RU2040867C1 - Soil slitter - Google Patents

Abstract

FIELD: agricultural engineering. SUBSTANCE: soil slitter comprises a shank of two sideplates with cutting edges. The shank has chamfers on both sides of the sideplates and grooves with deposited material whose wear-resistance is higher than that of the material of said shank. Each groove on the sideplate has the form of an angular recess on the opposite side from the chamfer and is disposed on a line congruent with the cutting edges. Sideplates are offset from one another by the width of the groove and interconnected with one another by their mirror-image sides. A chisel on the lower portion of the shank has the form of a rod fixed in an inclined hole inside the shank. The middle portion of the shank is convex in the form of two mating curvilinear surfaces of sideplates forming a through hole whose front and back sections are provided with inlet support ring and outlet ring. Both rings have removable members. The removable member of the inlet support ring may have the form of a cylindrical cutter or of the head portion of a drainer. The removable member of the outlet ring has the form of a drainer bottom. EFFECT: improved design. 12 cl, 14 dwg, 3 tbl

Description

 The invention relates to agricultural machinery, in particular to working bodies for cutting in the soil anti-erosion cracks, molehills and aeration channels.

 A well-known ripper containing a rack mounted on the frame with a chisel and placed at an acute angle to it and one to another additional racks with chisels, in which, in order to reduce the energy consumption of loosening the soil, the front edge of each rack is installed at an acute angle to the horizontal plane, and additional the racks are fixed on the back side of the bit of the main rack and their front edges are offset from the nose of the bit of the main rack in the direction opposite to the direction of movement, while the axis of symmetry of each supplement The flax bit is placed in the same plane with the longitudinal axis of the additional stand.

 The described working body is acceptable only for loosening soils with a small amount of plant and crop residues on the field surface. When loosening perennial crops of grasses and pastures on the main and additional racks at the junction with chisels, plant residues hang. This leads to complete clogging of the working body and instead of the ripper, a channel digger is obtained. Hanging root and plant residues on its three racks sharply increase its traction resistance. Hanging residues together with the soil lead to the expulsion from the soil of the entire working body. The presented working body is not suitable for making cracks in crops of perennial grasses and other perennial crops before irrigation to increase water permeability in the root layer of plants due to the complete destruction of the vegetation cover.

 Known rack tilling the working body, containing a set of elastic plates of rectangular cross section, the attachment of the plates to the frame of the tillage implement and the site of strengthening of the plates to the cutting elements of the working body, in which to reduce traction resistance and increase the stability of the working body along the depth of processing, the site of attachment of the plates to the cutting elements are shifted back along the direction of movement relative to the attachment site of the plates to the frame, while the plates are installed with a gap relative to the longitudinal plane with mmetrov working body.

 The V-shaped form of the working body stand in a longitudinally vertical plane promotes the movement of plant and root residues down on the upper inclined section of the stand and this ensures its self-cleaning from plant stems. The execution of the rack in the form of two parallel plates contributes when meeting with obstacles deflect lancet paw left or right. When the paws move from the loose processing zone to the over-compacted area under the influence of the occipital chamfers of the blades of the working body, a picking force arises (reaction on the chamfers). This leads to an individual deepening of the working bodies with a constant position of the frame of the gun and other lancet paws or chisels. Vertical movement of the paw up leads to the fact that the gap between the parallel soil plates increases, assuming a barrel-shaped shape in the middle of the rack. The latter, when making cracks in the crops of perennial plants, leads to soil deformation along with the roots of the plants, which causes their death. With further movement of the working body to a looser zone, clods of soil stuck between the plates of the rack do not allow it to penetrate to the original depth. A repeated meeting of the paw with a hard area leads to a greater deepening of the working body. In the presence of a plant background, this will lead to pruning of the plant roots. The described working body is not acceptable for making drains to remove excess water. The vertical movement of the paw on the rack, the barrel-shaped form of the rack when the paw is deepened and its torsion to the left and to the right leads to the formation of “torn” walls of the gap, which leads to complete collapse and siltation when watering them.

There is also a working body for soil sowing, in which, in order to reduce traction resistance, the curved-concave cutting edge of the knife is made in the form of a parabola with the center of its branch at the middle of the rack height, while the angle of knife sharpening in the upper and lower parts of the parabola decreases to its center branches. The value of the knife sharpening angle decreases from 40 to 18 ^about .

 The presented working body is acceptable for cutting cracks in crops of grasses, grain and row crops. Curved-concave cutting edge contributes to the cutting of a vertical gap without deformation of the soil. In this case, there is no violation of the root system of plants. The sharp edge on the bottom of the rack as the working body wears out quickly. The dull edge of the bottom of the rack leads to a deepening of the working body. Uneven depth of the gap leads to uneven wetting of the root layer of the soil, which ultimately leads to a decrease in crop yields.

 Known working body for soil sowing, containing a vertically mounted knife, on the side surfaces of which there are ribs for sealing the walls of the slit, in which to increase the uniformity of the compaction of the walls of the slit along its height due to the execution of moles in the walls, the ribs are made in the form of semi-cones, the apex of which is placed on the blade of the knife, while the half-cones located on one surface of the knife are shifted in height relative to the half-cones, greater than the distance between adjacent half-cones.

 In the described working body, the rack blade is inclined at an obtuse angle to the direction of movement of the slot machine. This leads to the fact that the root and plant residues hang on the rack of the working body. Fine-tuning of molehills along the height of the slit will undoubtedly increase the volume of the slit and thereby increase the wetting zone of the arable and subsurface horizons. Molehills are made by semi-cones, which are placed in tiers on the side faces of the rack. The sharp edge of the base of the half-cone leads to the formation of a "torn" wall of the drain. The relaxation of the soil layer and soil in the walls of molehills when irrigation water is supplied leads to peeling of soil particles. The silt clogs the volume of the gap and is half-drained. The quality of crafts of drains and gaps depends on the condition of the cutting edge on the rack blade and on the degree of sharpness of its toe on the lower base. Wear of the cutting edge under the influence of abrasive particles and a sock leads to an unstable course of the working body and, as a result, to a violation of the technological process of making drains.

 There is also a known working element of the slotter, containing a rack with a curved-concave cutting edge of the knife and a bit on the lower section of the rack, which is made in the form of a round rod mounted obliquely in the hole made on the lower section of the rack, and a latch of its position in which, in order to increase the life of the bit, on the surface of the bit are made recesses deposited with hard alloy, located along the entire length of its working surface and evenly around the perimeter. The recesses on the rod are placed along the working surface forming it. The recesses on the rod are placed along the helical lines of the multi-thread screw.

 The bit on the bottom of the rack provides the deepening ability of the rack working element of the slot machine. A curvilinear cutting edge provides cutting of a vertical slit with a width of 20 mm and a depth of up to 60 cm. The presence of plant and root residues on the field surface only contributes to the creation of a stable gap by reinforcing its walls. However, the two-sided blade is subject to wear, which limits the quality of the process. The resulting vertical gap does not violate the root system of plants. However, to increase the amount of absorbed water, it is necessary to increase the number of slots on an area of 1 ha (i.e., reduce the distance between neighboring slots from 1.4 to 0 8.0.9 m), which leads to high energy consumption.

 Known slitherer containing a rack with a cutting edge, on both sides of which on the rack there are chamfers and a groove with a deposited material having greater wear resistance than the material of this rack, and a bit on the lower section of the rack, made in the form of a rod and fixed in an inclined hole inside the rack in which, in order to increase durability, the stand is made of two sidewalls, each groove made in the form of an angular recess on the opposite side of the chamfer and placed along a congruent line with a cutting edge, while the sidewalls are offset relative to each other by the width of the grooves and are connected between the mirror sides. This working organ of the slot machine is taken as a prototype.

 In this slider, all the previously described disadvantages are eliminated. An increase in the amount of absorbed irrigation water when cutting gaps with this working body can be achieved by increasing the depth of the slotting and by decreasing the step between the gaps. In the first and second cases, this leads to increased energy consumption. The presented working body is not acceptable when making drains to drain excess water, as well as soil aeration.

 The claimed working body relates to agriculture and is intended for soil cleavage when making anti-erosion cracks before irrigation of perennial crops of grasses, pastures, estuaries in order to increase water permeability of the soil and exclude surface runoff of irrigation water. When replacing a removable ring knife and staging the head of the drainer with the same working body, drainage is carried out, thereby ensuring the removal of excess water from irrigated areas. For aeration of irrigated massifs with a poor oxygen content in the soil, the rack is equipped with two flat knives in the middle part. This also contributes to both the accelerated removal of excess water and the saturation of the soil with oxygen from the air. The stand of the working body can be made by stamping. A removable ring knife and parts of the trainer can be made by machining low-quality steels of the corresponding rolled product. The set of parts shown is a multifunctional working body for tillage in irrigated agriculture.

 The middle part of the rack of the working body is convex in the form of two mating curvilinearly concave external surfaces of the sidewalls, forming a cylindrical hole, with an axis coinciding with the direction of movement of the working body. The front and back sections of the hole in the middle of the rack are equipped with input support and output rings. The input support ring is equipped with a removable cylindrical knife or the head part of the trainer, made in the form of a truncated curved cone. The cutting edge of the head of the trainer is located in the alignment of the cutting edge of the rack. The output ring of the rack is equipped with a bottom of the trainer. The hollow part of the removable cylindrical knife, the support ring, the holes of the middle part of the sidewalls of the rack, the output ring and the bottom of the drain are made expanding in the direction from the input removable cylindrical knife to the bottom of the drain. The outer surfaces of the rack sides are concave-curved. A removable element in the form of a cylindrical knife on its front part is provided with a cutting edge formed by a blade on the inner surface, and its outer part from the side of the cutting edge is provided with an angular recess filled with wear-resistant material. The truncated parts of the removable element of the head part of the trainer are provided with rectangular grooves with wear-resistant material deposited into them. The head of the trainer and its bottom are hollow. The outer surface of the bottom of the trainer is either cylindrical, or spherical, or curved with its surface forming as part of a logarithmic curve. The rear of the rack is equipped with two horizontal flat blades of parts of the left and right sidewalls, mating with the surface of the bottom of the drainer. Paws on the front part are made with blades and cutting edges.

 In FIG. 1 shows a working body for soil cleavage, left view; in FIG. 2 same front view; in FIG. 3 the same, right view; in FIG. 4, section AA in FIG. 1, a diametrical section of a rack hole in the embodiment of a removable ring knife with a blade placed on the inner wall; in FIG. 5 the same, the diametrical section of the rack hole in the embodiment of the removable ring knife with the blade on the outer surface; in FIG. 6 section BB in FIG. 1; in FIG. 7 working body for soil cleavage in the version of the craft of drains to drain excess water, left view; in FIG. 8 same front view; in FIG. 9 same, right view; in FIG. 10 section BB in FIG. 7, a diametrical section of the head of the trainer on the support ring of the rack; in FIG. 11 the same, the diametrical section of the bottom of the drain on the output ring of the rack with a curved surface of the bottom; in FIG. 12 working body for soil cracking in the variant of soil aeration, right view; in FIG. 13 the same front view; in FIG. 14 is a view along arrow D in FIG. thirteen.

The working body for soil slitting consists of a stand 1 with a cutting edge 2, a bit 3 on the bottom of the stand 1, made in the form of a rod with pre-installed recesses 4, deposited with hard alloy 5. The bit 3 is placed in an inclined hole 6 in the lower part of the stand 1. The longitudinal axis of the hole 6 is inclined to the horizontal at an angle of ^about 5.6 sufficient to form an adjustable angle 7 between the toe post 1. The front part of the bit 3 is made flat face with an apex angle ^of 21 ± 3. The diameter of the hole 6 in the rack 1 exceeds the diameter of the rod 3 by 1.2 mm. The gap between the walls of the hole 6 is sufficient for the free placement of the bit 3. It provides convenience when moving the partially worn bit 3 in the direction of the toe 7 of the rack 1 or when removing the completely worn bit 3. The latter in the hole 6 is fixed by cylindrical pins 8 in the holes 9 of the rack 1. The pins 8 are used to perceive the axial load of the bit core 3. On the surface of the bit core 3, cylindrical grooves are made with a jig with a pitch equal to the pitch between the holes 9 on the lateral face of the Menus 1.

 In the upper part of the rack 1, holes 10 are made for fastening the working body on the frame of the gun (cherese). Brackets 11 are mounted on the left side of the rack 1 with welds for mounting and dismounting the working body from the beams of the implement frame using lifting equipment. Stand 1 is made of left 12 and right 13 sidewalls. The outer edges of the sidewalls 12 and 13 are provided with chamfers 14 and 15. Each sidewall 12 (13) is provided with a groove 16 in the form of an angular recess on the opposite side of the chamfer 15. The grooves 16 on the sides of the sidewalls 12 and 13 are made along the congruent line of the cutting edge 2. Cutting edge 2 of the left sidewall 12 is shifted forward by the width of the groove 16 with respect to the cutting edge 2 of the right sidewall 13. The sidewalls 12 and 13 are mutually joined by butt welds 17 and T-joints 18 in the annular technological holes 19 of the left sidewall 12. The outer sides are yn 12 and 13 are concavely curved with thickenings 20 on the perimeter (see. FIG. 6). This allows you to significantly reduce the friction surface of the sidewalls 12 and 13 of the rack 1 with the walls of the cut cracks.

 The middle part of the sidewalls 12 and 13 of the rack 1 from the side of their flat surfaces by stamping is made in the form of a cylindrical surface. The flat mirror surfaces of the sidewalls 12 and 13 after stamping with welds are connected into an integral unit. After connecting the sidewalls 12 and 13 in the middle of the rack 1, a cylindrical hole 21 is formed (see Fig. 1). The front part of the cylindrical hole 21 is provided with a support ring 22, which is connected by a closed weld seam 23 with bulges 20 on the front of the sidewalls 12 and 13 (see Fig. 4 and 5). An output ring 25 is connected by a welded seam 24 on the back side from the bulges 20 of the sidewalls 12 and 13. The inner surface of the support ring 22 is threaded 26 for connecting a removable cylindrical knife 27. The knife 27 is provided with a cutting edge 28 on its front part. The inner part of the removable cylindrical knife 27 is provided with a blade 29. On the outer surface 30 of the cylindrical knife 27 from the side of the cutting edge 28, an angular recess 31 is made, which is deposited with hard wear-resistant material 32. On the outer surface 30 of the cylindrical knife 2 7 from the side of the cutting edge 28 are made with equal pitch blind blind cylindrical holes 33 for screwing and screwing the knife 27 on the support ring 22.

 The output ring 25 on its inner surface has a threaded portion 34 into which a cylindrical threaded ring 35 is screwed. The rear part of the cylindrical threaded ring 25 is provided with slots 36 for dismounting or screwing into the output ring 25.

 The cylindrical hole 21 of the middle part of the strut 1, the cylindrical inner surface 37 of the removable cylindrical knife 27 with an offset by the size of the blade 29, the cylindrical inner surfaces of the support ring 22, the output ring 25 and the cylindrical threaded ring 35 are made conical after their complete assembly (see Fig. 4). In the described construction, a cutting edge 28 is formed in the soil of the drain, the dimensions of which remain unchanged as the rack 1 passes with a threaded ring 35 on its back.

 The outer part of the removable cylindrical knife 27, made according to the second embodiment (see Fig. 5), is equipped with a blade 29. On the inner surface 30 of the cylindrical knife 27 from the side of the cutting edge 28, an angular recess 31 is made, which is fused with hard wear-resistant material 32. A removable cylindrical knife 27 closer to the threaded part 26 is provided with two through diameter holes 33 for the screwdriver for screwing and screwing the knife 27 onto the support ring 22.

 The output ring 25 on its outer surface has a threaded portion 34 on which the bottom of the drain 38 is screwed. The back of the bottom of the drainer 38 is provided with rectangular grooves 36 for dismounting or screwing onto the output ring 25. The outer surface of the bottom of the drainer 35 is made spherical. The diameter of the sphere of the bottom of the drainer 38 is made larger than the diameter of the removable cylindrical knife 27. The cylindrical hole 21 of the middle part of the rack 1, the cylindrical surface 30 of the removable cylindrical knife 27 and the cylindrical inner surfaces of the support ring 22, the output ring 25 and the bottom 38 of the drainer, after their complete joint assembly, are bored on the cone (see Fig. 5). In the described design of the rack 1 of the working body for snapping, the soil layer cut by the cutting edge 28 remains in an undeformed natural state. At the same time, the walls of the drains are compacted in two stages. The blade 29 of the removable knife 27 performs the right phase of compaction of the walls, and on the plot of the concave cryo-linear part of the sidewalls 12 and 13, the soil is relaxed. After that, the spherical surface of the bottom 38 of the drains finally form the wall of the drain.

 In FIG. 7-11 show the working body for soil cleavage in the version of the craft of drains to drain excess water. For this, the head part of the drainer 39 is screwed into the support ring 22, which is made in the form of a truncated part of a curved cone by two planes located at an acute angle to the axis of the drainer 39. The intersection of the cutting planes 40 and 41 form the cutting edge 42 of the head of the trainer 39. On the planes 40 and 41 with offset relative to each other on opposite planes, rectangular holes 43 are made of a width of 5.8 mm and a depth of 1.5 mm, which are welded with a wear-resistant material. The head part of the trainer 39 can be made in the form of a paraboloid of rotation, facing the apex in the direction of movement of the working body strut. The cutting edge 42 is placed in alignment with the cutting edges of the blades 14 and 15 of the sidewalls 12 and 13. On the output ring 25, the bottom 38 of the drains 39 is mounted on the drain ring. The diametrical hole 44 in the bottom 38 of the drains is intended for screwing onto the threaded part 34 of the output ring 25. FIG. 11 shows an embodiment of the surface of the bottom 38 of the drainer 39 in the form of a part of a logarithmic spiral, most suitable for the form of relaxation of the material after repeated compression of the soil with a drainer or punch. The head of the drainer 39 and its bottom 38 are hollow.

 In FIG. 12 and 13 show a working body for snapping in a variant of soil aeration. For this, the sidewalls 12 and 13 of the rack 1 are provided with a left 45 and right 46 paws made of parts of the sides 12 and 13. The left paw 45 is made in mirror image of the right paw 46. The left 45 and right 46 paws are equipped with blades 47 and 48 with cutting edges 49 and 50. The horizontal flange of the paw 45, likewise the flange of the paw 46, goes into the vertical strut 1 along the congruent surface of the threaded ring 35. In the transition zone of the paws 45 and 46 from the surface of the ring 35, their cutting edges 49 and 50 are located behind the output ring 25. On horizontal sections of the left paw 45 and the right paw 46 of the blade 47 48 drenera inclined to the axis 39 (see. Fig. 14). This makes it possible, when making cracks, to maximize the surface for collection and speed up the process of excess water flowing through horizontal channels into drains and for aeration of the soil. The quality of the described technological operations is carried out under the condition of a sharp cutting edge 51 of the bit 3.

 The working body works as follows.

 When the rack 1 interacts with the soil, the curved-concave cutting edge 2 of the sidewall 12 ensures that the plant residues in the upper part of the rack 1 jam between the cutting edge 2 and the soil and cut them (see Fig. 1-6). In the absence of cutting conditions, the plant residues are carried deep into the gap, are compressed between its walls and cut in the middle of the rack 1, where the knife sharpening angle is the smallest. Shredded plant residues reinforce the walls of the gap. When interacting with the soil, bit 3 cuts a layer of soil. The lower edge 7 of the rack 1 with the cutting edge 2 cuts the remaining soil layer, forming the side walls of the gap and compacting its surface with loose soil coming from the bit 3. As a result of compaction of the walls of the gap with plant residues and soil, their shedding and siltation are reduced. As the operating time increases, bit 3, which works under the most difficult conditions of the soil, wears out intensively. The base metal of the nose of the core of the bit 3 wears out faster, exposing the areas deposited with hard alloy 5 in the prepared recesses 4. The cutting edge 51 on the blade of the bit 3 takes a crescent shape for the version with recesses made parallel to its longitudinal axis, or the shape of a drill in a spiral of a multi-thread screw, which improves self-sharpening of the blade 51 bits 3.

 During operation, for example, when cutting water-absorbing slots in crops of perennial grasses, stand 1 with its cutting edge 2 in the upper part cuts plant residues on the field surface: roots in the arable horizon, and together with chisel 3 in the lower part of stand 1, continental soil. As work progresses, the blade 14 of the left sidewall 12 wears out faster than the filler in the corner recess 16, exposing the cutting edge 2. When the operating time is reached within 180-210 ha in the corner recess 16, the filler is completely abraded. With an additional operating time of 8-12 ha, the blade 14 on the sidewall 12 wears out equally and exposes the filler tip in the groove 16 of the sidewall 13, forming a new cutting edge along the entire height of the strut 1. When the blade 15 is completely worn and the filler of the cutting edge 2 is chipped, a fillet is formed on sidewalls 12 and 13. With a fillet size of 3-5 mm, rack 1 is discarded, reaching an operating time of 500-530 ha.

 To ensure greater water permeability of water to the arable and subsurface horizons, the rack 1 is deepened to a depth greater than the arable horizon and so that the axis of the removable ring knife 27 should be at a depth of 40.45 cm with a diameter of at least 160.180 mm. In this case, the cutting edge 28 of the removable ring knife 27 when it moves cuts off the roots of plants in its path. The cut soil cylinder with the annular cutting edge 28 is guided by the blade 29 into the hole 37 of the removable knife 27. The holes made on the cone 37, the support ring 22, the holes 21 of the rack 1, the output ring 25 and the inner hole 35 do not interfere with the movement of the soil cylinder. The soil cylinder smoothly fits on the surface of the drain, which is obtained by simultaneously cutting the upper and lower parts of the gap. When cutting the soil and soil with the cutting edge 28 of the removable ring knife 27, the outer cylindrical surface 30 (see Fig. 4) seals the wall of the drain. On concave sections of the sidewalls 12 and 13, soil relaxation occurs. The second phase of the seal of the wall of the drain begins with thickenings 20 on the back edge of the sidewalls 12 and 13, and then ends with the outer surface of the bottom of the drainer 35. An embodiment of the removable knife 27 with the inner blade 29 shown in FIG. 4, it is preferable to use on hard and re-compacted soils. With a significant operating time of the working body due to the difference in hardness of the material of the blade 29 and the wear-resistant material 32 in the annular angular groove 31, intensive wear of the inner surface of the hole 37 of the removable annular knife 27 occurs. At the same time, the sting of the bevel of the wear-resistant material 32 in the groove 31 is exposed, thereby uninterrupted operation of the knife 27. When the chamfer on the front of the removable knife 27 with a fillet size of more than 5 mm is reached, the knife 27 is removed from the support ring 22 and replaced with a new or restored .

 When making anti-erosion cracks in grass crops of the first or second year of growth, it is preferable to use a removable cylindrical knife 27, shown in FIG. 5. The cutting edge 28, as in the first case, cuts off the soil cylinder, which moves freely in the hollow conical surface of the holes 21 of the rack 1 and fits into the drain between the upper and lower parts of the gap. Blade 29 intensely compacts the wall of the drain. The deformation of the wall of the drain is equal to the wall of the annular knife 27. After preliminary deformation, the convex part of the walls of the sides 12 and 13 of the hole 21 undergoes soil relaxation on the cylindrical surface of the drain.

 During irrigation with sprinkling machines with a flat surface and on slight deviations, excess water from the surface of the field slides into the drain along the walls of the gap. From the side surface of the drain, water flows into the lower part of the gap. As the lower part of the gap fills, irrigation water fills the volume of the drain and the cavity of the upper part of the slit. Since the degree of compaction of the walls of the gap and the walls of the drain is higher than the density of the soil cylinder, the soil swells from the irrigation water and fills the cavity of the drain. Water at the bottom of the gap remains in the locked reservoir. As the soil swells, the size of the slit in its upper part decreases, thereby reducing the intense evaporation of water from the slit. Drain in the middle part of the gap increases the volume of accumulated water and thereby minimizes water erosion of the soil. The moisture reserve in the lower part of the gap and in the middle part of the drainage leads to an increase in the wide zone of the soil monolith in the root-inhabited horizon. Faking a narrow gap without disturbing the soil structure in the arable layer does not damage the roots of fodder crops, which contributes to the fast regrowth of the aftermath and obtaining stable yields of the earth’s mass of grasses.

 The implementation of the rack 1 of the working body of the slot machine with curved-concave walls of the sidewalls 12 and 13 can significantly reduce the friction surface and thereby reduce the overall traction resistance of the gun. The sharp cutting edges 2 of the rack 1, the annular cutting edge 28 of the removable cylindrical knife 27 and the cutting edge 51 of the bit 3 provide cutting of root and plant residues, the soil layer in the arable horizon and the soil below the plow sole. This ensures the steady execution of the process when making erosion control cracks.

 To drain excess water (see Fig. 7-11) on the stand 1 of the working element of the slotter, a removable cylindrical knife 27 is removed from the threaded portion 26 of the support ring 22. The head of the drainer 39 is screwed into place of the cylindrical knife 27. The cutting edge 42 of the drainer 39 is installed in a solution with a cutting edge 2 racks 1. On the output ring 25 with a special screw that is inserted into the hole 44, screw the bottom 38 of the drainer with a spherical or curved surface. When moving the tool, the cutting edge 42 of the head of the trainer 39 cuts the soil. The curved surface of the drainer 39 and its lateral faces 40 and 41, the soil or ground is shifted to the side, forming a circular opening. The walls of this hole are sealed by the middle part of the head part of the drainer 39 and the outer cylindrical surface of the support ring 22. When moving the rack 1, the cutting edge 2 of the blade 14 cuts the root parts of the plants and the soil layer at the height of the rack 1. The blade 15 shifts the right part of the soil to the right and compacts the walls above and below the drain. With the further passage of the rack 1 by curved-concave sections of the sidewalls 12 and 13, relaxation (partial restoration of the soil within the size of the gap) of the soil and narrowing of the gap occur. The curved or spherical surface of the bottom 38 is densification of the wall of the drain. When making a drain, excess water is directed along the vertical slit and drain into the drainage ditches. Sludge particles in the discharged water fill the lower part of the gap as they precipitate. Drain in this case unhindered conducts water into drainage (waste) channels. As the gap fills with soil particles, soil impurities accumulate (sediment) on the bottom of the drain. Double sealing of the drainage wall contributes to its stability against wall collapse. These measures ensure the efficiency of water drainage on irrigated areas with a high occurrence of groundwater.

 To increase the fertility and efficient use of irrigated lands, it is important to carry out agrotechnical methods of soil aeration. Technological experiments have established that during aeration of the soil in the root-inhabited layer, the yield of fodder crops can increase up to 50% compared with the control crop. In FIG. 12-14 shows the working organ of the slot machine, which, in addition to the removable elements considered, is equipped with two horizontal paws 45 and 46. The paws 45 and 46, placed behind the rack 1, smoothly pass from the surface of the bottom 35 of the drains 39 to the sides 12 and 13. As in previously considered cases, the cutting edge 2 of the blades 14 and 15 cuts a vertical gap. The head of the trainer 39 with a cutting edge 42 cuts a vertical gap and then forms a cylindrical wall of the drain. Hardening of the wall of the drain occurs by the bottom of the 35 drainer. The cutting edges 49 and 50 of the blades 47 and 48 of the left paw 45 and the right paw 46 cut horizontal channels for both water drainage and oxygen access from the atmosphere in the root layer of plants. The deflected blades 47 and 48 of the legs 45 and 46 facilitate the removal of uncut root residues from the cutting edges 49 and 50.

 The described working body with removable elements allows for the cultivation of anti-erosion water-absorbing cracks, drains for removal of excess water with close occurrence of ground water and soil aeration, at any stage of plant organogenesis, without disturbing the vegetation cover on fields occupied by agricultural crops. Tables 1-3 show the experimental data on soil erosion for the geomorphological zones of the Lower Volga region after each irrigation with the Frigate, Volzhanka and DDA-100MA sprinkler machines without siping (control), with anti-erosion cracks made with the SchN 2-140 serial slicker and with experimental working bodies of the sample of 1991 and 1992 on the frame ЩН 2-140. Aggregate mounted scribers were aggregated with the DT-75 M tractors. The depth of the slit crafts was set to 45 cm in the first case and 0.6 m in the second. The distance between the slots, respectively, was 1.45 m (ЩН 2-140) and 2.1 m in experimental slitherese.

Claims (12)

 1. A WORKING BODY FOR GRAVING SOIL, comprising a rack of two sidewalls with cutting edges, chamfers and grooves with deposited material having greater wear resistance than the material of the rack are made on both sides of the sidewalls, each groove is made in the form of an angular recess on the opposite facets from the chamfer and placed along a contour line with a cutting edge, while the sidewalls are offset relative to each other by the width of the groove and are interconnected by mirror sides, and the bit on the bottom of the rack, nano in the form of a rod and fixed in an inclined hole inside the rack, characterized in that the outer surface of each sidewall is made concave-curved with a thickening along the edge and concavity in the middle part, and the mating is flat, and the middle convex part of the sidewall when mating with flat surfaces forms a through hole with a horizontal axis, the front and rear sections of which are equipped with an input support and output rings with removable elements, while the inner surface of the convex part of the mating x the surface of the sidewalls is made expanding in the direction from the input support ring to the output ring, and the outer surface of the bulge in the middle of the rack with a narrowing between the input support and output rings.  2. The working body according to claim 1, characterized in that the removable element on the input support ring is made in the form of a cylindrical knife with a cutting edge on the front part and a blade on the inner surface, and the outer surface of the knife on the side of the cutting edge is provided with a recess filled with wear-resistant material .  3. The working body according to claim 1, characterized in that the removable element on the input support ring is made in the form of a cylindrical knife with a cutting edge on the front part and a blade on the outer surface, and the inner surface of the knife on the side of the cutting edge is provided with a recess filled with wear-resistant material .  4. The working body according to claim 1, characterized in that the removable element on the input support ring is made in the form of the head of the trainer with a curved surface and a cutting edge formed by two secant planes of the curved surface of the trainer, the planes being inclined at an acute angle to the axis of the trainer.  5. The working body according to claims 1 and 4, characterized in that the cutting edge of the head of the trainer is located in alignment with the cutting edge of the rack.  6. The working body for PP. 1 and 4, characterized in that the truncated planes of the head of the trainer are provided with rectangular grooves offset relative to each other on opposite planes and deposited with wear-resistant material.  7. The working body according to p. 1, characterized in that the removable element at the output end is made in the form of the bottom of the trainer.  8. The working body according to paragraphs. 1 and 7, characterized in that the outer surface of the bottom of the trainer is made cylindrical.  9. The working body for PP. 1 and 7, characterized in that the outer surface of the bottom of the drainer is made spherical.  10. The working body for PP. 1 and 7, characterized in that the outer surface of the bottom of the drainer is made curved.  11. The working body for PP. 1, 4 and 7, characterized in that the head of the trainer and its bottom are hollow.  12. The working body according to claim 1, characterized in that the rear of the rack is equipped with two horizontal flat paws of the parts of the left and right sides, mating with the surface of the bottom of the drainer, and the paws on the front part are made with blades and cutting edges.

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