RU2250587C1 - Method of creating on slopes licorice crop plantations suitable for mechanical harvesting, and machine for providing moisture accumulating micro terraces and simultaneously for preparing soil for planting cuttings of rootstocks of licorice of tidal, liman and dry steppe ecotypes - Google Patents

Abstract

FIELD: agriculture and agricultural engineering, in particular, planting of licorice rootstock cuttings on slopes and abandoned lands and mechanical harvesting of root mass as licorice raw material.

SUBSTANCE: method involves preplanting cultivation of soil on slopes in late autumn by providing rectangular-section 1.1-1.4 m wide and 0.45-0.60 m deep channels; mellowing soil and ground in zones within channel, with soil and ground in one zone being rotavated to agronomically valuable fractions and soil and ground in other zone being mellowed to lumps and crumbs with average diameter of 8-15 cm in order to provide for larger amounts of cavities (porosity); forming moisture accumulating micro terraces by laterally moving agronomically valuable soil fractions onto surface of lumps and crumbs; planting licorice rootstock cuttings in part of channel with preliminarily located lumps and crumbs to 12-18 cm depth at soil temperature of at least 18°C. During autumn-winter period, moisture is accumulated in said channel, and precipitation is aerated and redistributed in layers. Method allows stable licorice associations to be grown at productivity rate of at least 20 t/hectare of conditioned roots used as licorice raw material in pharmaceutical and chemical industry. Machine has frame bearing successively arranged digging-transporting device, grinding device configured as rotavator-type soil mixer, and rotary terrace-forming device equipped with profiling moldboard and positioned behind rotavator-type soil mixer. Digging-transporting device is made U-shaped, with soil layer lifting shares. Rotavator-type soil mixer is formed as sectioned drum. Each of said drums is positioned on single geometric axis and is equipped with various frequency drive. One of said drums having hollow shaft is mounted by means of roller supports on pivot of other drum. Drum teeth of rotavator-type soil mixer are fitted with replaceable inversion turning knives with blades at their working faces. Drive sprockets of toothed-drive chains are mounted on pivots of drums, which face frame. Said chains are linked with the help of drive sprockets and are connected through individual overtime clutches with reducer of grinding device drive.

EFFECT: increased efficiency and reduced consumption of power.

6 cl, 11 dwg

Description

The invention relates to agriculture and agricultural engineering, and in particular to technologies and technical means for preparing the soil and planting cuttings from licorice rhizomes on slopes and inconveniences, followed by mechanized harvesting of the root mass as licorice.

A known method of creating long-term plantations of licorice culture as mesogalophyte on degraded irrigated soils, including its pre-planting and planting, which mechanically destroy weeds, crop residues and root systems in the surface layer, carry out strip loosening of the arable layer and arable horizon, lay from licorice rhizomes to the surface of the treated field, wide-row plantings are formed by covering the cuttings with a layer of soil by removing it from the row spacing and creating ridges on planting material; the destruction of weeds is carried out by milling the upper layer to a depth of 3-12 cm; strip loosening is performed to a depth of 0.35-0.55 m in increments between strips of 0.35-1.05 m; laying of cuttings is carried out over the ridges of untreated strips in increments of 0.7-1.4 m; soil excavation is carried out to a depth of 0.15-0.25 m from the surface of the field (RU Patent C1. IPC ⁷ A 01 B 79/02, A 01 C 11/02, 7/20. A method for creating long-term plantations of licorice culture as Mesogalophyte on degraded irrigated soils and a device for its implementation. A.P. Sokolov, A.V. Galda, A.M.Saldaev (RU) - Application No. 99126981/13; Declared December 23, 1999, Publish. June 20, 2001, Bull. No. 17 // Inventions. Industrial designs. - 2001. - No. 17).

The disadvantages of this method include the fact that it is intended to create licorice plantations in aligned and planned areas. When examining wild thickets of licorice licorice in the floodplains of the Volga, Akhtuba, Don and others, it was found that the greatest productivity of the root mass of licorice is on manes, slopes and inconveniences. Productivity in these areas exceeds 80 t / ha of raw conditioned roots. However, machine cleaning of licorice root in these areas is difficult. Licorice plants strengthen the coastal zones of rivers and canals. To mechanize planting processes, microterraces are required with a width equal to or greater than the track of mounted tractors.

The closest analogue to the claimed object in terms of the device is a tool for creating moisture-accumulating micro-terraces on the slopes with simultaneous soil preparation for planting wood and shrub plants, including a frame with sequentially mounted cutting-transporting and grinding working bodies, in which the cutting-transporting working body made in the form of a semicircular tray turning into an inclined plane, and a milling soil mixer is installed parallel to it, while behind the mill with a soil mixer, a distribution plate is placed, mounted at an angle to the axis of the implement in a longitudinally vertical plane, and a pivoting terrace-forming working body pivotally connected to the frame with a profiling blade; the profiling blade of the terrace-forming working body has the ability to change position in the transverse vertical plane by means of a control cylinder mounted on the frame, and is connected with it using a beam, shaft and lever (RU Patent No. 2195794 C2, IPC ⁷ A 01 B 13/16, 79/02, А 01 С 1/00 A tool for creating moisture-accumulating microterras on slopes with simultaneous soil preparation for planting tree and shrub plantations / Yu.M. Zhdanov, V. G. Yuferyov (RU) - Application No. 2000127628/13 ; claimed 02.11.2000; publ. 01.10.2003, Bull. No. 1 // Inventions. Useful for fashion Li. - 2003. - No. 1).

The disadvantages of the described tool include low operational reliability, the impossibility of terraces on the slopes when moving across the slope in a shuttle mode, clogging the soil between the frame and the control hydraulic cylinder, soil sticking to the surface of the profiling blade and distribution panel, high energy consumption and low productivity.

The essence of the claimed invention

The problem to which the claimed invention is directed is the creation of sustainable, long-term and highly profitable plant communities on slopes, excluding water and wind erosion of the soil, sliding and leaching of soil and soil on slopes and shores.

The technical result is a reduction in energy consumption, increased productivity, the collection of licorice raw materials with a high content of glycyrrhizic acid and low production costs for the needs of the pharmaceutical, chemical, food and other industries.

The specified technical result in terms of the proposed technology is achieved by the fact that in the known method of creating licorice crops on the plantation slopes suitable for machine harvesting, including pre-planting soil cultivation and planting, according to the invention, pre-planting soil cultivation on the slopes is performed in late autumn by making rectangular ditches sections 1.1-1.4 m wide to a depth of 0.45-0.60 m with loosening of part of the soil and soil into agronomically valuable fractions, and the other part into lumps and blocks with an average diameter of 8-15 cm, moisture opitelnye mikroterrasy formed sideways movement agronomically valuable soil fractions on clods and lumps, planting cuttings from the rhizomes of Glycyrrhiza conduct ditches in the part with the previously placed clods and lumps to a depth of 12-18 cm in the soil temperature is not lower than + 18 ° C; volumes of soil and soil with an agronomically valuable fraction and a fraction of clods and blocks are referred to as 1: (0.8-1.2).

The indicated effect in terms of technical means is achieved by the fact that in a known machine for making moisture-accumulating microterras on slopes with simultaneous soil preparation for planting cuttings from licorice rhizomes of bare floodplain, estuary and dry-steppe ecotypes, including a frame with a cutting, transporting and grinding worker sequentially installed on it body in the form of a milling mixer of the soil and placed behind it a rotary terrace-forming working body with a profiling barrel, according to the invention, the milling cutter The soil mixer is made in the form of a sectional drum, each of the drums is placed on a common geometric axis and has an individual multi-frequency drive, while one of the drums has a hollow shaft, is installed by means of rolling bearings on the axle of the other drum, the fangs of the milling mixer are equipped with interchangeable reversible reversible knives with blades on the working faces, on the trunnion of the drums facing the frame side, mounted sprockets of gear-drive chains connected to the drive gear with individual clutches of the maximum cient and undercut-conveying working member is configured U-shaped with the lifting plowshares formation, profiling blade terrasoobrazuyuschego working body is provided with mechanisms for remote changing the angle setting of the die blade to the moving direction, angle and insertion angle to the horizontal; the mechanism for remotely changing the angle of setting the profiling blade to the direction of movement is made in the form of a L-shaped rack mounted with the possibility of rotation around the vertical axis in the bearings in the middle part of the frame and connected via a lever to the rod of the power hydraulic cylinder; the mechanism of remote change of the angle of inclination to the horizon is mounted on the L-shaped rack of the mechanism of remote change of the angle of setting the profiling blade to the direction of movement and is made in the form of pivotally connected rack levers, the base of the power hydraulic cylinder is mounted on the upper lever of the rack, and its rod is kinematically connected to the lower rack lever; the mechanism for remote change of the angle of inclination of the profiling blade to the horizon is made in the form of a bracket connecting the blade with a L-shaped rack for discrete changes in the angle.

By creating moisture-accumulating microterras with zones in the form of clods, clumps and agronomically valuable fractions, moisture accumulation, aeration, and conditions for the normal growth of licorice cuttings from rhizomes are ensured.

The invention is illustrated by drawings.

Figure 1 shows a cross section of the slope of the southern exposure with made microterraces and loosened layers of soil in a trimmed ditch.

Figure 2 shows a cross section of a terrace on a slope with planted cuttings.

Figure 3 presents cross sections of terraces with three-year-old plants of licorice.

Figure 4 shows the sections of the ditches on the terraces at the time of cutting and complete sampling of the root mass of licorice in the sixth to seventh years of life when machine cleaning licorice raw materials.

Figure 5 in an axonometric image shows a machine for making water-holding microterras with simultaneous soil preparation for planting cuttings from licorice rhizomes of bare floodplain, estuary and dry-steppe ecotypes.

Figure 6 is the same plan view (the profiling blade of the terrace-forming working body by the mechanism of remote change of the setting angle is set to shift agronomically valuable fractions of soil and soil from right to left in the direction of travel of the machine).

In Fig.7 - the same when moving the soil and soil in the direction of movement of the machine.

On Fig - the same, when moving the soil and soil in the lateral direction (left to right).

In Fig.9 is the same view of the machine on the left.

Figure 10 is a view A in figure 9, a profiling blade with mechanisms for remote changes in the angle of inclination of the terrace forming tool to the horizon and the angle of setting the profiling blade to the direction of movement.

In Fig.11 - section bB in Fig.9, a transverse vertical (diametrical) section of a milling soil mixer.

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

The method of creating licorice plantations on the slopes of 1 plantation suitable for machine harvesting involves pre-planting tillage and planting. Pre-planting tillage on the slopes is performed in the late autumn period. Processing slopes 1 is done by making ditches 2 of rectangular section 1.1-1.4 m wide to a depth of 0.45-0.60 m. At this point, the relative soil moisture increases to 22-26% with a decrease in soil hardness to 40-50 kPa . In ditches 2 in zone 3, the soil and soil are loosened to agronomically valuable fractions. In the zone 4 of ditches 2, soil and soil are loosened into lumps and blocks with an average diameter of 8-15 cm (see figure 1). Moisture storage microterraces 5 are formed by moving agronomically valuable soil fractions from zone 3 to the surface of clumps and lumps in zone 4 and to the surface of the untreated part of slope 1. During the autumn-winter period, soil and soil aeration, accumulation and redistribution of moisture occur in zones 3 and 4 both in ditch 2 and on slope 1 between the microterraces 5. A layer of loose soil above zone 4 excludes evaporation and desiccation of soil and soil in the ditch 2. Planting of cuttings 6 from licorice rhizomes of four to five years old is carried out in zone 4 with previously located lumps and clumps to a depth of 12-18 cm from the surface of the microterrace 5 at a soil temperature of not lower than + 18 ° C (see figure 2). The volumes of soil and soil with an agronomically valuable fraction in zone 3 and a fraction of clods and blocks in zone 4 are referred to as 1: (0.8-1.2). This ratio provides the maximum accumulation of moisture in the autumn-winter period and the redistribution of the roots 7 and rhizomes of 8 licorice in the second and subsequent years of plant life (see figure 3). After six to eight years of licorice plant life, a complex multi-tiered network of vertical, horizontally and obliquely distributed roots and rhizomes is formed 8. When productivity reaches more than 10 t / ha of raw conditioned roots, the aboveground mass 9 is mowed in the form of cutting and distributed on the surface of the microterrace 5. The placement of cuttings 6 when planting in a ditch 2 in zone 4 allowed the formation of roots 7 and rhizomes 8 both along the ditch 2 and oriented upward towards the ascent of slope 1. The width of the microterras 5 allows you to use t actor class rods 3, 4, 5, and drive a car cleaning licorice root mass. Cleaning is carried out by cutting the soil layer in the ditch 10, removing the root mass from the soil and soil, followed by laying loose soil and soil on the bottom of the ditch 10 (see figure 4). After drying the raw roots of 7 and rhizomes of 8 licorice with a moisture content of 45-48% until the moisture content drops to 24-30%, the root mass is selected from the surface of the microterrace 5. Subsequently, the surface of the microterrace 5 is leveled and rolled. Repeated harvesting of licorice is carried out in five to six years.

The machine for making moisture-accumulating microterras 5 on slopes 1 with the simultaneous preparation of soil for planting cuttings 6 from rhizomes 8 of licorice naked floodplain, estuary and dry-steppe ecotypes includes a frame 11 (see Figs. 5-11) with a cutting-transporting working body sequentially installed on it 12 and grinding the working body 13 and placed behind him a rotary terracing working body 14 with a profiling blade 15.

The frame 11 of the welded structure contains a horizontal beam 16 of the upper level, the left longitudinal beam 17, the right longitudinal beam 18, the left strut 19, the right strut 20, the left jib 21, the right jib 22 and the horizontal beam 23 of the lower level. On the horizontal beam 16 of the upper level there is a bracket 24 with a finger 25 for connecting to the upper center link of the hydraulic system of an aggregated tractor of draft class 3 (VT-100, T-150, DT-75M, etc.). In places of conjugation of the left strut 19 with the left longitudinal beam 17 and the right strut 20 with the right longitudinal beam 18, brackets 26 and 27 are placed for connecting with the fingers 28 and 29 to the lower longitudinal rods of the tractor tractor traction class 3 (4, 5).

On the left rack 19 and the right rack 20 are detachable brackets for mounting the support wheels 30 and 31 with screw mechanisms 32.

On the shelves of the angles 33 placed two-speed gearbox 34 and individual clutch 35, 36 of the maximum torque for driving the grinding working body 13.

On the left longitudinal beam 17 and the right longitudinal beam 18 is installed cutting-transporting working body 12. The cutting-transporting working body 12 is made U-shaped with a cutting edge 37 on the front part and plowshares 38 on a flat horizontal part for lifting the soil and soil layer above the bottom ditches 2.

The grinding working body 13 is made in the form of a milling soil mixer. The latter has sectional drums 39 and 40. Each of the drums 39 (40) is placed on a common geometric axis and has an individual multi-frequency drive due to the design features of the two-speed gearbox 34. One of the drums 40 has a full shaft 41 (see Fig. 11). It is installed by means of rolling bearings 42 and 43 on the left long pin 44 of the right drum 39. The axial displacements of the drums 39 and 40 are limited by nuts 45 on the left long pin 44 of the right drum 39.

On pins 46 and 47 of the drums 39 and 40, facing the left longitudinal beam 17 and the right longitudinal beam 18, driven sprockets 48 and 49 of the gear-drive chains 50 and 51 are connected, connected to the two-speed gearbox 34 via individual clutches 35 and 36 of the maximum torque . Clutches 35 and 36 of the limiting moments are placed on the splined parts of the output shafts of the gearbox 34 and the shafts 52 and 53 (see FIG. 5) with the drive sprockets of the gear-drive chains 50 and 51. The left axle 47 has a flange 54 by which it is mated to the left the drum 40. The pins 46 and 47 are placed in the bearing bearings 55 and 56, having a single geometric axis (see Fig.11). Sprockets 48 and 49 have hubs with slots. Sprockets 48 and 49 on pins 46 and 47 are fixed with nuts 57. Access to them is provided by covers 58 and 59. The voltage of the gear-drive chains 50 and 51 is carried out through windows 60 and 61 on the left jib 21 and the right jib 22.

On the frames of the drums 39 and 40 are placed the fangs 62 of the milling mixer of the grinding working body 13. The fangs 62 of the drums 39 and 40 are equipped with replaceable inversion-revolving knives 63. Each of the knives 63 has blades 64 and 65 on the working faces.

The profiling blade 15 of the rotary tracer working body 14 is mounted on a horizontal beam 23 of the lower level and is equipped with mechanisms 66, 67 and 68 of remote changes in the angle of setting the profiling blade 15 to the direction of movement of the machine, the angle of incidence and the angle of inclination to the horizon (see Fig. 5-10 )

The mechanism 66 of the remote change of the angle of setting the profile blade 15 to the direction of movement of the machine on the slope 1 when the microterras 5 is made is in the form of a L-shaped stand 69. The stand 69 is mounted with the possibility of rotation around the vertical axis in the bearing supports by means of a sleeve 70 in the middle of the horizontal beam 23 frames 11.

The upper protruding portion of the strut 69 is connected via a lever 70 to the rod 71 of the power cylinder 72. Depending on the length of the stroke of the rod 71 in the cylinder liner 72, the profiling blade 15 occupies one of the positions shown in FIGS. 5-9.

L-shaped rack 69 is equipped with a mechanism 67 for changing the angle of incidence of the blade 73 of the profiling blade 15 to the horizon, which is made in the form of an arm 74 for connecting the blade 15 with the L-shaped rack 69 for discrete changes in the angle of cutting (see Fig. 9).

The mechanism 68 of the remote change of the angle of inclination of the blade 73 of the blade 15 to the horizon is mounted on an L-shaped rack 69 of the mechanism 66 of the remote change of the angle of setting the profiling blade 15 to the direction of movement of the machine and is made in the form of articulated levers 75 and 76 of the rack 69. On the upper lever 75 69, by means of the beam 77, the base 77 of the power hydraulic cylinder is mounted, and its rod 78 is kinematically connected with the lower lever 76 of the rack 69 via the bracket 79 and the pin 80. The upper and lower levers 75 and 76 are mutually connected by the axis 81 (see Fig. 10).

The reducer 34 (see Fig. 5) with a telescopic propeller shaft 82 is connected to a power take-off shaft (PTO) of an aggregated tractor. The shaft speed 82 is either 9 s ^-1 or 17 s ^-1 .

Machine for making moisture-accumulating microterras on the slopes works as follows.

The aggregated tractor of traction class 3 (4, 5) for ensuring normal operation of the machine must be equipped with a hydraulic system, two fittings that are remote from the cab for hydraulic connection of the cavities of the power hydraulic cylinders 72 of the mechanism 66 and the base 77 of the hydraulic cylinder of the mechanism 68 and the PTO with a rotation speed of 9 s ^{- 1} (540 min ^-1 ) and 14 s ^-1 (1020 min ^-1 ).

Fingers 25 of the upper bracket 24 and fingers 28 and 29 of the lower brackets 26 and 28 connect the thrust of the hydraulic system of the tractor to be coupled according to a three-point linkage pattern.

The locking chains hitch limit the lateral displacement of the frame 11 of the machine relative to the longitudinally vertical plane of the unit. The free universal joint of the Hook of the PTO shaft 82 is connected to the splined shaft of the tractor PTO shaft.

By means of screw mechanisms 32, the support wheels 30 and 31 are raised relative to the longitudinal beams 17 and 18, providing a depth of cut of the formation by the cutting-transporting working member within 0.45-0.60 m.

The switching mechanism of the two-speed gearbox 34, the rotational speed of the drum 39 is set equal to 4.5 s ^-1 (270 min. ^-1 ) when the tractor moves along the slope 1, the slope of which is directed downward. At the same time, the rotational speed of the drum 40 of the grinding working element 13 is set equal to 9 s ^-1 (540 min ^-1 ).

When driving along slope 1 (see Fig. 1), the tractor cabin is oriented towards the ramp. The cutting edge 37 of the working body 12 cuts a layer of soil soil 1.1-1.4 m wide, forming a ditch 2. The cut layer with plowshares 38 rises above the bottom of the ditch 2 and goes to the fangs 62 of the grinding working body 13. With 64 (65) inversion revolving removable knives 63 on the canines 62 of the drum 39, the layer crumbles into clods and blocks with an average diameter of 8-15 cm and again in the loosened state it is laid in the ditch 2, forming zone 4. Blades 64 (65) of the inversion-reversible removable knives 63 on the canines 62 drum 40 layer in zone 3 crumbles to agronomically valuable 1-1.5 cm.

Next, a rotary terracing working body 14 with a profiling blade 15 enters the work in the direction of the machine.

By mechanism 66, the blade 73 of the profiling blade 15 is set at an angle to the direction of travel of less than 90 ° (see FIGS. 5 and 8). The tractor driver, controlling the left handle of the hydroshock of the hydraulic distributor, supplying oil to the corresponding cavities of the hydraulic cylinder 72, sets the mechanism 66 for remote change of the angle of setting the profile blade 15 to the direction of movement of the machine, moving with the tractor on slope 1, ensures smooth movement of part of the cut soil from the slope with the left edge of the blade 15 and an agronomically valuable soil fraction from zone 3.

Simultaneously with this mechanism 68, the left end of the blade 15 with the blade 73 tilts under the beam 23 of the frame 11, forming a slope to the surface of the slope 1 so that the terrace 5 has a horizontal strip. With such manipulations by mechanisms 66 and 68, blocks and clods of soil and soil in zone 4 of the ditch 2 are covered with a loose fraction of soil from zone 3.

In the second pass of the assembly by the mechanism 66, the blade blade 73 of the blade 15 is placed in the position shown in Fig.6. The inclination of the blade 73 relative to the beam 23 of the frame 11 is changed in the other direction. When the tractor is turned on the headland of slope 1 by turning the forks of the two-speed gearbox 34, the rotational speeds of the drums 39 and 40 are changed so that the rotational speed of the drum 39 is greater than the rotational speed of the drum 40.

Depending on the hardness of the soil and soil, the machine operator discretely changes the angle of incidence of the blade 73 into the soil layer of slope 1 discretely in the range from 15 to 35 °.

On light soils, the profiling blade 15 of the terracing working body is set at an angle of 90 ° or close to these values (see Fig. 7 and 9).

Microterraces 5, which were made in the late autumn period, are wider than the track (width) of tractors of traction class 3 (4, 5) and are left alone until spring. Precipitation in the form of rain, snow, ice during melting fills the voids in zones 3 and 4. Soil and soil in the ditches 2 settle, forming hollows. This eliminates water and wind erosion of the soil on the terraces until the time of planting of cuttings 6. Planting of cuttings 6 is carried out by a landing machine with one centurion. The supply of cuttings 6 from licorice rhizomes is provided by one or two planters, providing a step between cuttings 6 in a ditch 2 of 0.35-0.55 m at a depth of 0.12-0.18 m. The gap after passage of the centurion of the planting machine is sealed. Precipitation during the spring-summer period accumulates in the lower part of ditch 2, providing the best conditions for the development of licorice roots, and later on overhead shoots.

The mechanisms 66-68 on the frame 11 of the machine provide the optimal position of the profiling blade 15, which reduces energy consumption with a given quality profiles microterras 5.

Claims (6)

1. The method of creating licorice culture plantations on the slopes of the plantations suitable for machine harvesting, including pre-planting tillage and planting, characterized in that the pre-planting tillage on the slopes is performed in late autumn by making rectangular ditches 1.1-1.4 m wide at a depth 0.45-0.60 m with loosening of part of the soil and soil into agronomically valuable fractions, and the other part into lumps and blocks with an average diameter of 8-15 cm, moisture-accumulating microterraces are formed by moving agronomically valuable soil fractions into the lumps to the side and blocks, planting cuttings from licorice rhizomes are carried out in parts of the ditch with previously placed clods and blocks to a depth of 12-18 cm at a soil temperature of at least + 18 ° C. 2. The method according to claim 1, characterized in that the volumes of soil and soil with an agronomically valuable fraction and a fraction of clods and blocks are as 1: (0.8-1.2). 3. A machine for making moisture-accumulating microterras on slopes with simultaneous soil preparation for planting cuttings from licorice rhizomes of bare floodplain, estuary and dry-steppe ecotypes, including a frame with a cutting-transporting and grinding working body in series in the form of a milling soil mixer and placed behind it rotary terrace-forming working body with a profiling blade, characterized in that the milling soil mixer is made in the form of a sectional drum, each of the drums p It is located on a common geometric axis and has an individual multi-frequency drive, while one of the drums has a hollow shaft installed by means of rolling bearings on the axle of the other drum, the fangs of the drums of the milling mixer are equipped with removable inversion-revolving knives with blades on the working faces, on the axles of the drum sections facing towards the frame, the driven sprockets of the gear-drive chains are mounted, connected to the drive gearbox by individual limit torque couplings, and the cutting-transporting working body made U-shaped with plowshares for raising the formation, the profiling blade of the terrace forming working body is equipped with mechanisms for remote changes in the angle of setting the profiling blade to the direction of movement, the angle of incidence and the angle of inclination to the horizon. 4. The machine according to claim 3, characterized in that the mechanism for remotely changing the angle of setting the profiling blade to the direction of movement is made in the form of a L-shaped rack mounted to rotate around a vertical axis in bearing bearings in the middle of the frame and connected via a lever to the rod power hydraulic cylinder. 5. The machine according to claim 3, characterized in that the mechanism for remotely changing the angle of inclination to the horizon is mounted on the L-shaped rack of the mechanism for remotely changing the angle of setting the profiling blade to the direction of movement and is made in the form of articulated link arms of the rack, on the upper lever of the rack by means of a beam the base of the power hydraulic cylinder is mounted, and its rod is kinematically connected with the lower arm of the rack. 6. The machine according to claim 3, characterized in that the mechanism for changing the angle of incidence of the blade of the profiling blade to the horizon is made in the form of a bracket connecting the blade with a L-shaped rack for discrete changes in the magnitude of the angles.

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