RU124521U1 - HARROW DISC - Google Patents

Abstract

1. Disc harrow, containing a frame with aggregation and transportation elements, on which in three rows, at an angle of attack to the direction of movement, spherical disks are fixed, characterized in that left and right-hand spherical disks are mounted on each row, while the spherical disks of the first and the second rows are oriented by concavities from the longitudinal axis of the harrow, and the spherical discs of the third row are oriented by concavities to the longitudinal axis of the harrow. 2. Disk harrow according to claim 1, characterized in that the spherical disks can be typed into the batteries of disk working bodies. The disk harrow according to claim 1, characterized in that the spherical disks can be mounted obliquely to the horizontal with the possibility of vertical movement on individual racks, which are pivotally mounted on the supporting beams of the frame. Disk harrow according to claim 1, characterized in that between the concavities of adjacent spherical disks of the third row additional loosening elements are installed. Disk harrow according to claim 1, characterized in that the supporting and transport wheels are installed between the second and third rows of disks. The disk harrow according to claim 1, characterized in that it has a roller or rollers in front and / or rear of the harrow pivotally attached by spring elements and / or levers to the harrow frame, the frame being able to rest on the roller or rollers. Disk harrow according to claim 3, characterized in that the group of working bodies in each row can synchronously change the angle of attack by moving and fixing the beam.

Description

The utility model relates to agricultural engineering and can be applied in tillage implements with disk working bodies.

The prior art disk harrow BDNT-2.2 [1] with batteries of disk working bodies located in an X-shaped symmetrical pattern (Reference designer of agricultural machines. M. vol. 2, 1967).

The advantage of the BDNT-2.2 disc harrow, as well as its analogs, with disc working bodies arranged in an X-shaped symmetrical pattern, is a stable directional stability during operation of the unit. The advantage is due to the fact that when the unit is operating, equal and multidirectional forces with respect to the unit's thrust vector act on the disk harrow. With the possible disc harrow to the side, on the leading side of the disc harrow, disk working bodies increase the angle of attack, which increases the resistance of this part of the disk working bodies. As a result of the forces, the straightness of the disk harrow [1] is restored.

The disadvantage of a disk harrow [1] is the incomplete cutting of the soil by disk working bodies. The disadvantage is due to the fact that reducing the distance between adjacent disks in a row in order to completely cover the traces of spherical disks leads to clogging of the interdisk space with plant residues and soil.

The disadvantage of disk harrows [1] with the arrangement of disk working bodies according to the X-shaped symmetrical pattern is the presence of an untreated soil strip in the junction between the right-handed and left-handed batteries. The disadvantage is due to the fact that the structurally X-shaped symmetrical scheme allows you to set the disk working bodies so that between adjacent multidirectional disk working bodies of the front row there is an untreated strip of soil.

The indicated drawback of disc harrows with disc working bodies arranged in an X-shaped symmetrical pattern is eliminated by installing additional working bodies that cut the untreated soil strip. According to RU Patent No. 94029780 [2], a solution is known where the Disk harrow has batteries of disk working bodies arranged in two rows in an X-shaped symmetrical pattern and an additional working body along the axis of symmetry of the harrow.

The technical solution of the analogue [2] eliminates the untreated strip of soil at the junction between the right-handed and left-handed batteries, but does not exclude the incomplete cutting of the soil by disk working bodies.

According to the Patent for the invention RU No. 2292695 [3], a technical solution is known where the Disk harrow contains four rows of disk working bodies, while the concavity of the disks of each subsequent row is opposite to the concavity of the disks of the previous row, with a certain displacement of the disk working bodies in subsequent rows.

The advantage of the analogue [3] is the increased distance between adjacent disk working bodies in a row, due to the arrangement of disk working bodies in four rows, with each disk of each row cutting a strip of soil with complete overlap of traces of disk working bodies.

The disadvantage of the analogue [3] is the asymmetric layout of the disk working bodies. To level the total component of the forces acting on the rows of disk working bodies, it is necessary either to consistently increase the angles of attack of disk working bodies in each subsequent row, or to increase the depth of soil cultivation by the front rows of disk working bodies in comparison with subsequent rows. Such a setting of the disk harrow [3] leads to uneven tillage along the width of the implement, which reduces the quality of the tillage.

The prototype of the claimed utility model is the technical solution according to the Utility Model Patent RU No. 99680 [4], where the disc harrow contains a frame with transverse beams on which spherical disks are arranged in three rows through individual racks. The disks are mounted on the working surface at an acute angle of attack with respect to the direction of movement, the left and right-hand disk working bodies are installed on the first row, they are mirrored, they are located relative to the longitudinal axis, and the concavity of the third row of disks is opposite to the concavity of the second row of disks.

The technical solution of the prototype [4] combines the advantages of analogues [1] and [3]. The symmetrical arrangement of the front row of disk working bodies stabilizes the directional stability of the unit, and the arrangement of disk working bodies in three rows allows to increase the inter-disk distance in a row, while each disk of each row cuts a strip of soil with complete overlap of traces of disk working bodies.

The prototype [4] is characterized in that the roller is articulated by means of spring elements and / or levers to the harrow frame, while the frame is able to rest on the roller and, by changing the position of the trailer, the depth of the soil cultivation is regulated.

The disadvantage of the prototype [4] is the adjustment of the depth of tillage using a roller. With increased soil moisture, the skating rink becomes clogged with soil and plant debris, which leads to disruption of the soil cultivation process.

The problem to which the claimed utility model is directed is to improve the quality of soil cultivation during operation of a disk harrow. In order to fulfill the task Harrow disk contains

a frame with aggregation and transportation elements, on which in three rows, at an angle of attack to the direction of movement, spherical disks are fixed, left and right-hand spherical disks are mounted on each row, while the spherical disks of the first and second rows are oriented by concavities from the longitudinal axis of the harrow, and spherical discs of the third row are oriented by concavities to the longitudinal axis of the harrow.

Between the concavities of adjacent spherical disks of the third row, additional loosening elements can be installed.

Spherical disks can be typed into the batteries of disk working bodies. Spherical disks can be mounted obliquely to the horizontal, with the possibility of vertical movement, on individual racks, which are pivotally mounted on the supporting beams of the frame. A group of working bodies on individual racks can synchronously change the angle of attack by moving and fixing the beam.

Between the second and third rows of disks installed support and transport wheels. The disk harrow has a roller (rollers) in front and / or rear of the harrow, which (which) is pivotally connected by spring elements and / or levers to the frame of the harrow, while the frame is able to lean on the roller (rollers).

The technical result of the application of the utility model is to increase the directional stability of the disc harrow, improve the quality of the soil cultivation, and the ability to adjust the depth of soil cultivation through the support wheels of the chassis.

The technical result of "increasing directional stability" is ensured by the fact that on each row there are left- and right-turning spherical disks, while the spherical disks of the first and second rows are oriented by concavities from the longitudinal axis of the harrow, and the spherical disks of the third row are oriented by concavities to the longitudinal axis of the harrow. The disk forces arising during the operation of the Harrow, aimed at shifting each spherical disk to the side, are mutually compensated by forces from symmetrically spherical disks relative to the thrust vector, which coincides with the longitudinal axis of the Harrow disk.

The technical result "improving the quality of soil cultivation" is achieved by the fact that the disc harrow has an increased directional stability, which eliminates flaws during the work of the disc harrow. In addition, additional loosening elements installed between the concavities of adjacent spherical disks of the third row exclude the formation of blemishes between the concavities of adjacent spherical disks of the third row.

The technical result "adjusting the depth of tillage by means of the support wheels of the chassis" is achieved by installing support and transport wheels between the second and third rows of discs. The support and transport wheels move along the agrophone aligned with the first and second row of spherical disks, and their track is sealed with the third row of spherical disks.

The industrial applicability of the claimed utility model is ensured by the fact that the disk harrow contains disk working bodies in the form of spherical disks mounted at an angle of attack to the direction of movement and arranged in three rows, while the spherical disks of the first and second rows are oriented with the concave side of the longitudinal axis of the frame, and spherical disks of the third row are oriented with the concave side to the longitudinal axis of the frame. This orientation and the relative position of the disk working bodies allow the stable disking of the soil without disrupting the process.

The harrow works as follows:

When translating the Disk Harrow into the working position and moving the unit, the spherical disks of each row, mounted at an angle of attack to the direction of movement, under the influence of the Disk Harrow weight, are buried in the soil. Support and transport wheels limit their depth depending on the adjustment of the depth. Each spherical disk of each row produces a cleavage of the soil layer and its displacement, while the forces directed to the lateral displacement of each spherical disk are mutually compensated by forces from symmetrically located spherical disks relative to the thrust vector, which coincides with the longitudinal axis of the disk harrow. The disc harrow moves in a straight line, and the technical process of disking the soil occurs without flaws.

Claims (7)

1. A disk harrow containing a frame with aggregation and transportation elements, on which in three rows, at an angle of attack to the direction of movement, spherical disks are fixed, characterized in that left and right-hand spherical disks are mounted on each row, while the spherical disks of the first and the second rows are oriented by concavities from the longitudinal axis of the harrow, and the spherical discs of the third row are oriented by concavities to the longitudinal axis of the harrow. 2. Disk harrow according to claim 1, characterized in that the spherical disks can be typed into the batteries of disk working bodies. 3. The disk harrow according to claim 1, characterized in that the spherical disks can be mounted obliquely to the horizontal with the possibility of vertical movement on individual racks, which are pivotally mounted on the supporting beams of the frame. 4. Disc harrow according to claim 1, characterized in that between the concavities of adjacent spherical disks of the third row additional loosening elements are installed. 5. The disc harrow according to claim 1, characterized in that between the second and third rows of disks installed support and transport wheels. 6. The disc harrow according to claim 1, characterized in that it has a roller or rollers in front and / or rear of the harrow pivotally connected by spring elements and / or levers to the harrow frame, the frame being able to rest on the roller or rollers. 7. Disk harrow according to claim 3, characterized in that the group of working bodies in each row can synchronously change the angle of attack by moving and fixing the beam.