) with countersunk head. Cone flanges 41 and 42 on disks 39 and 40 are installed with the possibility of dismantling. The conical flanges 41 and 42 on their inner conical surfaces have V-shaped brackets 58, which are fastened to the surfaces 43 and 44 of the disks 39 and 40 by means of nuts 59 (M8), flat and spring washers 60 and 61 (see Fig. 6).

 The stand 37 of the device 36 is mounted on the bracket 24 of the seed section 22. The device for making grooves 4 and 5 is located in front of the groove cutter 29. Herbicide sprayers are installed between the disks 39 and 40 of the groove cutter 29.

 The sowing unit is regularly prepared for work. Before starting work, the flow rate of the herbicide introduced onto the vertical walls 6 of the grooves 4 and 5 is additionally checked, as well as the sowing rate of the disk sowing devices 34 and the depth of the keel-shaped coulters 28 in each sowing section 22 when crafting seed beds 3. The length of the markers 19 and 20 is adjusted taking into account the tractor driver’s habits and the method of driving tractor 10 in the wake of marker 19 (20). If it is necessary to introduce mineral fertilizers into the fertilizer sowing apparatus 21, the fat of the corresponding fertilizer is poured. Mineral fertilizer application rates are specified taking into account the given characteristics of sorghum grain. Before starting the POU, check the tightness of the suction and discharge communications, pouring clean water into the tanks 23 of at least 50 l each. When the POU pump is on, each of the sixteen sprayers creates a torch with a diameter of 50-60 mm from a hole at a length of 100 mm. The diameters of replaceable nozzles are also specified in accordance with the actual consumption rate. With the steady movement of the sowing unit, the disks 39 and 40 of each sowing section 22 have their vertical edges 6 grooves 4 and 5 with their cutting edges on the peripheral parts 56. The conical flanges 41 and 42 compact the inclined walls 7 of the grooves 4 and 5. The spray torch is directed to the vertical walls 6 on which 90-95% of the sprayed herbicide is applied. From 5 to 10% of the working fluid enters the compacted surface of the walls 7. When moving a furrow cutter 29, the grooves 4 and 5 fall asleep with loose soil, while exposing the lower moist layer.

 A keel-shaped opener 28 opens the groove 3, and a vertically mounted disk apparatus 34 carries sorghum seeds from the seed box 26 and puts them on the bottom. The rear track roller 31 compacts the soil, and the earthing devices 32 and 33 level the surface topography of the field.

 Reserves of soil moisture and a stable positive temperature of the soil contribute to the emergence of sprouts, their intensive growth, the formation of the primary root system and aerial shoots. The compacted inclined walls 7 exclude the directed action of the herbicide, for example, oleogesaprim (2 ... 5 l / ha) or zeapos-10 (5, 3 ... 13.3 l / ha), or propazine (4 ... 5 kg / ha), while in the loose part and on the vertical walls 6, the soil herbicide inhibits the growth of weeds. Thus, sorghum plants are preserved in the protective zones along the row axes, and weeds are destroyed and suppressed without disturbing soil aggregates.

 The first inter-row cultivation of wide-row crops is started if necessary, taking into account the amount of precipitation and soil temperature, and often when rows of seedlings are indicated. For its implementation, lancet paws, left and right razor paws and shields-houses are used. The latter protect seedlings from falling asleep with soil. The total number of treatments is determined on each field based on weather conditions, soil conditions and the presence of weeds. The depth of treatments is 8 ... 10 cm. The second cultivation is carried out after 2 ... 3 weeks.

 The last inter-row processing is carried out with the installation of hillers together with loosening paws. Hilling helps root aerial roots and destroy weeds in a row.

 With a decrease in the moisture content of sorghum grain to 25%, plants are desiccated with a regulon dose of 3 ... 4 l / ha. The consumption rate of the working solution is 500 ... 600 l / ha. On wide-row crops for this use boom sprayers OPSh-15.

Sorghum is harvested 5 ... 7 days after desiccation only by direct combine harvesting with combine harvesters of 5-10 kg / s class. For this, the combine header will be refitted. Reel straps are replaced with frames with dimensions of 500x1740 mm. The frames are wrapped around the canvas, forming elastic blades. Reel axis is shifted towards the fingers of the cutting apparatus of the header. The angle of inclination of the blades to the radius of the reel set 15 ^o . The gap between the drum beams and deck levels for the SK-5M Niva combine is set at the input 24 ... 27 mm, and at the output 7 ... 10 mm. The frequency of rotation of the drum with its diameter of 600 mm should not exceed 10 s ^-1 (600 rpm).

 The translational speed of the combine should not exceed 0.7-0.8 m / s. The threshed sorghum grain is earned on mechanized currents of the ZAV-20 type (ZAV-4O, ZAV-10, etc.). The grain threshed by combines is stored at a moisture content not exceeding 30% in sections of concrete trenches with a capacity of 30 to 50 tons or in silos. The purified grain is covered with a plastic film and sealed. With intense breathing, the intergranular space is filled with carbon dioxide and self-preserving.

 Seed grain is actively ventilated, dried to 15% moisture, bagged and stored refrigerated in warehouses.

 When sowing seeds of grain sorghum in an ordinary way, the grain seeders SZP-3.6 are equipped as follows. A single disk 39 with a taper flange 41 is installed in front of each disk opener with a lateral offset of 7.5 cm. The sprayer for applying the herbicide is placed on the surface side of the disk 43 of the disk 39. Otherwise, the technological process of sowing and applying the herbicide occurs in the above sequence.

The claimed and existing methods of cultivating grain sorghum were tested on two sowing methods: wide-row with a row spacing of 70 cm, and an ordinary sowing method with a row spacing of 15 cm, and at two levels of soil temperature t _p = +15 ^o C and t _n = +25 ^o C, achieved by different sowing dates. Identification of the effectiveness of the claimed method of cultivating grain sorghum is established for two zoned varieties: Skoropeloe 98 and Volgograd 20. In the table. Figure 3 shows the soil moisture reserve in a layer of 0-50 cm depending on the timing and methods of sowing two varieties of grain sorghum. In the table. Figure 4 shows the field germination of grain sorghum seeds depending on meteorological conditions according to the weather station of the Volgograd State Agricultural Academy for 1993-1995. The data are given taking into account the timing of the method of sowing.

 In the table. Figures 5 and 6 show experimental data on the weediness of crops of grain sorghum varieties Volgogradskoe 20 and Skorospeloe 98 for the period of research from 1993 to 1995. in two sowing species (wide-row and ordinary).

 In the table. Figures 7 and 8 show the productivity of two varieties of grain sorghum depending on the sowing dates, the layout of seeds and varieties when cultivated according to the basic technology (control).

 In the table. 9 and 10 show the productivity of the same varieties of grain sorghum when cultivated according to the claimed method for three goals and the average value for 1993-1995.

 In the table. 11 and 12 present a bioenergy assessment of sorghum cultivation under conditions of dry irrigation, depending on the density of plant standing at different sowing dates.

 The data presented confirm the effectiveness of the claimed method of sowing grain sorghum in dry conditions.

 The effectiveness of cultivation is also proved by a significant reduction in weediness of grain sorghum crops on ordinary and wide-row crops. In FIG. Figure 7 graphically shows the increase in air temperature from the time of emergence of shoots of cold-resistant weeds to the appearance of 3-5 leaves of sorghum at 1 sowing season and 2-3 leaves at 2 sowing periods. In FIG. 8 graphs show the number of late heat-loving weeds. In FIG. Figures 8 and 9 show the effectiveness of weed control mechanically and combined - a combination of a mechanical method with a chemical method with local application of a herbicide with a small dose per unit area.

Example 2. Consider the features of the technology of cultivation of grain sorghum on irrigated light chestnut soils. Sorghum sowing, depending on the presence of moisture in the sowing layer, is carried out to a depth of 2-4 to 6 cm. With significant drying of the sowing layer, it is recommended to carry out pre-sowing irrigation at a rate of 120-300 m ³ / ha. The desired sowing depth of sorghum seeds is achieved by leveling the top soil layer and rolling the surface of the sown field. Early weeds are destroyed by mechanical presowing cultivation of the soil. Sowing is carried out in two ways: ordinary with a row spacing of 15 cm and dashed wide-row with a row spacing of 70 cm. The application of herbicides with sowing minimizes the number of late weeds in the protection zones.

To obtain a programmed crop of grain sorghum with a planned yield of 5, 7, 8, and 9 t / ha, it is required to apply the appropriate doses of mineral fertilizers and maintain the necessary irrigation regimes during the growing season (see Table 13). The pre-irrigation moisture threshold of the active soil layer of 0-70 cm should be maintained at least 70 and 80% HB. Pre-sowing irrigation during the drying of the upper soil layer contributes to obtaining stable seedlings. For grain sorghum, 3-4 irrigation with norms of 500-700 m ³ / ha is required. The first watering is carried out in the phase of 4-6 leaves, the second - in the tubovniya phase, the third - during the sweeping period and the fourth - during the grain filling period. According to calendar terms, watering usually begins in the second half of June and ends in early August.

The combination of fine irrigation and drip irrigation provides a decrease in irrigation rates to 250-350 m ³ / ha and maintains the water regime of the soil in a given interval. This contributes to the accelerated formation of secondary roots, the intensive growth of the vegetative mass and the guaranteed yield during droughts and dry winds.

 With a decrease in grain moisture up to 20 ... 22%, plants are desiccated by regulon with a dose of 3 ... 4 l / ha. The consumption rate of the solution is 500 ... 600 l / ha. On ordinary crops of grain sorghum, desiccation is carried out by an installation for fine irrigation. For this purpose, two-console sprinkler units of the DDA-100MA type are equipped with spray guns similar to those used for finely dispersed sprinkling. The same is done with front and circular multi-support sprinklers (DMF Fregat, DM Kuban-LK, DMEF Kuban and others. After desiccation, grain sorghum is harvested after 5 ... 7 days with combine harvesters with adjustments to the beater threshing apparatus and wind screening.With wide-row crops for desiccation, wide-grip boom sprayers can also be used.

 The productivity of grain sorghum of the Skorospeloye 98 variety under irrigation conditions is shown on the example of various doses of applied mineral fertilizers under irrigation regimes of 70-80-70% HB to the depth of soil soil moistening of 0.7; 0.4; 0.4 and 0.7 m (see table. 14). The effectiveness of the claimed method is confirmed not only when cultivating zoned sorghum varieties, but also others (see table. 15). In Fig. II and 12 shows the effectiveness of weed control on crops of grain sorghum under irrigation conditions according to the claimed method and existing technology. In the table. 16 and 17 show the technological operations of growing Sorghum grain sorghum 98 with yields of 4 t / ha in non-irrigated and 8 t / ha in irrigated fields.

 Thus, the above information indicates the fulfillment of the following conditions when using the claimed invention: the claimed method and the sowing unit for its implementation are intended for use in agriculture when sowing primarily grain sorghum, while the seeder (unit) can also be used for conventional sowing of a number other heat-loving crops; the possibility of carrying out the invention is achieved using known methods and means. The proposed method of sowing is highly effective at all stages of the life cycle of plants, from seed germination to harvesting, has a beneficial effect on the soil. The technical result of the proposed sowing unit for implementing the method is achieved with a simple design and is characterized by wide possibilities.

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

Claims (7)

 1. The method of cultivation of grain sorghum on light chestnut soils, including the tape application of herbicides on the cut surface under pressure and sowing seeds, characterized in that, with an offset from the axis of the bed of seeds, grooves with vertical and inclined walls are formed, with inclined walls facing into side of the seed bed, compacted, herbicides are applied to the vertical loose walls, and the grooves are covered with loose soil until the formation of the seed bed.  2. The method according to claim 1, characterized in that the vertical and inclined walls are formed in the protective zones with an offset from the seed bed at a distance of 1/4 - 3/8 of the width of the protective zone.  3. A sowing unit, including a tractor with a mounted seeder containing a frame, a hitch bracket, support wheels, markers, sowing sections, herbicide tanks, a drive pump, a rod, flexible pipelines and sprayers, characterized in that each sowing section is equipped with a craft device grooves with vertical and inclined sealed walls in the form of a rack with an axis installed in it with the possibility of rotation with opposed mounted disks with conical flanges on planes facing each other, while the disks on B interconnected offset mechanisms.  4. The assembly according to claim 3, characterized in that the displacement mechanism of each disk of the device for making grooves is made in the form of a threaded foot placed on the threaded part of the axis of the device, while the disk is mounted on the outer part of the threaded foot and fixed on it.  5. The assembly according to claim 3, characterized in that the conical flanges on the disks are installed with the possibility of dismantling.  6. The unit according to claim 3, characterized in that the rack of the device is mounted on the bracket of the seed section.  7. The unit according to claim 3, characterized in that the device for making grooves is placed in front of the groove cutter, and the herbicide sprayers are installed between the disks with conical flanges and a groove cutter

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