RU2056083C1 - Method and device for improving water-air conditions of irrigated soils - Google Patents

Abstract

FIELD: agriculture. SUBSTANCE: method involves cutting water-intercepting slits with tiered center reservoirs which latter are formed in two steps: by passive effect applied to soil to 0.25 - 0.35 of minimum section and by pulsating effect to the preset value. Device comprises working tool in the form of a shank with conical ribs, chisels on lower portion of shank, and drive shaft with discs. Conical ribs on shank sides face each other, the drive shaft is inclined behind the shank, and discs are mounted on shaft in symmetry with its rotation axle behind the conical shank ribs. EFFECT: improved functional and operating characteristics. 5 cl, 12 dwg

Description

 The invention relates to agriculture, in particular to technology and technical means for the cultivation of perennial feed crops on irrigated soils.

A known method of improving the water-air regime of the soil, according to which at the same time as cutting vertical soils in the soil (water-catching slots), several crootodrens are additionally cut into which irrigation water or drains are fed [1]
The reasons that impede the achievement of the required technical result when using the known method include insufficient cross-section of the cut crotodrens with increased resistance to movement in the soil of the working body.

Known working body for slitting the soil, containing a vertically mounted knife, on the lateral surfaces of which there are conical ribs for local expansion of the walls of the gap [2]
The reasons that impede the achievement of the required technical result when using the known device include the insufficiently high efficiency of the resulting molehole gap and the increased resistance of the working body.

The closest method and device of the same purpose to the invention is a method of soil slitting on the crops of perennial forage crops and a device for its implementation, according to which water-catching slits are cut with tiered focal reservoirs that form a pulsed action, while the working body is in the form of a vertical strut and the bit on the lower section is equipped with a drive shaft with disks for the formation of focal reservoirs [3]
The disadvantages of the prototype are the increased energy intensity of the formation of focal reservoirs due to disks with curved surfaces eccentrically mounted on the drive shaft, the limited cross-section of the focal reservoirs and the overhang of root and plant residues in the soil, since the drive shaft with discs are located in the corresponding cutouts of the rack.

 The problem to which the invention is directed, reducing energy intensity and improving the quality of the technological process of formation of cracks in the soil with focal reservoirs while expanding the cross section of the reservoirs.

 The technical result is a decrease in the resistance of the working body during the technological process, an increase in the resistance of a gap formed in the soil of a complex configuration, an increase in the effectiveness of the effect of irrigation water, livestock runoff and atmospheric air on the soil.

 The specified technical result in the implementation of the invention is achieved by the fact that in the known method, including cutting slit water-catching slots with tiered focal reservoirs with the placement of displaced soil in the sidewalls of the cracks and reservoirs and subsequent compaction of the walls, focal reservoirs are formed in two stages: passive action on the soil on the value of 0.25.0.33 from the nominal cross-section and impulse exposure to a predetermined value. In the device for implementing the method, comprising a frame, hinge brackets, support wheels and a working body for cutting slots and focal reservoirs in the form of a rack with cone-shaped ribs, bits on the lower section and the drive shaft with disks, the cone-shaped ribs on the sides of the rack are located opposite each other, the drive shaft is placed obliquely behind the rack, and the disks are mounted on the shaft symmetrically about its axis of rotation behind the conical ribs of the rack. The rack is made of two interconnected plates, while the conical ribs are formed due to the deformation of the respective plates; the rack is equipped with spaced-apart bushings and installed between pairs of frame beams.

 In FIG. 1 shows an irrigated area with irrigators and cut water-catching slits; in Fig. 2, section AA in Fig. 1, the cross-section of the slit with focal reservoirs made in the first stage (thin lines) and in the second stage (contour lines), and with soil density plots; figure 3 is the same, but after irrigation with highlighted zones of pumping slots and focal reservoirs; figure 4 tool for cutting cracks with focal reservoirs, plan; in FIG. 5 same side view; Fig.6 working body for cutting cracks and the formation of focal reservoirs, side view; Fig.7 is the same front view; in FIG. 8 same plan; Fig.9 section BB in Fig.6; figure 10 section bb in figure 6; figure 11 section GG in figure 6; in Fig.12 section DD in Fig.5.

 A method of improving the water-air regime of irrigated soils is implemented as follows.

 In the irrigated area with crops of perennial forage crops perpendicular to irrigators 1 and the direction of crops, for example, alfalfa, with the help of slottes, water-catching slots 2 are cut (Fig. 1). Slots are cut at 3 intervals; 2 and 1.4 m for alfalfa, respectively, the second, third and fourth years of growth. In the vertical alignment of each slit 2, tier reservoirs 3 symmetrically located on the sides are formed in tiers with an interval of 15.18 cm (Fig. 2). The walls 4 of the tanks 3 are formed by a second-order surface, which is performed in two stages. At the first stage, using cone-shaped ribs on the working body, a passive effect on the soil is carried out at a value of 0.25.0.33 from the nominal cross-section of the reservoir 3, preliminary reservoirs a are formed (indicated in thin lines in Fig. 2).

The formation of preliminary reservoirs is achieved mainly by increasing the density of the soil in places of its additional deformation. At the second stage, the formation of reservoirs 3 is completed to a given value; the walls of 4 reservoirs are formed due to the pulsed action on the soil with a frequency of 9.17 s ⁻¹ . A loosened portion 5 is formed in the lower part of the slit. The displaced soil is located in the sides of the slots and in the reservoirs. Ultimately, the soil is displaced due to compaction of the walls of the resulting slit of a complex configuration, where the soil density is greatest at the side ledges of the tanks 3.

 Figure 2 shows a comparative increase in soil density (the initial soil density is not taken into account), where the maximum density is shown in section 6. When irrigating the area, irrigation water or livestock runoff enters the slots 2 with focal reservoirs 3 and the lower loosened section 5. Through the walls of the slit 2, the lower section 5 and partially through the walls of 4 reservoirs 3 water or liquid effluent moistens the soil horizons. The wetting zone of the slit 2 with focal reservoirs 3 is shown by the shaded outline 7 in figure 3.

 Thus, the formation of water-catching slots with tiered focal reservoirs in two stages due to passive and pulsed effects on the soil reduces the energy consumption of this process and at the same time expands the cross section of the reservoirs and increases the durability of the resulting complex configuration gap. At the end of irrigation, water or runoff flows horizontally to the roots of agricultural plants, while the humidification circuits from sprinkler 1 are mostly closed. The presence in the cracks of focal reservoirs of increased cross section and with compacted walls also improves air exchange, intensifies the development of aerobic microflora, arranges organic residues and better assimilation of nutrients by plants, increases the duration of this process during repeated use of water-catching cracks. As a result, the water-air regime of irrigated soils improves.

 A device for improving the water-air regime of irrigated soils (Fig. 4-12) is made in the form of an agricultural implement mounted on a transport base 8, which contains a frame 9, hinge brackets 10, support wheels 11 and working bodies 12 for cutting cracks and forming focal reservoirs . The latter are made in the form of a vertically arranged rack 13 with conical ribs 14, a bit 15 on the lower portion of the rack and the drive shaft 16 with discs 17. The conical ribs 14 on the sides of the rack 13 are symmetrically opposed to each other. The stand 13 is made of two interconnected plates b and c, while the conical ribs are formed due to the deformation of the respective plates (Fig.9).

 The rack 13 is equipped with spaced apart along the length of the bushings and using the axis 19 is installed between the pairs of beams g and d belonging to the frame 9 (Fig.6, 12); An extensive cutout is provided at the top of the rack for ease. The bit 15 on the bottom of the rack is installed with the possibility of ball extension (Fig. 6). On the curved-concave frontal plane 20 of the rack due to the corresponding sharpening, surfacing and displacement of the plates b and c, a wear-resistant blade is formed (Fig.6.9). The rear side of the rack 13 has an inclination towards the bit 15. On this part of the rack at the top and bottom there are supports 21 in which a drive shaft 16 with disks 17 is installed, therefore, the drive shaft is inclined behind the rack (Fig. 5,6). The cross section of the drive shaft 16 between the supports 21 has the shape of a square, and the corresponding square holes are provided in the disks 17; the disks have the shape of a cylinder symmetrical with respect to the axis of rotation of the shaft 16. On the drive shaft between the lower support 21 and the disk 17, a support sleeve 22 is provided, between the other disks and the upper support the spacer sleeves 23 (Fig. 10). By selecting the length of the bushings 22 and 23, the disks 17 are installed on the drive shaft 16 so that the disks are located behind the conical ribs 14 of the rack 13 (Fig.6). The bearings 21 of the drive shaft include spherical rolling bearings (FIGS. 10, 11). The upper drive ends e of the drive shafts have splines (FIGS. 6, 10) by which the drive shafts are connected to the power take-off shaft of the transport base 8 by means of bevel angular gears 24 and a telescopic driveshaft 25 (FIG. 4,5). The transport base contains a hydraulic hitch with lower 26 and upper 27 rods for connection with an agricultural implement.

 A device for improving the water-air regime of irrigated soils works as follows.

During the initial assembly of the agricultural implements, the working bodies 12 are connected with the axles 19 to the pairs of beams g and d of the frame 9 using the axles 19, the bits 15 are pre-installed on the uprights 13 in the extreme rear position. Next, the tool with its brackets 10 is connected to the lower 26 and upper 27 links of the hydraulic base of the transport base 8, the telescopic driveshaft 25 is connected to the power take-off shaft of the transport base, the support wheels 11 set the specified depth of the slit. After preliminary deepening of the working bodies during movement of the transport base, the posts 13 with their wear-resistant blades on a curved concave plane 20 cut the soil formation with root and plant debris, then with the thickness of the plates c and b, and also by means of the bits 15 and conical ribs 14 on the posts 13 form in the soil water-catching slots 2 with preliminary reservoirs a and loosened section 5 in the lower part. At the same time, from the power take-off shaft of the transport base 8, by means of a telescopic driveshaft 25, bevel angular gears 24 and splines of the upper output ends e, the rotational movement is transmitted to the drive shafts 16, inclined behind the uprights 13, the latter, rotating in their supports 21, by means of a square connection transmit rotation to the disks 17 located behind the conical ribs 14 of the racks. By their impulse action on the soil with a frequency of 9.17 s ^{-1, the} disks 17 on the drive shafts 16 complete the formation of focal reservoirs 3 to a predetermined value, sealing the walls of the 4 reservoirs.

 Due to the inclined position of the drive shafts 16, with the symmetrical placement of the disks 17 relative to the axis of rotation of the shaft, a complex movement of the outer edges of the disks is achieved, as a result of which focal reservoirs are formed with a profile of the walls 4 formed by a second-order surface. Due to the formation of focal reservoirs 3 in two stages by passive action of conical ribs 14 racks on the soil by a value of 0.25.0.33 from the nominal cross section and the pulsed action of disks 17 with an inclined axis of rotation, the cross section of the reservoirs is expanded and the density of their walls 4 is increased.

 The tiered arrangement in the range of each gap of 2 focal reservoirs 3 with an interval of 15.18 cm contributes to the formation of several humidification circuits when 2 irrigation water or drains are supplied to the water-catching cracks, and in combination with an expanded cross section and increased wall density of the 4 reservoirs, increases the resistance of cracks due to the slowing down of siltation and erosion of the walls. In the inter-irrigation period, the soil will be more intensively aerated, which ultimately helps to improve the water-air regime of irrigated soils. Along with this, the formation of focal reservoirs in two stages reduces the energy intensity of the process. The presence in the agricultural implement of the bit 15 with the possibility of stepwise extension, a wear-resistant blade on the cutting curvilinearly concave frontal plane 20 of the rack 13, conical ribs 14 formed by deformation of the plates b and in the racks spaced along the length of the rack of bushings 18 installed between pairs of beams g and d frame 19, an extensive cutout in the upper part of the rack, the inclined location of the drive shaft 16 behind the rack and the symmetrical placement of the disks 17 relative to the axis of rotation of the shaft helps to reduce the metal consumption, technologist chnosti during manufacture, improving montazhesposobnosti, improve wear resistance and service life, reduce the resistance during operation.

Claims (4)

 1. A method of improving the water-air regime of irrigated soils, including cutting of water-catching slots with tiering with focal reservoirs arranged in tiers with the placement of displaced soil in the sides of the cracks and reservoirs and subsequent compaction of the walls, characterized in that the focal reservoirs are formed in two stages: passive action on the soil by 0.25 - 0.33 of the nominal cross section, and then by a pulsed action of a given value.  2. A device for improving the water-air regime of irrigated soils, containing a frame, a hinge bracket, support wheels and a working body for cutting cracks and focal reservoirs in the form of a rack with cone-shaped ribs, a bit on the bottom of the rack and the drive shaft with disks, characterized in that the conical ribs on the sides of the rack are located opposite each other, the drive shaft is inclined behind the rack, and the disks are mounted on the shaft symmetrically relative to its axis of rotation behind the conical ribs of the rack.  3. The device according to p. 2, characterized in that the rack is made of two interconnected plates, while the cone-shaped ribs are formed due to the deformation of the respective plates.  4. The device according to claim 2, characterized in that the rack is equipped with spaced apart along the length of the bushings and installed between the pairs of beams of the frame.

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