RU2231244C2 - Agricultural unit for high-speed surface cultivation of soil - Google Patents

Abstract

FIELD: agricultural engineering, in particular, complex surface soil cultivation by means of self-propelled energized vehicle.

SUBSTANCE: agricultural unit has frame with carrier wheels at its ends, transverse beam attached to frame and equipped with vertical tines, triangular metal flat hoes fixed to vertical tines, and mechanism for tightening of rotating chain module mounted on frame rear part and provided with mellowing teeth fixed on chain links. Agricultural unit is further provided with double-roll disk-type soil grinder having disks immovably positioned at an angle to longitudinal axis of square shaft. Frame carrier wheels are equipped with soil removal device. Carrier wheel spacing is equal to width of track of vehicle adapted for advancement of agricultural unit. Point cover applied onto cutting edges of metal flat hoes is made in the form of directed circles of wear-resistant material. Vertical knife is provided with directed continuous cutting edge adjoining vertical tine and is attached to flat hoes. Chain module teeth are simultaneously fixed at two angles to longitudinal axis of link and to its surface. Soil grinder disks are mounted on single shaft at equal angles. Soil grinder disks may be mounted on different disks at equal angles or may be inclined in opposite directions. Spacing between soil grinder shafts may be selected in such a manner that disks fixed on one shaft enter clearances between disks on other shaft. In this case, shafts are connected by chain contour to provide for synchronized rotation thereof.

EFFECT: stabilized soil cultivation depth, improved quality of displacement and grinding of soil in transverse direction and uniform leveling of soil.

4 cl, 14 dwg

Description

The invention relates to agricultural machinery, is intended for the preparation of soils with different composition and properties in one pass for sowing grain, vegetables, industrial and agricultural crops in any agro-climatic zone and can be used in aggregates for complex surface treatment of soil with a self-propelled energy-saturated vehicle.

Known agricultural unit, which is a flexible rotating harrow with adjustable width grip. The unit is made in the form of a telescopic transverse frame, consisting of individual links. A flexible chain loop with loosening teeth attached to chain links is attached to the extreme links of the telescopic frame. To accelerate the transfer of the chain loop into the transport (or working) position, the frame has a tubular design, and the cantilever links of the frame can rotate about its longitudinal axis. To transfer the harrow to the transport position, the tractor driver includes a hydraulic motor, which rotates the end sections of the pipe through an asterisk with a chain contour and thereby winds the chain loop onto the telescopic frame. The transfer of the chain loop into the working position is carried out in a similar way by turning on the hydraulic motor “to reverse” to rotate the sprocket and chain chain in the opposite direction (see Russian patent No. 2034422 for class A 01 B 19/02, published on 05/10/95 in Bull. No. 13).

The main disadvantage of the known agricultural unit is that it does not provide soil preparation for sowing in one pass. This is due to the fact that harrowing the soil using a chain module provides only its spot surface treatment by “piercing” the soil with the teeth of the chain with a frequency depending on the size (length) and number of teeth on each link of the chain plume. However, when preparing the soil for sowing, this is not enough, because the teeth of the chain train cannot cut the roots of the plants, nor remove the remains of plant origin, nor can they ensure continuous loosening or stratification of the soil over the entire area of the cultivated area. Therefore, when preparing the soil for sowing in one pass of the unit, such a point tillage should be carried out only after its continuous preliminary plowing. But the well-known agricultural unit in its design does not contain units that provide continuous tillage with the help of a plow, or a plane cutter, or other similar working body.

This disadvantage was eliminated in an agricultural unit containing a multihull plow mounted on a self-propelled vehicle with a spine beam on which plow bodies are mounted, and a harrow connected to it, made in the form of a chain freely rotating module with loosening teeth on chain links. A telescopic beam is mounted on the spinal beam with the possibility of rotation in the vertical and horizontal planes. At the cantilever end of the telescopic beam, the support wheel and one end of the chain harrow are fixed. The second end of the harrow is mounted on the spinal beam of a multi-body plow. Using a telescopic beam, the chain harrow is tensioned and transferred from the transport to the working position and, conversely, from the working position to the transport. When the vehicle is moving, a multi-body plow carries out continuous plowing of the soil, and the harrow performs its surface tillage, providing soil preparation for sowing in one pass (see Ukrainian patent No. 18969 for class A 01 B 49/02, published on December 25, 1997 in Bull . No. 6).

The main disadvantage of this agricultural unit is that continuous tillage is carried out using a multi-body plow, which is included in its design. This traditional method of tillage (plowing using a plow) is an energy-intensive process (38% of all energy consumption during crop production is accounted for by plowing the soil) and causes increased wind and water erosion of the soil (only in the Dnipropetrovsk region due to plowing it was removed from economic circulation 36 % sown land). Therefore, countries with developed agriculture (USA, Canada, Australia, etc.) have not used the plow for tillage for a long time. In addition, the plow in the process of tillage forms longitudinal rolls from the soil and turns out clods of earth, which are of significant size. As a result of this, a significant unevenness of the soil surface is formed, which usually cannot be eliminated with a chain harrow in one pass. Thus, the known unit cannot provide the required quality of soil preparation for sowing in one pass, and its operation requires increased fuel consumption.

The closest in essence and the achieved effect, taken as a prototype, is an agricultural unit for high-speed surface tillage, containing a frame with support wheels at its ends, on which a transverse beam with vertical posts is fixed, to which metal plane cutters are attached, having a triangular shape, and an expansion rod for tensioning the rotary chain module with loosening teeth on the chain links mounted in the rear of the frame. Plane cutters are made in the form of solid triangular segments made of hardened steel and have the ability to rotate in a horizontal plane relative to the vertical posts.

To do this, at the lower ends of the uprights placed sliding bearings, providing free rotation of plane cutters. The loosening teeth of the chain module are attached to its links perpendicularly or obliquely to their longitudinal axis. Moreover, the plane formed by each pair of loosening teeth is either perpendicular or inclined in only one direction relative to the plane of the link. The frame is supported at a certain distance from the soil surface using the support wheels. A known unit operates as follows. When the vehicle is moving, rotating plane cutters cut the topsoil. When the plane cutters meet obstacles, they bypass them by turning relative to the vertical struts, which reduces the resistance to movement of the vehicle, therefore, reduces the energy consumption of the soil cultivation process. Further, the rotating chain module loosens the soil layer, which before that was cut with plane cutters. Thus, the well-known agricultural unit provides soil preparation for sowing in one pass (see Ukrainian patent No. 21093 for class A 01 B 19/02, published on 02/27/98 in Bull. No. 1).

The main disadvantage of the known agricultural unit is that it does not provide the required quality of tillage for sowing in one pass, due to the imperfection of its design. So, for example, rotating plane cutters, meeting with an obstacle (clods or layers of solid soil), bend around them, but do not destroy, therefore, they do not ensure the continuity of the soil treatment, leaving areas in it that are unacceptable for sowing crops. Untreated areas of the soil cause either uneven seed germination, or the latter will not germinate at all, which will invariably affect the yield for the worse. Since the supporting wheels of the unit are located at the ends of the frame, the distance between them (in width) does not coincide with the distance between the wheels (track) of the vehicle. Therefore, when the agricultural machine moves, the support wheels roll over not on the track of the vehicle, but on the surface of the soil, which, as a rule, has large irregularities compared to uneven soil in the track. Since the plane cutters are rigidly connected in height to the frame, they also turn out to be indirectly rigidly connected to the support wheels. Consequently, the wheels rolling over uneven ground surface will constantly change (through the frame and racks) the depths of plane cutters into the soil, that is, the latter will be processed unevenly in depth. This increases the likelihood of breakdown of the unit during its operation due to the bending of the uprights at the time of deepening into the soil of plane cutters when lowering the frame down due to fluctuations in the height of the support wheels. In addition, the adhesion of the soil to the support wheels of the unit increases the height of the frame, therefore, the unevenness of the soil tillage will increase. In addition, a plane cutter cuts off the soil layer in a horizontal plane, separating its outer layer from the inner one. At the same time, this layer practically remains continuous, and it is ineffective to destroy (loosen) it with the help of the teeth of the chain module, since solid sections can also appear in this layer, the point impact on which by the teeth does not lead to their destruction.

The second disadvantage of the known agricultural unit is its low operational reliability, which is due to the following. Since the racks are equipped with rotating plane-cutters, the nodes of their rotation (in fact, sliding bearings) are completely or partially (depending on the depth of impact on the soil) located in the soil, and this inevitably leads to the ingress of particles of soil, dirt and dust, which, in in turn, it causes increased wear of the rotation unit and leads to an increase in failures in its operation, since the earth, as is well known, is a sufficiently strong abrasive material. In addition, when a moving vertical strut meets an obstacle (for example, a block or a stone), it can bend. In this case, the plane cutter will not be able to rotate at all and to process (“cut”) the soil qualitatively. It is this circumstance (in order to prevent their bending) that makes it necessary to significantly increase the thickness of the racks, which increases the mass of the unit as a whole, and therefore, the energy consumption for its movement, that is, for tillage.

The third disadvantage of the known agricultural unit is the limited service life of its tillage organs. This disadvantage is explained as follows. It is well known that soil, being a strong abrasive material, leads to premature deterioration of tillage organs, in particular plane cutters. For this reason, knives of plane cutters are forced to make of expensive steel type 65G, Art. 35, Art. 45. However, this is ineffective, therefore, plane cutter knives are traditionally protected with a chisel attached in front (in the direction of soil cultivation). But fastening the bit is only possible if the plane cutter is stationary relative to the rack to which it is attached. Since in a well-known agricultural machine, a plane cutter has the ability to rotate relative to the rack, then he does not even have the concept of a “constant leading edge”. In such a situation, fixing the bit is impossible, because if it (the bit) appears as a result of turning the plane cutter not in the direction of the vehicle, it will only interfere with the uniformity of tillage and will increase the resistance to movement of the vehicle, and will also contribute to the bending of the vertical stand . Thus, the known rotating ploskore cannot be protected from the inevitable increased wear, therefore, its service life is sharply reduced, and this leads to the need for its frequent replacement, which increases the cost of operation of the unit, and therefore, the cost of tillage.

The fourth disadvantage of the known agricultural unit is that its use makes the process of soil cultivation unreasonably high cost. This disadvantage is explained as follows. Since plane cutters have significant dimensions (90 cm or more) in the plane, their rotation in the horizontal plane in the soil relative to the attachment axes requires additional costs for overcoming the resistance of the latter. Moreover, if as a result of rotation the plane cutter becomes not a wedge, but a plane to the direction of the vehicle’s movement, then it will create additional resistance to its movement. On vertical racks, to which the plane cutters are attached, during the tillage, crop residues will accumulate, which also increase the resistance to movement of the vehicle. The lack of any means on the racks for their cleaning of plant residues is a drawback of the unit. Thus, the use of the known agricultural unit causes increased fuel consumption to overcome resistance to vehicle movement due to imperfect design of rotating plane cutters and the accumulation of plant debris on the elements of the unit.

The fifth disadvantage of the known agricultural unit is the low efficiency of harrowing the soil with a chain module due to the peculiarities of fastening loosening teeth to the links of the chain. This disadvantage is explained as follows. Each pair of loosening teeth is formed by bending the sharpened metal rod in one plane. In a known assembly, such a pair of teeth is welded to a chain link either perpendicular to its plane or inclined to its plane in only one direction, that is, symmetrically with respect to the plane of the link. As a result of such attachment, when the chain module is rotated, both loosening teeth act on the soil in one line, which does not provide full leveling of the soil on the surface, and also the soil located between the lines of influence of adjacent teeth does not loosen and does not level out. This, in general, reduces the quality of the final surface tillage.

The basis of the invention is the task of improving the agricultural unit for high-speed surface tillage by increasing the wear resistance of its tillage organs, reducing the amplitude of vertical frame movements when moving the unit across the field, additionally equipping the unit with a ground shredder and increasing the density of the point impact on the soil with a chain module without increasing the number of teeth and frequency rotation angle to increase, in the aggregate, the quality of processing and soil preparation under sowing in one pass while reducing the energy consumption of the process and increase the life and reliability of the whole agricultural machine.

The technical result is an increase in the quality of processing and preparation of soil for sowing in one pass of the unit.

The solution to this problem is achieved by the fact that the agricultural unit for high-speed surface tillage, containing a frame with support wheels at its ends, on which a transverse beam with vertical posts is fixed, to which metal plane cutters having a triangular shape are attached, and a mechanism for tensioning a chain rotating module with loosening teeth on the links of the chain installed in the rear of the frame, is additionally equipped with a two-roll disk soil grinder, the disks of which are installed independently it is necessary at an angle to the longitudinal axis of the square shaft, in addition, the support wheels of the frame are equipped with a soil cleaner and are mounted with the possibility of adjustment along the gauge of the vehicle moving the unit, while a point coating is applied to the cutting edges of the metal knives of the plane cutters in the form of deposited circles of wear-resistant material and attached to them is a vertical knife with a deposited continuous wear-resistant cutting edge adjacent to the vertical strut, as well as the teeth of the chain module are fixed simultaneously under glom to the longitudinal axis of the link and at an angle to its plane. The disks of the soil grinder on one shaft are installed at the same angles. The slope of the disks of the soil grinder on different shafts is the same or opposite. The distance between the shafts of the soil grinder can be chosen so that the disks mounted on one shaft are located in the gap between the disks of the second shaft. In this case, the shafts are connected by a chain contour for their synchronous rotation.

A two-roll soil grinder with inclined disks rotating simultaneously with the shaft additionally cuts, pushes and crushes the soil coming out from under the plane cutters in a continuous layer, which ensures continuous intermediate linear tillage and its partial alignment in the plane. By installing discs on different shafts with the same or opposite slope, the effect on the soil increases and the quality of crumbling increases.

The teeth of the chain module complete the crushing of clods and the alignment of the soil in the plane, and this operation is performed qualitatively due to the fact that the teeth are inclined in two directions, therefore, the density of the impact of the teeth on the soil increases.

The equipment of the support wheels with cleaners eliminates the buildup of soil on them, therefore, their diameter during operation of the unit remains unchanged, and therefore the height of the frame decreases. Since the support wheels are located at a certain width, they roll along the track of the vehicle, which is a more even and solid support, which also reduces the height of the frame. Reducing the height fluctuations of the frame provides a more uniform depth of surface tillage.

Spot surfacing of wear-resistant material on plane-cutter knives provides a gradual transition (under the influence of wear) of the cutting edges from linear to sawtooth, which improves the conditions for cutting plant roots and reduces energy consumption for this operation. A vertical knife mounted on a plane-cutter in front of the support post reduces its resistance to movement of the vehicle and discards plant debris.

A further summary of the invention is illustrated in conjunction with illustrative material, which shows the following: FIG. 1 is a General diagram of the proposed agricultural unit for high-speed surface tillage, top view; FIG. 2 - supporting wheel of the unit, side view; FIG. 3 is the same front view; FIG. 4 - design of a plane cutter, top view; FIG. 5 is the same side view; FIG. 6 is the same in plan; FIG. 7 is a top view of a plane cutter knife with a wear-resistant material overlay without wear on the cutting edges; FIG. 8 - the same, with wear of the cutting edges; FIG. 9 - arrangement of plane cutters on the unit; FIG. 10 - design of the disk of the grinder of the soil, side view; FIG. 11 - design of a soil grinder; FIG. 12 is a side view of a chain module link; FIG. 13 - the same, a top view; FIG. 14 is a side view of the longitudinal beam of the unit.

The proposed agricultural unit for high-speed surface tillage contains a frame 1, on the front end of which support wheels 2 are installed, equipped with cleaners 3 made in the form of metal scrapers, the width of which coincides with the width of the wheels 2. Wheels 2 are attached to the frame 1 with the possibility of shifting in width frames 1. In this case, it becomes possible to install the wheels 2 so that the distance between them corresponds to the gauge left by the wheels (or tracks) of the vehicle Which moves on the field agricultural machine during its operation. Due to this, the wheels 2 of the agricultural unit always rely on a harder and smoother surface of the soil in the rut, therefore, the frame 1 of the unit will oscillate less in the vertical plane, which ensures a more uniform tillage in depth. Since the wheels 2 of the unit are constantly cleaned of dirt and soil adhering to them, their diameter remains constant, which also helps to reduce the vibrations of the frame 1 in height.

On the transverse beams 4 of the frame 1, vertical posts 5 are installed, at the lower ends of which planes 6 are fixed, which provide a continuous cutting of the upper soil layer. Depending on the type of soil being cultivated, plane cutters 6 can be installed in one or two rows. Soil disc grinders 8 are attached to the last row of plane cutters 6 by means of couplers 7. A longitudinal beam 10 is attached to the rear of the frame 1 by means of a hinge 9, the cantilever end of which is equipped with a support wheel 11. A winch 12 is secured to this beam 10, providing tension to the chain module 13 using cables 14. Swivel beams 15 provide the location of the chain module 13 at a given angle with respect to the direction of movement of the agricultural unit. On the frame 1 and on the longitudinal beam 12 there are rollers 16, 17 and 18 that envelope the cables 14 when the chain loop 13 is tensioned or when it is transferred to the transport position.

The knives 19 of the plane cutter 6 form a wedge (see Fig. 4), the tip of which is directed towards the movement of the agricultural unit. The span of knives 19 of the plane cutter 6 does not exceed 500 mm, which allows you to process the soil at shallow depths without “popping out” of the plane cutters 6 from the soil (usually the range of the plane cutters exceeds 900 mm and when they are used to till the soil at shallow depths they partially come out of the ground or “pop out” ”Completely). A vertical knife 20 with a weld-in cutting edge 21 is attached to the knives 19 of the plane cutter 6 and to the vertical stand 5 at the same time. Moreover, the vertical knife 20 can be welded to the knives 19 of the plane cutter 6, and is attached to the vertical rack 5 by a detachable connection, for example, by a bolt (due to the well-known in the drawings not shown). Such fastening allows you to quickly replace the tillage organ if necessary. The vertical knife 20 is made in the form of a steel triangle, the diagonal of which is the cutting edge 21 and is directed towards the movement of the agricultural unit. Since the vertical knife 20 is located in front of the vertical post 5, it, firstly, cutting the soil, reduces the resistance to movement of the vehicle and, secondly, raises the collected plant residues, which also reduces the resistance to movement of the vehicle. The reduction in resistance, in General, increases the productivity of the unit and allows you to increase the speed of tillage.

The knives 19 of the plane cutter 6 are made in the form of strips of ordinary steel, for example, Art. 3. A protective coating in the form of weld points 23 (or circles) of wear-resistant material is applied to the cutting edge 22 of the knife 19 (see Fig. 7). During operation of the plane cutter 6, its cutting edge 22 is abraded in areas between the weld points 23, which, due to the high wear resistance, are not abraded, and the cutting edge 22 gradually transforms from a straight shape to a sawtooth shape (see Fig. 8). The sawtooth shape of the cutting edge 22 facilitates cutting the soil and cutting off the roots of the plants, therefore, the load on the vehicle is reduced, and therefore it becomes possible to increase the speed of soil treatment.

Vertical racks 5 of plane cutters 6 are fixed on the transverse beams 4 of the frame 1, and the distance between them is chosen so that adjacent plane cutters 6 in different rows (on different transverse beams 4) overlap each other at a distance of at least 50 mm (see Fig. 9) . The overlapping of the plane cutters 6 with each other ensures complete cultivation of the soil until the wear of the cutting edges 22 is complete.

The soil grinder 8 is structurally made as follows. The disks 24 are made of steel with protruding radial segments 25 of a larger diameter (see Fig. 10). The outer ends of the disks 24 have a sharpening 26. The sharpening 26 can be weld of wear-resistant material. In the center of the disk 24 there is a square hole 27 through which the disks 24 are mounted on the square shaft 28 (see Fig. 11). Between adjacent discs 24 on the shaft 28 are installed spacer sleeves 29, the ends of which are made inclined. The angle of inclination of the end surfaces of the spacer sleeves 29 determines the angle of inclination of the disks 24. The ends of the shafts 28 are mounted in bearings 30, the housings 31 of which are fixed in rectangular frames 32. The distance between the shafts 28 may be greater than the diameter of the disk 24. In this case, the disks 24 are different the shafts 28 rotate (when moving the agricultural unit) independently of each other and do not interfere with each other. The distance between the shafts 28 may be even smaller than the diameter of the disk 24. In this case, the disks 24 of one shaft 28 enter the gaps between the disks 24 of the other shaft 28. In this case, the shafts 28 must rotate synchronously. Otherwise, the disks of adjacent shafts can engage with each other, excluding the free rotation of the shafts. To ensure synchronization of rotation of the shafts 28, a chain contour 33 is installed on each of them. When the agricultural machine moves, the disks 24, rotating, due to their inclination relative to the longitudinal axis of the shafts 28, constantly converge, diverge, that is, move along the soil surface in a zigzag manner, sliding and shifting while the soil, which is loosened and crushed. As you know, zigzag motion reduces the resistance to movement of the vehicle, therefore, the speed of cultivation can be increased.

Each link 35 of the chain module 13 has the same design for all. Each pair of loosening teeth 35 is formed, as in the prototype, by bending the sharpened metal rod in one plane. A pair of teeth 35 is welded to the chain link 34 with an inclination in two directions, that is, asymmetrically to the plane of the link (see Figs. 12 and 13). As a result of such fastening, each tooth 35 of one pair during rotation of the link 34 will rotate along its path. Due to this, the same width of the soil treated by the teeth 35 of one link 34 will be twice as densely exposed to the teeth 35. This contributes to better leveling and loosening of the soil.

The tension of the chain module 13 and its translation into transport position is carried out using a mechanical winch 12 mounted on the longitudinal beam 10. The winch 12 has the ability to move along the beam 10. For this, it is mounted on the tubular sleeve 36, the end of the first cable 37 is attached to the roller 38. The two second cables 14 are connected to the swinging beams 15, to which the ends of the chain cables 13 are also attached. The free ends of the chain cables 13 are connected through vertical posts 39 with a mechanical winch 12. When winding the cables 14 and 37 onto the winch 12 pos the one moves to the rear end of the beam 10 and at the same time turns the swing beams 15 outward, thereby tensioning the chain cables 13. If the swing beams 15 are additionally fixed in a certain position, for example, with fingers (not shown), then a certain angle of the cables 13 can be set relative to the longitudinal axis of the agricultural unit. To translate the chain cables 13 into the transport position, the cables 14 are disconnected from the swing beams 15 and hooked directly onto the chain cables 13. Next, winding the cables 14 and 37 onto the winch 12, the loosely sagging cable trains 13 are pressed against the longitudinal beam 10. In this case, the swing beams 15 are fond of chain trains 13 and are located along the agricultural unit.

The principle of operation of the proposed agricultural unit for high-speed surface tillage is as follows.

Before starting the operation of the agricultural unit, it is placed in a pen to transfer the chain loops 13 to the working position. Winding the cables 14 and 37 from the winch 12, the chain cables 13 are lowered to the ground. Then the cables 14 are led by the hinges 16 and 17, and their ends are fixed on the rotary beams 15. Next, the cables 14 and 37 are wound on the winch 12. In this case, the tension of the chain modules 13. After fixing the winch 12, the unit is ready for operation.

When the agricultural unit moves along the field, the pro-cutters 6, being the first in the direction of the movement of the unit, cut off the topsoil and root systems of plants uniformly in depth over the entire working width, since frame 1 practically does not oscillate in the vertical direction, since the support wheels 2 of the unit are rolled over track formed by the wheels of the vehicle. Next, a continuous layer of soil falls under the disks 24 of the soil grinder 8, which alternately move it and push it apart and cut into dense layers and lumps. Then the partially loosened soil falls under the chain plumes 13, where it is finally loosened and leveled. As a result of such a triple effect by the working bodies on the soil, the latter is completely and qualitatively prepared for sowing. At the same time, due to the decrease in resistance to movement of the vehicle, the processing speed can be increased without increasing fuel consumption.

A significant difference between the claimed object and the previously known is that the agricultural unit for high-speed surface tillage is equipped with a soil grinder made in the form of rotating inclined disks, plane cutters with spot welded wear-resistant material on cutting edges, a chain loop, the teeth of which are inclined in two directions relative to the plane of the link, and supporting wheels, the track of which coincides with the track of the vehicle moving the agricultural unit. These differences, in aggregate, allow you to qualitatively prepare the soil for sowing in one pass, while reducing energy consumption by reducing the resistance to movement of the vehicle. None of the known agricultural aggregates can have the indicated properties, since they do not contain tillage tools with a sawtooth cutting edge, zigzag-spreading elements in one design, and also do not provide measures to reduce frame vibrations.

The technical advantages of the proposed technical solution include the following:

- stability of the depth of tillage by equipping the support wheels of the frame with cleaners and by combining the track of the support wheels with the track of the vehicle;

- reduction in resistance to movement of plane cutters due to the presence of weld points on the cutting surface of their knives;

- the ability to move and crush the soil in the transverse direction due to the presence in the design of the soil grinder with inclined disks;

- the possibility of uniform soil planning due to the location of the teeth of the chain module at two angles relative to the plane of the chain links;

- high reliability in operation due to the presence of vertical knives in front of the racks carrying plane cutters;

- increase the service life of the unit by reducing the wear of its tillage tools.

The economic effect of the implementation of the invention is obtained by reducing the energy costs of surface tillage for sowing in one pass, as a result of reducing the resistance to movement of the vehicle and by improving the quality of tillage as a result of reducing frame vibrations and tripling the soil in one pass.

In fact, during operation of the unit, a plane cutter cuts the soil layer, soil shredders spread the earth under their own weight, and a chain loop loosens, crushes, levels, plans the soil and covers up moisture in it, while throwing stones and plant roots to the surface. In one pass of the unit, operations are carried out to prepare the soil for sowing, to destroy weeds and protect the soil from further drying out, creating favorable conditions for biological life in the soil, which is a guarantee of high and stable crops with minimal energy and labor costs, reducing the time for agricultural soil preparation work. It should be noted that in the design of the proposed agricultural unit there are no drives for rotation of its tillage organs. For this purpose, only the vehicle traction is used. The rotation of the working bodies occurs due to their contact with the soil, and they practically do not resist the movement of the vehicle. Due to this, it is possible to increase the speed of soil cultivation by about 3-4 times without increasing the power of the vehicle and reduce fuel consumption by 4-7 times (depending on the depth of soil cultivation) compared to using aggregates containing plows in their design. Despite the apparent complexity of the design, the proposed agricultural unit is serviced by one worker.

Claims (4)

1. An agricultural unit for high-speed surface tillage, containing a frame with support wheels at its ends, on which a transverse beam with vertical posts is fixed, to which metal plane cutters are attached, having a triangular shape, and a mechanism for tensioning a rotating rotating module with loosening teeth on chain links installed in the rear of the frame, characterized in that the unit is equipped with a two-roll disk soil grinder, the disks of which are mounted motionless at an angle to the longitudinal axis of the shaft la, and the teeth of the chain module are fixed simultaneously at an angle to the longitudinal axis of the link and at an angle to its plane, while the support wheels of the frame are equipped with soil cleaners and are installed with the possibility of adjustment along the gauge of the vehicle moving the unit. 2. The agricultural unit according to claim 1, characterized in that the disks of the soil shredder on each shaft are installed with the same angle of inclination, and the inclination of the disks on different shafts is the same or opposite, the disks of one shaft being located in the gaps between the disks of the other shaft, and the shafts connected by a chain contour for their synchronous rotation. 3. The agricultural unit according to claim 1, characterized in that the cutting edges of the metal knives of the plane cutters are coated with a spot coating in the form of deposited circles of wear-resistant material. 4. The agricultural unit according to claim 1, characterized in that each plane cutter has a vertical knife adjacent to its stand with a weld-in continuous wear-resistant cutting edge.

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