RU66654U1 - DISC SOIL PROCESSING DEVICE - Google Patents

Abstract

NAME OF USEFUL MODEL: Disc tillage device. USE: in tillage devices designed for tillage after harvesting thick-stalked row crops, for stubble cultivation, for loosening and preparing the soil for sowing, destruction of weeds and crushing of crop residues, and can also be used for the primary treatment of old arable land and heavy soddy soils. SOLVED PROBLEM improving the quality of tillage due to the uniform distribution of the cultivated soil across the width and depth, as well as increasing the uniformity of the soil structure. ESSENCE OF A USEFUL MODEL: in a disk tillage device containing a frame with transverse bars on which racks with convex-concave disks mounted for rotation are fixed frontally over the entire width of the grasp, while the disks are mounted with an angle of attack, and their the axes are inclined to the plane of the earth’s surface, which is close to horizontal, at an acute angle so that the convex side is turned to the earth’s surface, while in each successive row the disks are displaced in the transverse direction flax of the disks of the previous row by Δ equal to the quotient of dividing the inter-disk distance by the number of rows, moreover, in each row, one half of the disks is installed in one direction and the other half in the opposite direction, i.e. with concave or convex sides, respectively, in the opposite direction, it is proposed that the disks of each subsequent row be installed in the opposite direction relative to the disks of the previous row, while the centers of distance between the nearest disks of the same row located in the opposite direction are shifted by Δ from row to row. The proposed disk tillage device may contain leveling working bodies of the rotational type. In this case, the leveling working bodies of the rotary type can be made with the possibility of moving the soil along a path trailing along the longitudinal axis of the working body so that the soil moves in opposite directions from the longitudinal axis of symmetry of the device.

Description

The utility model relates to agricultural machinery, in particular, to tillage devices designed for tillage after harvesting thick-stalked row crops, for stubble cultivation, for loosening and preparing the soil for sowing, destruction of weeds and grinding of crop residues, and can also be used for primary processing old arable land and heavy soddy soils.

Known garden disk two-track harrow according to the USSR copyright certificate for the invention No. 1491357, АВВ 21/08, priority 23.03.87. The garden disk two-track harrow contains a frame, a linkage mechanism, an articulated parallelogram of the displacement mechanism, and two rows of sections of disk working bodies, each of which has a rotation axis. The axis of rotation of each disk of the next row is offset from the axis of rotation of the previous row by half the distance between adjacent disks in the row. Disks of the first row are installed in one direction, and disks of the second row are in the opposite direction and have an adjustable angle of attack. The discs are mounted at an angle of 90 ° to the surface of the earth.

The disadvantage of this garden disk two-track harrow is the low quality of the soil. Firstly, since the discs are installed at an angle of 90 ° to the surface of the earth, they cannot produce a turnover of the formation and mixing of the treated soil layer, as a result of which the quality of the soil treatment is impaired. Secondly, during the operation of this garden disc harrow in each row, all discs are affected by soil resistance forces directed opposite to the working (concave) surface of the discs. Since the disks of the first row are installed in one direction, and the disks of the second row in the opposite direction, the soil resistance forces acting in the horizontal plane on all disks of each of these rows are directed in opposite directions. The second row of discs is located at a greater distance from the connection point with the traction means than the first row, i.e. has a larger shoulder. In this regard, the total moment of the transverse forces acting on the disks of the second row relative to the connection point with the traction means is greater than the total moment of the transverse forces acting on the disks of the first row. The difference in moments resulting from this leads to a displacement of the discs of the harrow in the transverse direction, either left or right relative to the direction of movement, as a result, the discs of the next row are displaced into the recesses formed after processing the land strips

the previous row of discs, resulting in areas of uncultivated land. All this leads to a deterioration in the quality of tillage.

Known disk tillage implement according to the patent of the Russian Federation for invention No. 2185044, АВВ 21/08, priority 2000.07.04, containing a frame with transverse bars fixed to it in several rows. On the transverse bars, vertical posts are mounted with axes at the ends and spherical disks mounted on the axles with the possibility of rotation. The disks have an adjustable angle of attack and are located frontally along the working width, in addition, the disks on the first and second bars are installed with the concave or convex sides respectively in opposite directions and form the first pair of disks. In subsequent adjacent paired rows, the disks are mounted respectively opposite to the disks of the first paired row. Each subsequent disk is displaced in the transverse direction relative to the previous disk in the direction of the first row of disks of the inter-disk strip of land by an amount equal to the quotient of dividing the inter-disk distance by the number of rows, while the disks are inclined to a vertical plane.

This implement compares favorably with the harrow described above in that the discs are tilted to a vertical plane, however, the quality of the tillage remains not high enough. This drawback is due to the fact that in the first pair of rows the disks on the first and second bars are installed with concave or convex sides, respectively, in opposite directions and at different distances to the point of connection of the implement with the traction means, i.e. the transverse forces of soil resistance acting on the disks of the second beam have a larger shoulder than the transverse forces acting on the disks of the first beam, so the moment of the transverse forces of the second beam will be greater than the moment of the transverse forces of the first beam, and will have the opposite sign. As in the disk harrow described earlier, a difference in the moments of forces in the horizontal plane occurs, which leads to the displacement of the gun in the transverse direction to the left or to the right, i.e. straightness of movement is violated. The next adjacent pair of discs, which are respectively installed opposite to the discs of the first pair of discs, does not eliminate the imbalance that is why, after processing with this tool, sections of uncultivated soil remain on the soil surface, and wide furrows and earth shafts form. The surface of the cultivated land is combed, uneven, with the content of crushed clods of land and plant debris, which significantly reduces the quality of the soil treatment. In addition, discs are the only working bodies on this

implements and play the role of plowshares (dumps), and since additional loosening is not performed, the quality of the tillage remains low.

Also known is a disk tillage aggregate according to the RF patent for utility model No. 58282, АВВ 21/08, priority 06.07.2006, containing a frame with longitudinal and transverse beams adapted for connecting to the traction means. Racks with convex-concave disks mounted for rotation are mounted frontally on the frame bars frontally over the entire width of the grip, while the disks are mounted with the possibility of adjusting the angle of attack, and their axes are inclined to the plane of the earth’s surface, which is close to horizontal , at an acute angle so that the convex side is turned to the surface of the earth. In each subsequent row, the disks are shifted in the transverse direction relative to the disks of the previous row by an amount equal to the quotient of dividing the inter-disc distance by the number of rows. In the first pair of rows, the disks of the first row are installed in one direction, and the disks of the second row in the opposite direction, i.e. concave or convex sides respectively in opposite directions. In the disks following the first pair of rows, the disks are set respectively in the same direction as in the first pair of rows, and the angle of attack of the disks in the rows following the first pair of rows is larger than the angle of attack of the disks of the first pair of rows. Also, the unit additionally contains leveling working bodies of a rotary type, which are made in the form of rollers or roller modules, including at least two sequentially mounted rollers, the working elements of one of the rollers being made of a loosening type and the other of a leveling type.

Unlike the implements described above, in this disk tillage aggregate in the subsequent subsequent to the first pair of rows the discs are respectively installed in the same direction as in the first pair of rows and, as a result, spend less energy on processing narrow stripes of land. Reducing the load on the disks of the second pair row creates the prerequisites for increasing the angle of attack of these disks. An increase in the angle of attack of the disks in the rows following the first pair of rows contributes to a more complete cutting of plant residues, provides a more even bottom profile of the treated soil. However, in the same way as in the above-described inventions, when paired rows of all the disks of the first row in the same direction, and the disks of the second row in the opposite direction, i.e. concave or convex sides, respectively, in opposite directions, creates a difference in the moments of soil resistance forces in the horizontal plane. This leads to a violation of the linearity of motion, i.e. the unit moves across the field, deviating from one course,

then to the other side, as a result, disks of the next row are shifted to the recesses formed after processing the stripes of land by the previous row, i.e. occupy a more favorable position for work, requiring less energy. Displacement of the disks in the transverse direction from row to row in the final result leads to uneven tillage, i.e. after passing through this aggregate, there remain areas of uncultivated monolithic soil, the surface of the soil is ridge, so the disadvantage of this disk aggregate is uneven and poor-quality tillage. The additional leveling working bodies of the rotary type installed on the unit, which are made in the form of rollers with working elements of a cultivating or leveling type, do not sufficiently level the comb surface of the soil treated with disks, therefore the quality of the land cultivation as a whole decreases.

Also known disk tillage implement according to the patent of the Russian Federation for the invention No. 2291605, АВВ 21/08, priority 2005.10.17, selected as the closest analogue. The disk tillage implement contains a frame with transverse bars fixed to it in several rows, on which vertical posts with axles at the ends are mounted, and spherical disks mounted on the axles with the possibility of rotation. The disks have an angle of attack, are inclined to the vertical plane and are installed frontally along the width of the capture in rows, in which each subsequent disk is displaced in the transverse direction relative to the previous one towards the untreated first row of disks of the interdisk strip of the earth. The disks in the rows are directed by the convexity or concavity to the longitudinal axis of symmetry of the implement in such a way that the number of disks in each row of one direction on one side of the axis of symmetry is equal to the number of disks in the opposite direction of its other side. Also, between the disks of the first row of guns along the line of its longitudinal axis of symmetry, a plane-cutting paw with a working width equal to the interdisk gap of the middle disks of the last row was installed.

This disk tillage implement on the one hand compares favorably with the one described above in that when the disks in rows are convex or concave to the longitudinal axis of symmetry of the implement in such a way that the number of disks in each row of one direction on one side of the symmetry axis is equal to the number of disks in the opposite direction of its other hand, the equality of soil resistance forces in the horizontal plane and their moments acting on the disks of the gun. As a result, one of the reasons for poor quality

tillage, namely a violation of the linearity of movement, i.e. deviation of the gun from the course to the left, then to the right, is eliminated.

However, on the other hand, the quality of tillage remains unsatisfactory due to the following. The poor quality of soil cultivation is due to the uneven distribution of the cultivated soil over the surface due to the fact that in each row one half of the discs is installed in one direction to the axis of symmetry, and the other half in the opposite direction, i.e. concave or convex sides to the longitudinal axis of symmetry of the gun, while the centers of distance between the nearest disks of the same row, located in the opposite direction, are located on the same line - the longitudinal axis of symmetry. Due to the fact that in each subsequent row, the disks are directed in the same direction as in the previous row, i.e. all disk working bodies of the implement are set to be slit or slid to the longitudinal axis of symmetry (depending on how the disks in the rows are directed by the convexity or concavity to the longitudinal axis of symmetry of the implement), this leads to the fact that the cultivated soil will recline all the time in one direction (to the center, or from the center, i.e. to shift either to the axis of symmetry, or from the axis of symmetry), therefore, in the central part will form a ridge or groove, which leads to an uneven distribution of the treated soil along erhnosti and degrades the quality of soil treatment.

In addition, the centers of distance between the closest, opposite, discs of the same row are located on the same axial line from row to row, which leads to the presence of an untreated soil in the central part, which means a decrease in the quality of processing in the central part. The presence of a plane-cutting paw between the disks of the first row of the implement along the line of its longitudinal axis of symmetry, provided for processing the central portion of the soil untreated with the disks, does not give the desired result, and the quality of the tillage remains low due to the following. The flat-cutting, or otherwise hollow, paw used in this case is mainly intended for cutting weed vegetation at a shallow depth and produces a slight displacement of the soil, so the untreated central part of the soil will be cut and loosen to a shallow depth (4 ... 6 cm). Also a characteristic feature of flat-cutting paws is a small crumbling angle (9 ... 10 °), as a result of which the crumbling of the soil is practically reduced to zero. Therefore, the treated soil in this area will be uneven, with the content of unshredded clods of soil, while some of the plants, as the blade of the paw is dull, may not be cut, but torn out and will be

envelop the blades or lie on the surface uncrushed, which reduces the quality of tillage.

It should be borne in mind that the flat-cutting leg is intended for one type of tillage, for example, cultivation, i.e. for cutting weeds to a depth of till 6 cm, and discs for another type of tillage, for example, disking, harrowing, i.e. play the role of a ploughshare (dump) - they turn a layer of land, crumble and loosen the soil, more fully cut and shred plant residues. As a result of this, the tillage will be heterogeneous and uneven in width and depth, the surface of the cultivated land will be ridged, uneven, with the content of crushed clods of land and plant debris, which affects the quality of the tillage.

Since there are no additional leveling working bodies of the rotational type - rollers and further cultivation are not performed, the quality of the soil treatment will be low.

The objective of the proposed technical solution is to improve the quality of tillage due to the uniform distribution of the cultivated soil across the width and depth, as well as increasing the uniformity of the structure.

The essence of the utility model lies in the fact that in a disk tillage device containing a frame with transverse bars, on which racks with convex-concave disks mounted for rotation are fixed frontally over the entire working width, forming rows, the disks are mounted with an angle attacks, and their axes are inclined to the plane of the earth’s surface, which is close to horizontal, at an acute angle so that the convex side is turned to the earth’s surface, while in each subsequent row the disks are displaced in the transverse the direction relative to the disks of the previous row by Δ equal to the quotient of dividing the inter-disc distance by the number of rows, moreover, in each row, one half of the disks is installed in one direction and the other half in the opposite direction, i.e. with the concave or convex sides, respectively, in the opposite direction, it is proposed that the disks of each subsequent row be installed in the opposite direction relative to the disks of the previous row, while the centers of distance between the nearest disks of the same row located in the opposite direction are shifted by Δ from row to row.

The proposed disk tillage device may contain leveling working bodies of the rotational type. Moreover, the leveling working bodies of the rotary type can be made with the possibility of moving the soil

along a trajectory twisting along the longitudinal axis of the working body so that the soil moves in opposite directions from the longitudinal axis of symmetry of the device.

The leveling working bodies of the rotary type can be made in the form of cylindrical screw rollers.

The leveling working bodies of the rotational type can also be made in the form of rollers with spiral winding so that the spiral of circular cross section is wound around the supporting frame of a cylindrical shape and is fixed on it.

In the proposed disk tillage device, the arrangement of the disks is convex-concave in such a way that in each subsequent row they are installed in the opposite direction relative to the disks of the previous row, while the centers of distance between the nearest disks of the same row located in the opposite direction are shifted by Δ from row to row, provides improved soil cultivation due to the following.

Due to the fact that in each subsequent row, the discs are directed in the opposite direction relative to the discs of the previous row, the cultivated soil will recline alternately from row to row either to the center or from the center, therefore, it will be distributed evenly without the formation of a central dump crest or excavation, which improves the quality of tillage.

In addition, the centers of the distance between the nearest, opposite, discs of the same row are shifted by Δ from row to row, which leads to an increase in the quality of processing the soil in the central part of the working width. As a result of this, the tillage will be uniform and uniform in width and depth, the surface of the cultivated land will be flat without pile ridges with evenly crushed lumps of soil and plant debris, which improves the quality of the tillage.

The presence of additional leveling working bodies of the rotational type - rollers, made with the possibility of moving soil along a trajectory twisting along the longitudinal axis of the working body so that the soil moves in opposite directions from the longitudinal axis of symmetry of the device, improves the quality of soil treatment by moving the treated soil from the ridges to recesses evenly over the entire width of the grip along a twisting path, thereby eliminating combing (uniform alternation of ridges and recesses), o spherical disks formed during the operation and, therefore, leveling the surface of the treated soil. Also improving the quality of tillage

it is provided due to additional crumbling of the lumps remaining after the discs, combing and grinding of weeds cut by the discs.

The use in the soil tillage device of leveling rotary working elements made in the form of cylindrical screw rollers provides high-quality crumbling of soil lumps and grinding of weeds cut by disks, while the turns of screw rollers shift the soil from ridges to furrows, the soil surface is leveled, which improves the quality of processing the soil.

The use in the inventive device of leveling working bodies of the rotary type, made in the form of rollers with spiral winding so that the round spiral is wound around the supporting frame of a cylindrical shape and fixed on it, improves the quality of the soil treatment by increasing the degree of grinding of the lumps and leveling the soil while simplification of the manufacturing process of this type of roller with spiral winding.

Figure 1 shows the inventive disk tillage device, top view. Figure 2 shows a disk tillage device, side view. Figure 3 shows a fragment of the arrangement of disks of a convex-concave shape of the inventive device. Figure 4 shows the leveling working body of the rotational type - a helical roller of a cylindrical type. Figure 5 shows a view In figure 4. Figure 6 shows the leveling working body of the rotational type - a roller with spiral winding. In Fig.7 shows a view of Fig.6.

The disk tillage device (FIGS. 1, 2) comprises a frame 1 adapted to be attached to the towing means (not shown in the figures), which is made of transverse beams 2 connected to one another. On the transverse beams 2, they are mounted frontally along the entire working width, forming rows, racks 3, on which are mounted with an angle of attack and with the possibility of rotation, spherical disks 4 of a convex-concave shape, which are the main working bodies. The disks 4 are mounted on the axes 5 located at the lower ends of the uprights 3. The axes 5 are inclined to the horizontal plane of the earth's surface at an acute angle so that the convex side of the disks 4 is turned towards the earth's surface.

On the frame 1 installed leveling working bodies of the rotational type in the form of rollers 6.

In each subsequent row, as shown in FIG. 3, the disks 4 are displaced in the transverse direction relative to the disks 4 of the previous row by

Δ equal to the quotient of dividing the inter-disk distance l by the number of rows, moreover, in each row, one half of the disks 4 is installed in one direction and the other half in the opposite direction, i.e. concave or convex sides, respectively, in the opposite direction.

Also, the disks 4 of each subsequent row are installed in the opposite direction relative to the disks 4 of the previous row, while the centers A1, A2, A3 and A4 of the distance between the closest opposing disks 4 of the first to fourth rows are respectively displaced by A from the row to the row.

Figure 4 shows an embodiment of the roller 6 in the form of a helical cylindrical roller with right winding, which can be used on the right side of the disk tillage device. The helical cylindrical roller contains a pipe 7, to which, using rods 8, a strip 9 curved by a screw is made of strip steel. The pipe 7 is mounted on the axles 10 with the possibility of rotation.

Figure 6 shows an embodiment of the roller 6 in the form of a roller with spiral winding, which can be used in the Central part of the disk tillage device. The roller with spiral winding contains a supporting cylindrical frame 11 mounted on the axles 12 with the possibility of rotation and two spirals - a spiral 13 with a right winding, and a spiral 14 with a left winding. Spirals 13 and 14 are wound around a supporting frame 11 of a cylindrical shape, which is made of straight tubular elements 15 located parallel to each other along a generatrix of a cylindrical frame 11 between the disks 16. The turns of the spirals 13 and 14 are firmly fixed to the supporting frame 11. The cross-section of the spiral is round.

The operation of the device we consider on the example of a disk tillage device with three screw rollers 6 (figure 1).

The main working bodies of the device are spherical disks 4 of a convex-concave shape.

When the disk device moves forward, due to the fact that the disks 4 are mounted in rows along the working width, they have an optimal angle of attack, for example, 20 °, and their 5 axes are inclined to the plane of the earth’s surface at an acute angle, for example, 15 ° so that the convex side is turned to the surface of the earth, disks 4 rotating while the unit is moving, cut the soil layer with plant and crop residues and crumble them. Curly cuts along the cutting edge in the discs 4 improve the crushing of the earth, as well as cutting and ejecting plant debris on the soil surface.

Due to the fact that in each row, one half of the disks 4 is installed in one direction, and the other half in the opposite direction, i.e. with the concave or convex sides, respectively, in the opposite direction, the equality of the soil resistance forces acting on the disks of the implement in the horizontal plane and their moments relative to the connection point of the device with the traction means (not shown) is observed. Due to this, the disk device will not deviate from the course either left or right, i.e. straightness of movement will be observed.

Since in each subsequent row, the disks 4 are displaced in the transverse direction relative to the disks 4 of the previous row by a value Δ equal to the quotient of dividing the inter-disk distance by the number of rows, and the centers A1, A2, A3 and A4 of the distance between the nearest ones located in the opposite direction , the disks 4 are also shifted by the same value Δ from row to row, while the disks 4 of each subsequent row change the working direction relative to the disks 4 of the previous row, i.e. installed in the opposite direction, then during the operation of the device, disks 4 will cut off monolithic land strips and tilt the treated soil alternately from row to row either to the center or from the center, therefore, the treated soil will be evenly distributed without the formation of a central dump crest or excavation, which improves the quality of the field surface after the passage of the disk device. At the same time, the disks 4 are actively mixed, high-quality crushed soil and trimmed weeds in depth and width of capture. As a result of this, together with the straightforward movement of the disk tillage device, the tillage will be uniform and uniform in width and depth, including the central part, which improves the quality of the tillage.

The leveling working bodies of the rotational type - rollers 6 improve the quality of the soil treatment due to their additional grinding of lumps of the cultivated soil and 4 weeds cut by the discs, as well as by leveling the surface of the treated soil. Rollers 6 are installed in a row across the width of the grip. The number of rollers 6 depends on the width of the device. Three - the optimal number of rollers 6 for wide-angle devices, as shown in figure 1. The central roller 6 is made with left and right coils, the left roller 6 with left coils, and the right roller 6 with right coils.

When the rollers 6 are moved across the soil, each turn of the strip 9, which is made of strip steel with left or right winding, will cut into the soil with its edge and move the soil from the ridges into grooves along a helical path, due to this the field surface will be leveled. Additional crumbling occurs at the same time.

lumps of soil, combing, grinding weeds and throwing them to the surface of the soil. A mulching layer forms on the surface of the soil. Due to the fact that the helical strip 9 is attached to the pipe 7 with the help of rods 8, the possibility of jamming of plant debris and soil lumps between the turns of the helical strip 9 is excluded, the quality of soil cultivation is improved.

However, the embodiment of the roller 6 in the form of a helical cylindrical roller with all its advantages is technologically complex and laborious to manufacture. Therefore, if it is necessary to reduce labor costs, a more technologically advanced embodiment of the roller 6 is used in the form of a roller with spiral winding.

The roller with spiral winding, shown in Fig.6, operates as follows.

When the disk tillage machine moves across the field, the rollers 6 rotate on the half shafts 12. Tubular elements 15 installed between the disks 16, the rollers 6 break up large lumps of soil, while the spirals 13 with the right winding and the spirals 14 with the left winding move the soil from the ridges to the furrows, formed on the surface of the field after processing it with spherical discs 4. At the same time, additional spiral crumbling of 13 and 14 soil lumps occurs, combing, grinding 4 weeds cut by the discs and throwing them over rhnost soil to form a mulch layer. Therefore, the use of rollers 6 in the form of rollers with spiral winding in the disk tillage device allows to improve the quality of the soil treatment by increasing the degree of grinding of lumps and 4 weeds cut by the disks, leveling the surface of the treated field.

Both helical cylindrical rollers and the embodiment of the rollers with spiral winding provide soil movement in different directions from the longitudinal axis of symmetry of the device due to the fact that the spiral winding is made with the ability to move soil in the transverse direction along a twisting path in opposite directions relative to the longitudinal axis of symmetry of the device .

Thus, the inventive disk tillage device provides high quality tillage due to the uniform distribution of the cultivated soil across the width and depth, increasing the uniformity of the structure of the treated soil, improving the quality of crumbling lumps and grinding weeds and crop residues, as well as by leveling the surface of the soil.

Claims (5)

1. A disk tillage device comprising a frame with transverse beams on which racks with convex-concave disks mounted for rotation are mounted frontally over the entire working width, forming disks, while the disks are mounted with an angle of attack and their axes are inclined towards a plane of the earth’s surface, which is close to horizontal, at an acute angle so that the convex side is turned to the earth’s surface, while in each subsequent row the disks are displaced in the transverse direction relative to the disks of the previous row and by Δ equal to the quotient of dividing the inter-disk distance by the number of rows, moreover, in each row, one half of the disks is installed in one direction and the other half in the opposite direction, i.e. the concave or convex sides, respectively, in the opposite direction, characterized in that the disks of each subsequent row are mounted in the opposite direction relative to the disks of the previous row, and the distance centers between the nearest disks of the same row located in the opposite direction are shifted by Δ from row to row. 2. The disk tillage device according to claim 1, characterized in that it further comprises leveling working bodies of a rotational type. 3. The disk tillage device according to claim 2, characterized in that the leveling working bodies of the rotary type are arranged to move the soil along a path trailing along the longitudinal axis of the working body so that the soil moves in opposite directions from the longitudinal axis of symmetry of the device. 4. The disk tillage device according to claim 3, characterized in that the leveling working bodies of the rotary type are made in the form of cylindrical screw rollers. 5. The disk tillage device according to claim 3, characterized in that the leveling working bodies of the rotary type are made in the form of rollers with spiral winding so that the spiral of circular cross section is wound around the supporting frame of a cylindrical shape and is fixed on it.