RU2110167C1 - Soil-protective tillage tool - Google Patents

Abstract

FIELD: agricultural engineering, in particular, tools for slitting soil occupied with fodder crops and for erosion-preventive tillage. SUBSTANCE: tool has frame, hitching device, slitter, disk-shaped cutter and supports. Slitter tine is made corrugated. Slitter tine section and corrugation thickness are reducing in the direction of motion of chisel mounted on lower end of tine. EFFECT: increased efficiency and simplified construction. 8 dwg

Description

 The invention relates to agricultural machinery, in particular to tools for slitting soil occupied by crops of fodder crops and anti-erosion treatment.

Known working body for soil sowing, containing a rack with a knife on the front part, in which, in order to reduce traction resistance, a 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 height of the rack, with the knife sharpening angle at the top and the lower parts of the parabola decreases to the center of its branch; the value of the angle of sharpening of the knife decreases from 40 to 18 ^o (SU, copyright certificate, 1329634, A 01 B 13/16, 1987).

The minimum allowable thickness of the knife from the conditions of the strength of the rack cannot be made less than 20 mm, even for high-strength structural materials used by modern agricultural engineering. The curved-concave cutting edge of the knife provides stable vertical cutting to a depth of 45-50 cm.However, when irrigating perennial forage crops, even with small irrigation rates of 400 m ³ / ha, the soil swells rapidly and the mouth (upper) part of the gap closes. For this reason, irrigation water at local depressions slides to areas with large slopes, while flushing the fertile layer. Due to the closure of the upper part of the slit, the uniform distribution of rain on the surface of the irrigated field becomes problematic.

где
B_i - ширина захвата i-й лапы i-го яруса;
B₀ - ширина захвата лапы одного из ярусов;
φ - угол трения почвы о металл;
θ - угол скалывания пласта;
a_i - высота рабочей части стоек i-й лапы i-го яруса;
α - угол установки лапы к дну борозды (SU, авт. св., 1817947, A 01 B 13/16, 1993).Also known is a deep-ripper containing a frame with a hinged device, a support roller and belt mounted loosening working bodies made in the upper tiers in the form of lancet paws, with a working width that decreases from the upper tier to the lower one, made in the form of a chisel, in which, in order to reduce energy intensity of the process of loosening and improving the quality of the soil, the width of each leg is determined from the ratio

Where
B _i - the width of the i-th leg of the i-th tier;
B ₀ - the width of the paws of one of the tiers;
φ is the angle of friction of the soil on the metal;
θ is the shear angle of the formation;
a _i - the height of the working part of the racks of the i-th paw of the i-th tier;
α is the angle of the paw to the bottom of the furrow (SU, ed. St., 1817947, A 01 B 13/16, 1993).

 When loosening the soil in fields occupied by agricultural crops, the roots of plants are destroyed by tierly mounted lancet paws. The support roller installed behind the stand does not restore the original soil surface profile. They form a soil shaft of sufficient height. During irrigation, the sediment layer between adjacent shafts is directed to lowerings, washing away loose soil aggregates along its way, increasing erosion processes.

 In addition, a tool for anti-erosion tillage is known, which includes a frame and successively mounted working bodies along the tool and tier-mounted on it, moreover, the working body for cutting the second tier is made in the form of slitheree, in which, in order to reduce energy consumption, the implement is equipped with additional slitherer for cutting the third tier, and the working body for cutting the first tier is also made in the form of slitherery, tilted in the direction of movement of the gun, with the thickness of each subsequent slit and its angle less than the previous one (SU, ed. St., 1155167, A 01 B 13/16, 1985).

 The most significant drawback of the implement is that after the passage of the implement there remains a gap filled with soil. This reduces her water-catching abilities. Tiers of slabs with low density are formed by tierly installed slits. With a slight supply of irrigation water or retention of rainfall, the walls of the cracks collapse. These disadvantages are due to the fact that first wide slit of the first stage is formed by slitherer. With the movement of the second layer trough, a less wide gap, but of a greater depth, is cut. Due to the setting of the cutting edge of the slitherese of the second tier at an acute angle to the direction of movement, the soil from the lower horizons is forced into the slot of the first tier. With the passage of the third layer tier gill, with an even smaller thickness, the entire space of the step gap is filled with loose soil and soil. The density of the walls of the formed gap is low, because undergoes only a single seal.

 In addition, there is a known method of soil cleavage containing stepwise cutting of a slit, in which, in order to reduce the energy intensity of the process and improving the quality of cleavage, the first step of the slit is cut with loosening its bottom and lower part of the walls, and before cutting the second step of the slit, the loosened soil is wetted the bottom of the bottom of the walls of the first step of the gap. A device for soil slitting, including a frame with support wheels and belt mounted on it in tiers, in which, in order to reduce the energy consumption of the process and to improve the quality of tapping, the slit is installed in pairs and the pair of slit is located frontally, and the slit in a pair are installed parallel to each other and in tiers while the top layer trough is equipped with a ripper installed in its lower part, which is connected to the trough through articulated traction (SU, ed. St. 1426480, A 01 B 13/16, 1988).

 To implement this method, an indispensable condition is the presence of an existing irrigation system and any design of the sprinkler. However, it is simply impossible to perform high-quality cracks in the second pass. A tractor with a device for soil slitting according to the aforementioned method cannot follow the previous track. This leads to a violation of the former cracks and to the formation of soil shafts, which is unacceptable in the fields under perennial forage crops.

 The closest device of the same purpose to the proposed object in terms of features is a tool for soil protection tillage, containing successively installed slitherese and a working body for loosening the walls of the slit, in which, in order to increase the degree of crumbling of the soil along the edges of the slit, the working body for loosening of the walls of the slit is made in the form of a mouth box mounted on a spring C-shaped rack with a half-screw dump; a disk placed with it in one plane is installed in front of the slithereer (ed. St. 1530108, A 01 A 13/16, 1989).

 The reasons that impede the achievement of the required technical result when using the well-known devices adopted for the prototype include low quality crafts water-absorbing cracks. The disk installed in front of the rack and in the same plane with it undoubtedly ensures cutting of roots in the soil and plant debris on the field surface. Mounted on a spring C-shaped strut, a twist spreader with a half-screw dump destroys the walls of the gap. The loose soil fills the cavity of the gap. When irrigated by sprinkling, the surface moist soil layer, being a waterproof screen, covers the entrance of the slot. Water flows along the slit flow to the lowering of the field surface, thereby violating the uniform distribution of artificial precipitation and, excluding the access of water to root-containing horizons. This reduces the effectiveness of irrigation in the crops of perennial forage crops, and as a result, the yield of cultivated crops.

 The problem to which the invention is directed is to increase the water interception capacity of cracks and the efficiency of distribution of irrigated water over soil horizons.

 EFFECT: reduced water erosion and increased productivity of perennial forage crops, such as clover, alfalfa, and their mixtures with cereal herbs, etc.

 The specified technical result during the implementation of the invention is achieved by the fact that in the known device for soil tillage, including a frame, a hitch and a disk knife and a slit mounted sequentially on the frame, equipped with a stand and a chisel, the slit rack is corrugated, and the stand section and the thickness of the corrugations decreases along the height of the rack in the direction of the bit.

 Due to the fact that the rack is made corrugated, the above technical result is achieved.

 The analysis of the prior art, including a search by patent and scientific and technical sources of information and identification of sources containing information about analogues of the present invention, allowed to establish that no analogue was found, characterized by features identical to all the essential features of the proposed invention.

 Hence. the invention meets the requirement of "novelty" under applicable law.

 To verify the compliance of the invention with the requirement of "inventive step", an additional search was carried out for known solutions in order to identify features that match the features of the invention that are distinctive from the prototype, the results of which show that the invention does not explicitly follow from the prior art, since no prior art has been identified the influence of the transformations provided for by the essential features of the invention on the achievement of a technical result.

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

 In FIG. 1 shows a tool for soil tillage, right view; in FIG. 2 - same, plan view; in FIG. 3 - 6 - section, respectively, aa, bb. BB, DG in FIG. 1, sections of the corrugations of the rack in the direction from the mounting part to the replaceable bit; in FIG. 7 is a cross section of the gap after the passage of cherezerez and the plot of soil density along the depth of soil horizons; in FIG. 8 is a cross section of a slit after irrigation by irrigation and a diagram of water permeability along the height of the walls of the slit.

 Information confirming the possibility of carrying out the invention are as follows.

 The tool for soil tillage (Fig. 1 and 2) contains a frame 1, an attachment 2, supports 3 and 4, a circular knife 5 and slitherer 6.

 Frame 1 is made of a front hollow beam of 7 hollow square or round sections with a wall thickness of at least 10 - 12 mm. The front hollow beam 7 is welded by two curved longitudinal bars 8 and 9 made of strip steel with a section of 120x20 mm. The rear parts 10 and 11 of the longitudinal bars 8 and 9 are provided with pairs of through holes with a diameter of 28.8 mm to accommodate a pair of fixing bolts 12.

In the middle part of the hollow beam 7, two racks 13 of the attachment device 2 are fixed with welds. The upper parts of the racks 13 are provided with holes 14 with a diameter of 30 ^+0.6 mm for mounting the finger 15. The upper link of the mounted system of the mounted tractor is connected with finger 15. Racks 13 with end sections of the front hollow beam 7 are connected by two braces 16 and 17. On the ends of the hollow beam 7, step fingers 18 and 19 with a diameter of 35 _-0.6 mm are fixed with ring welds for connecting the lower longitudinal linkage of the tractor hitch system of draft class 3 or 4 tons of power. According to the height of the uprights 13, two cheeks 20 are welded on the back of them for welding with bolts 21 of the extension 22. The extension 22 is made of two strips with a cross section of 100x12 mm. On the back of the extension 22 is made a pair of holes for installing the mounting bolts 23.

 On the outer side walls of the longitudinal bars 8 and 9, brackets 24 and 25 are mounted in welded mirrors for mounting the supports 3 and 4. Each support 3 (4) contains a stand 26, a support heel 27, a latch 28 of the position of the support 3 (4) and a stop 29 rack movement 26.

-образных профилей, соединенных с нижней частью 34 стойки 30 посредством заклепок 38. В задней нижней части переходника 35 сварными швами закреплена пята 37. В передней части переходника 35 цилиндрическим штифтом 39 закреплен кронштейн 40 сменного долота 36. Верхняя монтажная часть 31 стойки 30 щелереза 6 снабжена двумя парами отверстий. Верхняя пара отверстий диаметром 25 мм соединена болтами 23 с растяжкой 22. Нижняя пара отверстий диаметром 28,8 мм соединена болтами 12 с задними частями 10 и 11 продольных брусьев 8 и 9 рамы 1.Slitherez 6 includes a rack 30 with an upper mounting part 31, a front part 32 with a cutting edge 33, a lower part 34 with an interchangeable bit 36 and a supporting heel 37 fixed to it by an adapter 35. The adapter 35 is made of a pair

-shaped profiles connected to the lower part of the strut 30 by rivets 38. In the rear lower part of the adapter 35, a heel 37 is fixed by welds. In the front of the adapter 35, a bracket 40 of the replaceable bit 36 is fixed by a cylindrical pin 39. The upper mounting part 31 of the strut 30 of the slot 6 equipped with two pairs of holes. The upper pair of holes with a diameter of 25 mm is connected by bolts 23 with a brace 22. The lower pair of holes with a diameter of 28.8 mm is connected by bolts 12 with the rear parts 10 and 11 of the longitudinal bars 8 and 9 of frame 1.

The rack 30 of the crevice 6 is made corrugated (Fig. 1, 3 - 6). Corrugation 41 on the front part 32 of the rack 30 is made with a thickness of t ₁ = 20 mm The average corrugation 42 is made with a thickness of t ₂ = 30 mm.

In the middle of the strut 30, the thickness t _{3 of the} corrugations 41 and 42 is 45 mm. In the mounting part 31, the thickness of the corrugations t ₄ reaches 60 mm (Fig. 3). The mounting portion 31 of the strut 30 at the junctions of the rear parts 10 and 11 of the longitudinal bars 8 and 9 and the rear of the extension 22 is provided with support sleeves ensuring a snug fit of the corrugations 41 - 43 to the mating surfaces. Stand 30 is made with a variable cross-section. The cross section of the strut 30 gradually decreases in the direction from the mounting part 31 to the bit 36.

 The disk knife 5 is placed in front of the slitheree 6. The cutting edge 33 of the strut 30 of the slitherer 6 and the plane of the disk knife 5 are placed in the same plane. The disk knife 5 is equipped with a hub 44, in which the axis, rolling bearings, stuffing box seals, blind and through covers are placed. The axis of the disk knife 5 is mounted on the lead 45, which is welded to the rack 46. The rack 46 is located in the sleeve 47 mounted on the frame 1. The position of the rack 46 in the sleeve 47 is fixed by a locking bolt 48. The peripheral part of the disk knife 5 is provided with a cutting edge.

 The gun works as follows.

 The gun with the fingers 15, 18 and 19 of the attachment 2 is connected to the rods of the mounted tractor, configured according to a three-point setup scheme. The locking chains of the lower longitudinal linkage of the tractor hitch in the working position are sagging within 40 - 60 mm. The stand 46 with the loosened locking bolt 48 sets in the sleeve 47 the desired position of the lower part of the cutting edge of the disk knife 5. The stroke depth of the disk knife should be set between 0.12 - 0.18 m. After moving the frame 1 from the transport position to the working, cutting the edge of the interchangeable bit 36 cuts into the arable horizon and carries along the slit rack 30. The cutting edge 33 on the front part 32 of the rack 30 rushes into the slot previously cut with a circular knife 5. When the implement moves at a given working speed, cutting to The blade of a disk knife cuts plant and root residues on the surface of the field and in the upper soil layer. This eliminates the overhang of the roots and stems on the cutting edge 33 of the rack 30. The cutting edge 33 of the middle part of the rack 30 performs vertical cutting of the lower part of the arable layer and the arable horizon.

Consider the processes of formation of cracks 51, 52, 53, 54 and 55 along the depth of the processed layer. The cutting edge 33 (Figs. 1 and 6) on the lower part 34 of the rack 30 of the slit-hole 6, moving after the bit 36, in a relatively loose layer due to deformation of the soil, cuts the vertical section and corrugates 41 compacts the walls 56 of the slit 51. The width of the slit 51 after a one-time seal with the corrugations 41 is somewhat less than or equal to the thickness t _{1 of the} corrugations 41.

The corrugations 41 and 42 in the middle part of the rack 30 form the following two levels of slots - 52 and 53. The depth of these slots 52 and 53 is dictated by two factors: a) an increase in the thickness of the corrugations 41 and 42 to sizes t ₂ and t ₃ ; b) an increase in the cross section of the strut 30 due to an inclined cut of its rear part (Figs. 1, 5, and 4). The sealing of the walls 57 and 58 of the slots 52 and 53 occurs sequentially in time in two stages. The corrugations 41 first make a slit with a width of t ₁ , and then the corrugations 42 expand the gap 52 to a width of t ₂ . This leads to an increase in the density of the soil in the lower horizon and the hardness of the walls 57 and 58 in the cracks 52 and 53. Similarly, the walls 59 and 60 of the cracks 54 and 55 are formed, with the only difference being that the walls are densified in the loose upper horizon without disturbing the roots of the plants produce three to four times. The described sequence of execution of step slots 51 - 55 eliminates the formation of crevice soil rollers.

A bit 36 in the lower part of the slit 49 (Fig. 7) carries out a drain 50. Corrugation 41 with a thickness of t ₁ = 20 mm in the soil performs a narrow slit 51, which connects the cavity of the drain 50 with the surface of the field. Corrugations 41 - 43 perform stepped slots 52 - 55, the width of which increases as the depth of slit 49 decreases from 20 to 60 mm. A plot of the density of walls 56-60 of slit 49 is shown in FIG. 7. Following the snapping of crops of perennial grasses after mowing the aerial parts, irrigation is carried out with irrigation machines. During irrigation, the wide part 55 of the gap 49 intercepts the irrigation water and directs it to the drain 50 along the walls 55-60. The excess of moisture from the field surface along the cracks 49 and drain 50 is evenly distributed over the field surface and in the root horizons. The humidification zone 61 after completion of irrigation along the height of the slit 49 is shown in FIG. 8. Swelling of the soil leads to a narrowing of the width of the gap to its minimum size, providing moisture access to the lower horizons to the end of irrigation. This ensures a uniform distribution of precipitation over the surface of the field and along the depth of the root layer, and the processes of water erosion of the soil are also excluded.

 The soil-protective tillage tool can be successfully used in landscape farming to increase soil moisture reserves on slopes, as well as to increase the productivity of natural pastures and meadows. Tillage can be done at any time during the agricultural work.

Thus, the above information indicates that when using the invention the following set of conditions:
means embodying the invention in its implementation, is intended for use in agricultural machinery;
for the invention, as described in the independent clause of the claims below, the possibility of its implementation using the means and methods described above or known prior to the priority date is confirmed;
means embodying the invention in its implementation, is able to ensure the achievement of a technical result.

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

Claims (1)

 A soil-cultivating tillage tool comprising a circular knife and a slit, sequentially installed one after the other, equipped with a stand and a chisel, characterized in that the slit staple is corrugated, and the cross-section of the stand and the thickness of the corrugations decrease along the stand height in the direction of the bit.

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