RU80089U1 - DISC OF THE WORKING BODY OF SOIL PROCESSING TOOLS (OPTIONS) - Google Patents

Abstract

A disc for a tillage implement is proposed that is curved in a sphere and equipped with a bearing assembly with a stand. The authors believe that the disk is made combined with different profiles of the spherical surfaces of the external (external) and internal parts of the disk to improve the turnover of the soil layer and its crumbling during the rotation, moreover, the combination of geometrically different surfaces is represented by the options for the execution of the disk. First option. A spherical disk as part of the working body of a tillage implement with a removable ring of a curved triangle (in cross section) of the profile mounted on the clamps on the inside of the disk, and the ring may be part of the disk or flange. The ring in conjunction with the inner surface of the disk sphere provides a new surface, which is an annular curved groove around the bearing assembly. The second option is a variation of the first and, in this case, the curved surface forming an annular curved groove around the bearing assembly is ensured due to the fact that the ring of the curved profile is integral with the flange of the disk hub and forms the configuration of the inner sphere of the disk. The third option. Inside the disk sphere, a cone-shaped part is placed along its axis, the cone of which smoothly curves along the curve with the inner surface of the disk, the conical part of the disk can be a removable or integral part of the disk. In this case, the bearing assembly is placed on the outer convex side of the disk. And in this case, a new surface is also formed inside the disk sphere in the form of an annular curvilinear groove in the zone of the central part of the disk. The fourth option is a working body with a flat disk instead of a spherical one, and the central part around the bearing assembly is either in the form of a replaceable curved ring (as in the first option), or it can be made integral with the hub flange (as in the second option). The fifth option. The inner (working) surface of the disk has a variable curvature, and the peripheral part of the sphere at the site of deepening the disk into the soil is made over a larger radius, the inner

the part has a smaller radius, and the central part has a flat bottom for mounting and fixing the bearing assembly. The disk is made integral, for example, by stamping, and does not have additional inserts for changing the surface curvature. The technical result is an improvement in the quality of tillage, achieved by increasing the turnover and deformation of the soil layer moving along a sphere with greater curvature, which improves the crumbling of the soil and reduces its rejection. The invention is industrially applicable. It can be implemented in a factory or other industrial enterprise. 5 ill.

Description

The present invention relates to machine technologies of tillage, where spherical discs are used in tillage implements.

Tillage tools with spherical discs are used in the main processing, harrowing, tinning and other tillage.

Spherical disks in such implements are mounted in rows frontally to the direction of the working movement of the implements, have an angle of attack and an angle of inclination to the vertical plane and can be installed both on individual stands on bearings and on a common shaft battery.

A disk with a stand and a bearing constitutes a working body.

Spherical notched and not-cut circular discs are known. (See the book. "Disk tillage machines." Auth. V.F. Strelbitsky. M. "Mechanical Engineering", 1978, p. 3, Fig. 2, 3).

The disadvantage of such disks is that the radius of the sphere of the disk is larger than the diameter of the disk. With this ratio of the radius of the sphere to the diameter of the disk, the disk wraps poorly and crumbles the soil layer it processes. The soil is poorly shredded, it is widely scattered in the direction of rotation and on the sides. All this affects the quality of tillage.

Known cut disk for tillage tools (see US Pat. RF. Model No. 466620, A01B 7/00 of 03/04/2006) with a diameter of 560 mm and a sphere radius of 635 mm.

Its disadvantage is the small curvature, that is, a large radius of the sphere, which is larger than the diameter of the disk. Such a disk unsatisfactorily wraps the formation during operation, poorly crumbles the soil, and discards this poorly shredded soil from itself. All this reduces the quality of tillage.

The disk described above, in conjunction with the bearing assembly and stand, forms the working body of the tillage implement (see Pat. RF for floor model No. 57073, A01B 21/00 of 09.03.2006) - prototype.

The working body contains a rack on which a bearing assembly with the axis of the disk is attached and a spherical disk, the radius of the sphere of which

also larger than the diameter of the disc.

The disadvantage is that the disc of the working body wraps poorly and crumbles the layer. The rotation of the formation is additionally hindered by a bearing assembly allowed inside the disk sphere to which the disk rack is attached. The disk rotates on the axis of the bearing assembly.

The technical result of the invention is to improve the quality of tillage, achieved due to better turnover of the formation and crumbling of the soil disks of the working body of the tillage implement.

The specified technical result is achieved by the fact that the disk is made combined with different profiles of the surfaces of the external (external) and internal parts of the disk.

The combination of geometrically different surfaces is represented by disc options.

In more detail, the invention will be described below.

Figure 1 shows a spherical disk as part of the working body of a tillage implement.

Figure 2 shows a spherical disk with a stand and a bearing assembly, the axis of which has a flange forming the configuration of the inner sphere of the disk.

Figure 3 shows a spherical disk with a bearing assembly and a strut located on the outer surface of the disk sphere.

Figure 4 shows a disk whose outer surface is flat and the inner surface is curved.

Figure 5 shows a disk made of sheet material, the surface of which has a variable curvature, moreover, the peripheral part of the sphere at the site of the disk deepening into the soil is made over a larger radius, the inner part has a smaller radius, and the central part of the disk has a flat bottom and holes for mounting and mounting the bearing assembly.

The working body of figure 1 consists of a rack 1, which is rigidly connected about the housing 2 of the bearing assembly, which, in turn, consists of a hub 3 with a flange 4. On the hub 3 are angular contact bearings 5 and 6, fixed relative to the housing 2 and hubs 3, washer 7 and nut 8, with a stopper 9 and closed by a cover 10. The front bearing 5 is sealed by a sleeve 11. A spherical disk 13 is attached to the flange 4 on the bolts 12. A replaceable ring of a curved triangular profile is mounted on the latches 14 on the latches 14 15. Ring 15 may I pour in

part of the disk 13 or the flange 4. The fixation of the ring 15 on the disk 13 can be performed using glue, welding or other means. The ring 15, in conjunction with the inner surface of the sphere of the disk 13, provides a new surface, which is an annular curved groove around the bearing assembly. This annular groove, depending on the height of the ring 15 and the originality of the surface curvature (lekalnogo or made in radius, see figure 1) in conjunction with the surface of the disk 13 provides a new trajectory of the formation and increase the degree of crumbling of the soil. As an embodiment, the ring 15 can be made together with the flange 4 of the hub 3 (see figure 2) and form the configuration of the inner sphere of the disk (see figure 2).

The disk 13 of the working body of figure 3 has a spherical outer surface 16 and an inner cone-shaped part 17, which may also be removable or be an integral part of the disk 13.

Figure 4 presents the disk, which on the outer surface is made flat, and on the inner surface, as in figure 1, is equipped with a ring 15, made removable or together with the disk 13, and its curvature determines the rotation and crumbling of the reservoir.

Figure 5 presents the working body, consisting of a disk 13 made of sheet material, the surface of which has a variable curvature, moreover, the peripheral part of the sphere at the site of deepening the disk into the soil (ℓ ₁ ) is made over a larger radius R ₁ , the inner part ℓ ₂ a smaller radius R ₂ , and the Central part ℓ _{3 of the} disk 13 has a flat bottom 18 and a hole 19 for mounting the bearing assembly and a hole 20 for mounting the disk 13 to the flange of the hub 3.

The disk of the working body of the tillage tool works as follows. Option 1 (see figure 1).

A tillage implement, for example, a harrow with spherical disks mounted on posts 1, rows frontally, is moved by a tractor along the field in the operating mode of tillage. The tractor and harrow are not shown in figure 1. Through the rack 1, which is mounted on the frame of the harrow, the disk 13 is given an angle of attack (the angle between the direction of movement of the harrow and the plane of the spherical disk). The angle of inclination of the disk 13 to the vertical plane (Fig. 1 angle β) is set during the design of the working body. Stand 1, through the housing 2 of the bearing assembly, bearings 5 and 6, which are located on the hub 3, allows the harrow to rotate in the field to rotate

the disk 13. The disk 13 with bolts 12 is rigidly attached to the flange 4 of the hub 3.

Disc 13, cutting the soil, due to its rotation, angle of attack and angle β, feeds the soil up the inner sphere of the disk. Due to the sphericity of the inner surface of the disk, the soil turns around in a sphere and crumbles when deformed, and in this form falls onto the soil surface. A furrow forms behind the disc in the soil. The sleeve 11 and the cover 9 prevent dust from entering the bearing assembly.

The larger the radius of the sphere, the less curvature of the disk and less deformation of the soil when it moves along the surface of the disk, and the soil is more strongly discarded by the disk due to centrifugal force. Such tillage will be of poor quality. To avoid this phenomenon, a ring 15, for example, of a curved triangular profile, which, in conjunction with the disk 13, provides a new surface, which is an annular curved groove, inside which the bearing assembly is placed, is mounted on the clamps 14 on the inner surface of the disk 13. The curvature of this gutter can be any, depending on the conditions of tillage. The soil layer receives a new shorter trajectory of movement and, therefore, is easier to turn around and crumble faster, with some twisting, which makes the spread of soil less intense. All this improves the quality of tillage, that is, ensures the achievement of a technical result.

The advantage of this variant of the disk is provided by the fact that the ring 15 is interchangeable. You can put rings of different sizes, different configurations and different materials, including polymer, which has a low coefficient of friction on the soil, which will reduce the energy consumption of the process.

The operation of the disk according to option 2 (see FIG. 2) is characterized in that the ring 15 (see FIG. 1) is made in conjunction with the flange 4 of the hub 3. This simplifies the manufacture of the disk 13, since the need to install latches 14 disappears. The need also disappears manufacturing the latches themselves 14. There is a simplification of the design of the disk. In this case, you can use the serial disk without its development. This simplification of the design, while achieving a technical result, makes option 2 preferred and promising.

The operation of the disk according to option 3 (see FIG. 3) is characterized in that the bearing assembly 2 with the strut 1 is placed on the outside of the surface of the sphere 16 of the disk 13. Inside the disk 13, a cone-shaped part 17 is placed along its axis, the cone of which is smooth along the curved line

mates with the inner surface of the disk 13. Part 17 may also be removable or be an integral part of the disk 13.

The advantage of this option is that the bearing assembly does not interfere with the turnover of the formation, due to the fact that it is placed on the outside of the disk 13, therefore, such a disk can be deeper into the soil than expanding its functionality, ensuring the achievement of a technical result.

The work of the disk according to option 4 (see figure 4) is characterized in that the disk 13 is made flat. It is known that the contact area of the spherical disk on the outer surface of the sphere with the soil, taking into account the angle β (see Fig. 1), is larger than that of a flat disk, therefore, the spherical disk is worse buried in the soil and has greater soil resistance during operation. The elimination of this drawback reduces the energy consumption of the process with better burial of the disk, that is, it is possible to reduce the weight of the harrow, its metal consumption, which simplifies and cheapens its manufacture, while achieving a technical result.

The operation of the disk according to option 5 (see FIG. 5) is characterized in that the bearing assembly 2 with the rack 1 can be placed both on the inside of the sphere 16 and on the outside of the disk 13, and the spherical surface of the disk has a variable curvature increasing from disc edges, i.e. from its peripheral part, to the center. This is achieved by the fact that along the edge of the disk, at the site of its deepening into the soil (ℓ ₁ ), the radius of the sphere of the disk R ₁ is large, i.e. less curvature, and then to the center passes into a spherical surface with a smaller radius of the sphere R _2, i.e. with greater curvature in the area ℓ ₂ . The central part of the disk 18 is made flat (section ℓ ₃ ) and has a hole 19 for mounting the bearing assembly and a hole 20 for mounting the disk 13 to the flange of the hub 3.

The advantage of such a disk is that it is made integral, for example, by stamping and does not have additional inserts to change the surface curvature. The deepening section (ℓ ₁ ) is made with a small curvature, which contributes to its better deepening, and further to the center of the disk, its curvature increases, which helps to increase the turnover and deformation of the soil layer moving along the disk sphere, and, therefore, improve its crumbling. The rejection of soil up and to the side in this case is minimal. Energy costs for dropping soil are reduced, and the efficiency of crumbling is increased. In addition, bearing

the node with the housing 2 and the rack 1 can be installed both on the inner side of the disk 13, and on the outside, and the presence of a flat bottom of the disk allows you to simplify the manufacture of the hub 3, because its plane of attachment to the disk will be flat, i.e. simpler, which reduces the cost of its manufacture.

Thus, the proposed options for the disk of the working body of the tillage implement, ensuring the achievement of a technical result, have individual advantages over each other.

The invention is industrially applicable.

It can be implemented in a factory or other industrial enterprise, as well as workshops with the necessary machine park.

Claims (5)

1. The disk of the working body of the tillage implement, curved around the sphere, equipped with a bearing assembly with a stand, characterized in that the spherical disk from the inside on the axis of symmetry of the bearing assembly and around it is equipped with a ring that decreases in thickness from the hole to the periphery and smoothly mates with the inside the surface of the disk, forming with it an annular curvilinear groove of an arcuate cross-section. 2. The disk of the working body of the tillage implement, curved around the sphere, equipped with a bearing assembly with a stand, characterized in that the flange of the axis of the bearing assembly, rigidly connected to the inner surface of the disk, is made with decreasing thickness to the periphery and forms an annular curved transverse arcuate trough with the disk surface sections. 3. The disk of the working body of the tillage implement, curved around the sphere, equipped with a bearing assembly and a stand, characterized in that the disk on the inside of the sphere is equipped with a cone-shaped part mating with the surface of the disk and forms an annular curved trough with an arcuate cross-section and a bearing assembly with a stand made on the outside of the disk. 4. The disk of the working body of the tillage implement, curved in a sphere, equipped with a bearing assembly and stand, characterized in that the outer surface of the disk is made along a radius of infinite curvature, that is, flat, and the inner surface from the flat periphery passes in an arc towards the center in a circular curvilinear surface. 5. The disk of the working body of the tillage implement, curved around the sphere, equipped with a bearing assembly and stand, characterized in that the inner spherical surface of the disk is made with a variable curvature of the sphere increasing from the edge of the disk to its center, and the central part along the diameter of the bearing assembly is flat and has holes for its installation and fastening.