RU2125783C1 - Potato growing method and apparatus - Google Patents

Abstract

FIELD: agriculture. SUBSTANCE: method involves hilling up during pre-emergence period and orienting plant underground part centrally of ridge relative to its vertical axis of symmetry at ridge sides; exposing plants to forces of equal value oriented in opposite directions and dynamically acting upon plants along arced path from their bottom to top parts. Force is created by hiller moldboards rotated by engagement with soil and positioned in symmetry with respect to vertical axis of symmetry of ridge. Hiller working surfaces are formed as covering disks with hilling members and covering disk angle adjusting mechanisms, with angle of covering disks being set within the range of 2-85 deg depending on distance between horizontal axes of adjacent ridges. Force developed by hiller moldboards acts upon plant roots and stem buds to create stresses. Method further involves separating soil in ridge top part. Separating members of drums rotated by cooperation with soil act upon slowly advancing soil to reverse direction of projection on horizontal axis of symmetry of ridge of linear speed vectors of soil particles movable in ridge top part. Soil layer height above tubers is reduced to 0.01-0.5 m for each pass of apparatus. Hilling process performed prior to soil separation in ridge top part provides increase in soil layer height above tubers in ridge by at least 0.02-0.51 m depending on row spacing for each pass of hiller. EFFECT: increased efficiency by uniform thickness of soil layer above tubers in adjacent ridges, increased potato yield and quality, and improved weed control. 4 cl, 12 dwg

Description

 The invention relates to agriculture, and in particular to methods and devices for growing crops, including potatoes.

 A known method of growing potatoes [1], consisting of planting tubers, planting care by inter-row cultivation, carried out by the method of layer-by-layer cultivation of each row-spacing with three-tier ridges, first in the middle to a depth of 8-9 cm, and then from 2 sides of the first trail of the hiller to a depth of 17-18 cm with the formation of a protective zone from the planted row with tubers equal to 15-16 cm, and again in the middle to a depth of 8-9 cm, while the hills on the cultivator are arranged in three rows with a distance between the first and second rows of 40-45 cm.

 The disadvantage of this method of growing potatoes is its complexity due to the presence of four operations for its implementation and loosening of the row spacing in its middle, loosening of the row spacing on both sides of the first track of the hiller, repeated loosening in the middle of the row-spacing, leveling the soil of the crest apex. The disadvantage of this method is that for its implementation, devices with passive working bodies (ridgers with dumps and a harrow) are used, which does not allow to qualitatively grind and fluff the soil when moving it from the row-spacing to the ridge.

 A device [2] is known which relates to working bodies for tillage and consists of a disk with teeth. Each tooth has a leaf spring. The front edge of the tooth is made in the form of a wedge, and the rear has a groove, while the spring, its end, is rigidly fixed to the upper part of the rear edge of the tooth, and the other is freely placed in the groove.

 A disadvantage of the known working body of a rotary tillage implement is the complexity of its design and fragility in connection with the presence of an additional spring installed in front of the loosening tooth.

 Closest to the alleged inventions is a method of caring for planting potatoes and a device for its implementation, described in [3]. The method includes the following operations: loosening the crest peaks, hilling ridges, loosening the sides and crest peaks, forming a crest profile. A device for implementing this method consists of pups and conical tooth drums located behind each of them on the horizontal axis, and additional tooth drums are located between adjacent pups on the longitudinal axis of symmetry of the device, with one drum placed in front of the pups and the other behind the conical drums.

 The disadvantages of this method and device for its implementation are as follows. When earthing with the help of progressively moving ridders with dumps, the soil from the row-spacing to the ridge moves in the form of large lumps, when grinding by compressing them with conical and special-shaped rollers with teeth (drums), the soil is compacted on the sides of the ridge and its top, which contributes to the rapid formation on them of a compacted soil crust, which prevents aeration of the soil in the ridge, and therefore, the life support of plants. In fact, the destruction of lumps and soil crust on the sides of the ridge and its top is carried out by rolling the soil with the help of cylindrical, conical and specially shaped rollers with teeth.

 Due to the pressure of the surface elements of the cylindrical and special shape of the rollers on the top of the ridge, they damage vegetative potato plants.

 The presence of four operations of the method and four functional elements of the device for implementing this method complicates the method and device when the aeration of the soil is worsened and, as a result, the potato yield and its quality are reduced.

 The aim of the invention is to ensure when hilling the spreading of the soil layer of the same height above the tubers in adjacent ridges, improving the soil structure, increasing the yield of potatoes with an increase in the number of tubers and improving their quality, as well as reducing the weediness of the field by weeds.

 This goal is achieved in that in a method of growing potatoes, including planting tubers, planting care by inter-row cultivation with loosening, hilling and combing in the pre-emergence and post-emergence periods during the earthing operation in the pre-emergence period, the underground part of the plants creates a stressful situation, orienting it in the center of the ridge, by affecting the roots and shoots of the stems of the plant, from the sides of the ridge, equal in size, oppositely directed and dynamically acting on the plant along the arcuate trajectory from their lower part to the upper, by the forces created by rotor ridges located symmetrically with respect to the vertical axis of the ridge, the ridges of the pupils, the working surfaces of which are made in the form of disk-zagortachi, with special adjustment of the angle of attack of the disk zagortachi, immediately after hilling operations with the crushing of the ground soil on the crest tops with the rotary dumps of the hills, during which the projection onto the horizontal axis of symmetry of the line vector ridge the speed of each particle of the spread soil is directed forward, the soil is separated in the upper part of the ridge with the action of the separating elements of the drums rotating from adhesion to the soil moving forward with the deceleration of the soil and as a result of a change in the direction of the projection of the linear velocity vectors of soil particles moving in the upper part of the ridge, on the contrary, with a controlled decrease in the height of the soil layer above the tubers to 0.01-0.5 m for each pass of the device for growing potatoes and the separation of weeds from the soil you, and during the hilling operation, preceding the separation of the soil in the upper part of the ridge, for each pass of the hills they provide an increase in the height of the soil layer above the potato tubers in the ridge by no less than 0.02 - 0.51 m, depending on the row spacing.

The goal in a device for growing potatoes, containing pupils with bow parts and dumps, is achieved by the fact that the bow parts of pellets, made in the form of slitters, are mounted on the front beam of the device, on the rear beam of the device are rigidly fixed dumps made in the form of rotating from the clutch with the soil of the zagrotachi discs and the possibility of adjusting the angle of attack of the latter, the front beam of the device is connected to the rear beam using spring-hinged nodes and flexible stabilizers, each of the spring The leveling units are made in the form of a spring mechanism pivotally mounted between the lower double-hinged frame and the upper screw mechanism, the front part of the spring mechanism is pivotally connected to the removable bracket of the front beam, its rear part is connected to the bracket on which the rear removable beam of the device is attached, each of the flexible stabilizers is installed under the spring-hinge assembly and connects the removable bracket of the front beam and the lower part of the rear beam, and to the rear beam of the device using the lower rigid and the upper flexible rods pivotally connected device for the separation of soil in the upper part of the ridge, made in the form of ribbed drums located on a horizontal axis with separating elements mounted on the edges of the drums. The angle of attack of the rotating disc-zagortach is set in the range from 2 to 85 ^o depending on the distance between the horizontal axes of adjacent ridges. The ribs of the drums with loosening elements of the device for soil separation are located parallel to the axes of the drums, and the separating elements on the ribs of the ribbed drums can be made in the form of teeth of round, rectangular or other section with an installation angle with respect to the perpendicular to the edges of the drum from 0 to 180 ^o .

 In FIG. 1 shows a diagram of the effect of pre-emergence period on the underground part of plants of forces created by rotating disks; in FIG. 2 is a diagram of a change in the direction of projections onto the horizontal axis of symmetry of the ridge of vectors of linear velocities of soil particles in the upper part of the ridge; in FIG. 3 is a horizontal projection of a device for implementing the method; in FIG. 4 - frontal projection of the device; in FIG. 5 is an embodiment of a replaceable loosening element of a zagotag disc; in FIG. 6 is a section BB in FIG. 3, with an image of a bearing assembly of a zagotag disk; in FIG. 7 is a view A in FIG. 3, with the image of the rear beam of the device with the assembly of the disk-earthing device mounted on it; in FIG. 8 is a view B in FIG. 3, depicting a spring-swivel assembly with a flexible stabilizer; in FIG. 9 is a view C in FIG. 4, depicting a spring-swivel assembly; in FIG. 10 is a view D in FIG. 3 depicting a device for separating soil in the upper part of the ridge; in FIG. 11 is a view E of FIG. 3 with an image of the support wheel assembly of the device.

The method of growing potatoes includes well-known operations - planting tubers and caring for plantings by inter-row cultivations with loosening, hilling and cresting. Distinctive operations of the method are as follows. In the process of hilling in the pre-emergence period, the underground part of the potato plants 1 (Fig. 1) is oriented in the center of the ridge 2 relative to its vertical axis of symmetry 3 from the sidewalls 4 of the ridge 2 equal in value, oppositely directed and dynamically acting on the plants 1 along an arcuate path from the bottom parts of plants 1 to the upper forces 5 created by rotating from adhesion to the soil and located symmetrically with respect to the vertical axis of symmetry 3 of the ridge 2 dumps 16 hills, the working surfaces of which They are not used in the form of clutch disks 6 with loosening elements 7 at their ends, with special adjustment of the angle of attack α of clutch disks 6, which is set in the range from 2 to 85 ^o depending on the distance between the horizontal axes of adjacent ridges. In this case, the forces 5 created by the rotor disks 6, which rotate from the soil and adhere to the soil, act on the soil on the sides 4 of the ridge 2, shift it to the top of the ridge 2 along the tangent to the rotation path of the loosening elements 7, and, in the process of soil displacement, orient the underground part of plants 1 in the center of ridge 2 relative to its vertical axis of symmetry 3. When exposed to the roots and shoots of plant stems 1 by forces 5, the latter create a stressful situation. Immediately after the earthing operation with the particles 8 (Fig. 2) of crushed soil being poured onto the tops of the ridges 2 by the rotary dumps 16 of the hills, the soil is separated in the upper part of the ridge in the interval between the top of the ridge 2 and the upper surface of the uterine potato tuber 9. Moreover, they rotate from the clutch with soil, the separating elements 10 of the drums 11 act on the soil moving forward with deceleration and change the direction of projection onto the horizontal axis of symmetry 12 of the ridge 2 of the linear velocity vector of soil particles 8, dv -moving at the top of the ridge 2, - to the contrary. The slow motion of the soil layer, which is poured onto the top of the ridge 2 by the rotary dumps 16 of the hills, is carried out using gravity forces acting on each soil particle 8, and friction between the soil particles 8 in the layer that is poured onto the top of the ridge 2. This slow motion of the soil layer occurs due to the fact that each of its particles 8 has a mass, kinetic energy and speed. Moreover, the projection 13 of the linear velocity vector of the slow movement of each soil particle 8 after the impact of dumps 16 on it is directed forward, and due to the impact on these soil particles 8 of the separating elements 10 of the rotating drums 11, they change their direction of movement in the opposite direction and, accordingly, the projection 13 vector of linear velocity of the soil particles, the soil moves backward and to the side, fluffs, the height of the ridge decreases. A controlled decrease in the height of the soil layer above the tubers 19 with separation during the separation of weeds 14 from the soil is carried out from the height of the soil layer above the tubers 9 within 0.51 - 0.002 m to a height of 0.5 - 0.001 m, depending on the row spacing. For example, with a row spacing of 0.7 meters, the height h of the soil layer above the tubers may decrease from 0.3 meters to 0.05 meters. Separation of the soil with the fluffing of the latter and separation of the weeds 14 from the particles 8 of the soil becomes possible due to the fact that the separating elements 10 on each edge of the rotating drums 11 are located in the same line as a comb, enter the soil and sift it, separating the weeds 14 from the soil particles 8 having large linear dimensions in comparison with particles 6 of the soil.

 When orienting the underground part of plants 1 potato with soil displacement on the sides 4 of the ridge 2 upward to the top of the ridge 2 by loosening elements 7 of the drive disc 6 and soil displacement in the upper part of the ridge 2 back and to the side when the separating elements 10 of the drums 11 are exposed to it soil separation, alternating soil vibrations are transmitted to the underground part of plants, including developing roots. Those. a stressful situation is created for plants. As tests have shown, plants, including their protective biological mechanisms, respond to a stressful situation by increasing the number of stolons with the formation of tubers on them and the more powerful accelerated development of their root system, and later on tops and tubers.

 A device for growing potatoes consists of hillers with bow parts 15 (Figs. 3, 4), rotating dumps 16, which are an assembly. The nasal parts of 15 hillers are made in the form of slit formers. The working element of the slit-forming device is an arc-shaped non-toe toe 17 (Fig. 4), fixed by means of bolts to a rigid arc-shaped rack 18. The arc-shaped rack 18 is fixed using detachable connections, for example, threaded ones on the front beam 19. On the rear beam 20, the devices are installed with using rigid mounting dumps 16, the working surfaces of which are disks 6, with loosening elements 7 on their periphery. The loosening elements 7 can be removable and installed in special holders 21 (Fig. 5) rigidly fixed around the perimeter of the disc-harnesses 6. The right and left disc-harrowers 6 are mounted to rotate on a curved axis 22. In this case, the horizontal axis of symmetry of each of the pupils passes through the horizontal axis of symmetry of the slotting machine, as well as the right and left zagortachi discs. The curved axis 22 is mounted to rotate with adjustments in the hole 23 of the plate 24. The plate 24 is mounted on racks 25, in turn, mounted on the rear beam 20 of the device. The plate 24 has adjustment holes 26 located in an arc relative to the hole 23. By means of the adjustment holes 26 and bolted connections to the plate 24, an arm 27 is fixedly mounted on the curved axis 22. A bearing assembly 28 is mounted on each end of the curved axis 22 (FIG. 6), and the housing of the bearing assembly 28 is attached using detachable threaded connections to the disk-shortener 6. On the plates 24 installed at the ends of the rear beam 20 of the device, one disk-shortener 6 is installed 6. From the foregoing that each blade 16 is an assembly consisting of a zagotachka disk 6, a curved axis 22 and a bearing assembly 28. Due to the bend in the central part of the axis 22, turning the latter and fixing its position in the adjustment holes 26 of the plate 24, using bolted connections 29 (Fig. 7) set the angle of attack α. α is the angle between the plane passing through the ends of each shorting disk 6 and the horizontal axis of symmetry 12 of the ridge 2. It is chosen in the range from 2 to 85, depending on the distance between the horizontal symmetry axes of 12 adjacent ridges 2.

 The front beam 19 of the device is connected to the rear beam 20 using spring-hinged nodes 30 (Fig. 8, 9). Each of the spring-hinged nodes 30 is a spring mechanism 31 mounted between the lower hinge frame 32 (Fig. 8) and the upper screw mechanism 33. The spring mechanism 31 is an arcuate rod 34 (Fig. 9) with two threaded ends in its right part. One spring 35 is installed on each of the two rods of the arcuate rod 34. The springs 35 are limited on both sides by special washers 36 and plates 37, 38. Compression of the springs 35 is carried out using nuts installed on the threaded ends of the rod 34. The plate 37, mounted in the left part of the rod 34, pivotally connected to the brackets 39 of the front beam 19 of the device. The plate 38, mounted on the right side of the arcuate rod 34, is rigidly attached to the bracket 40. On the two brackets 40 is attached to the rear beam 20 of the device. With the help of the upper screw mechanism 33 provides fine adjustment of the angle of attack α of the disk-harrowing 6.

To the rear beam 20 of the device using the lower rigid 41 and upper flexible 42 rods connected devices 43 (Fig. 10) for separating soil in the upper part of the ridge. Each device 43 consists of a drum 11 with ribs 44 fixed on it and parallel to the axes of the drums. Separating elements 10 are mounted on the ribs 44 or are made directly in the body of the ribs 44. The separating elements 10 can be made in the form of teeth of round, rectangular or other section with the angle β of the installation with respect to the perpendicular of the edges of the drum at its upper point from 0 to 180 ^o . Each rib 44 with separating elements 10 is a separating comb. Ribbed drum 11 is mounted on the lower ends of the two lower rigid rods 41 of the device 43, with the possibility of rotation. The upper ends of the lower rigid rods 41, using hinges 45 connected to the rear beam 20 of the device. In the upper part of the rear beam 20, longitudinal rigid rods 46 are fixed with sockets 47 at their ends. The longitudinal rods 46 may be a continuation of the bracket 40. In this case, the rear beam 20 of the device is mounted on the rods 46. Arched racks 48 are installed in sockets 47 with flexible rods 42 fixed in their upper part, the lower end of which is fixed to the lower end of the lower rigid rods 41.

 In the central part of the front beam 19, a frame 49 for connecting the device to the rear linkage of the tractor is installed.

 Using the brackets 50 (Fig. 11) of the swivel mechanisms 51 and the arcuate racks 52, two support wheels 53 are installed on the front beam 19 of the device.

 At the ends of the front beam 19, removable markers 54 are installed. Markers 54 are an arcuate slotless slotter with a toe 17 and a stand 18 mounted on the front beam 19, for example, using a guide 55 and threaded connections 56.

 To prevent large-amplitude oscillations of the spring-hinge assembly 30, the rear beam 20 of the device is connected by a bracket 57 and a latch 58 with a flexible stabilizer 59 to the bracket 39 of the front beam 19 of the device.

 To create a crest with the shape of a smooth sinusoid in cross section at the end of the treatments, it is possible to adjust the installation height of the zagrotachi disks 6 relative to the nose parts 15 of the hills. To do this, the clamps 60, washers 61 and nuts 62 are removed, the rear beam 20, mounted under the bracket 40, is also removed and installed on the upper part of the bracket 40, is fixed to the latter with the help of clamps 60, washers 61 and nuts 62.

 In the event of a breakdown of the arcuate rod 34 of the spring-pivot assembly 31, it is provided for fixing the latter with the latch 63 of the bracket 40, the latch 64 of the lower double-hinged frame 32 and the rigid rod 65 connecting the latches 63 and 64.

 The device operates as follows. Each hiller device is installed in the center of the row-spacing and the unit (device and tractor) is given the speed of translational movement. At the same time, the sock 17 of the slot former, which is the nose part 15 of each hiller, loosens the soil in the center of the row-spacing and forms in one pass a gap in the soil with a depth of 0.1 - 0.3 meters. This gap is cut with the help of the right and left dumps 16 hiller, the working surfaces of which are made in the form of disks-zagortachki 6 with loosening elements 7 at their ends. The process of cutting the gap is as follows. In the process of translational movement of the device for growing potatoes, each clutch disc 6, as a result of adhesion to the soil of the loosening elements 7 installed at its ends, rotates. At the same time, the loosening elements 7 enter the soil in the gap zone at the center of the row-spacings formed by progressively moving gap-forming machines located on the front beam 19 of the potato growing device. In the process of rotation of the right and left drive discs 6 mounted on the rear beam 20 of the device, the loosening elements 7 crush the soil in the gap zone along the entire width of the row spacing and sidewalls 4 of the ridge 2 and, at the same time, tell the microcombs of the crushed soil the speed towards the top of the ridge 2 and along during the movement of the device, the crushed soil is thrown to the top of the ridge 2. When inter-row cultivation (hilling) in the pre-emergence period and contact of the loosening elements 7 of the disc-harrow 6 with soil on the sidewalls of 4 ridges 2 of the underground part of the races 1, especially the roots and shoots, create a stressful situation by acting on them from the sidewalls 4 of the ridge 2 equal in magnitude, oppositely directed and dynamically affecting the roots of the plants and shoots of stems along an arcuate trajectory from their lower part to the upper, forces 5, created by rotating from coupling with the soil and arranged symmetrically relative to the vertical axis of symmetry 1 of the ridge 2 dumps 16 with the working surface in the form of disks-zagortachki 6 and loosening elements 7 on their periphery. Simultaneously with the creation of a stressful situation when exposed to the underground part of plants 1 by external forces 5, plants 1 are oriented in the center of the ridge using the same equal in magnitude and oppositely directed forces 5. Soil that has fallen onto the working surface of a rotating disk-zagratka 6 is fed to centrifugal forces loosening elements 7, which are crushed and laid on the comb 2.

 The process of grinding the soil is intensified due to the connection of the front 19 and rear beam 20 of the device for growing potatoes using spring-hinged nodes 30. In this case, the spring-hinged nodes 30 provide vibration of the rear beam 20 with respect to the front beam 19. Together with the rear beam 20, vibrations are transmitted through racks 25, plates 24, brackets 27, axles 22 and bearing assemblies 28 on zagachachi disks 6 with loosening elements 7. Additional vibrations of the loosening elements 7 and, in general, zagratachi disks 6, which are the working surfaces of heaps 16 hiller, intensify the process of grinding the soil. Vibration vibrations through the rear beam 20, the lower rigid rods 41 and flexible rods 42 are transmitted to the drum 11 and its separating elements 10. The devices 43 for separating the soil in the upper part of the ridge 2 intensify the process of soil separation, increase its fluffiness, i.e. reduce the specific gravity of the soil after the separation process, improve the structure of the soil and improve the quality of separation of weeds 14 from the soil in the separation process. The direct process of soil separation is as follows: in the process of translational movement of the device for growing potatoes, each ribbed drum 11 rotates as a result of adhesion of its separating elements to the soil 10. Moreover, the separating elements 10, made in the form of separating teeth, and representing a comb comb , when entering the soil, it is repeatedly shifted and in the process of rotational movement of the gear ribs 44 of the drum 11, the soil is crushed in the upper part of the ridge 2, about eivayut it, ie the soil is separated and weeds 14 are separated from the soil during the separation process, because soil microcrushers 8, which are much smaller than weeds 14, freely pass through the separating teeth 10 of the ribs 44 of the drum 11. The weeds 14 are separated from the soil and carried to the surface of the latter. During the separation process, the upper part of ridge 2 is destroyed to ensure the height of the soil layer above the tubers, for example, during the first pass of the device from 0.01 to 0.12 m. After emergence of shoots of potato plant stems above the surface of the ridges (starting from a height of 0.01 up to 0.1 m, depending on the presence of soil crust in the upper part of the ridge 2, the device 43 for separating soil in the upper part of the ridge 2 is removed from the rear beam 20 of the device and inter-row processing of potatoes is carried out only by hillers, which include rotating dumps 16 andnose parts 15, made in the form of slit formers.

 An important advantage of the proposed method for growing potatoes is the creation of stressful situations for the underground part of plants by affecting the roots and shoots of stems with external forces. This forces plants in the struggle for survival to include their protective biological mechanisms, while increasing the number of stolons with the formation of tubers on them, rapidly developing the root system, tops and ultimately increasing the yield of tubers. When hilling the soil layer over tubers 9 in adjacent ridges 2 of the same height, carried out by rigidly securing 20 rotary dumps 16 on the rear beam, it provides optimal and identical conditions for the growth and development of plants in adjacent ridges 2, which ultimately improves yield potato field.

 A phased increase in the height of the soil layer above the tubers 9 in ridges 2 from 0.2 to 0.51 meters, with soil separation in the upper part of the ridge 2, improves soil aeration, improves conditions for the development of plants in general, tuberization, and improves the quality of the latter by stabilizing factors of plant life support, and effectively separate weeds 14 from the separated soil.

 The loose state of the soil in the ridge and at the bottom of the aisle facilitates the work of separating working bodies, which reduces the number of failures.

 The device allows you to cut the ridges before planting potatoes and to produce inter-row processing when growing other crops using soil ridges, for example, corn, beet fodder and sugar and others.

Sources of information
1. USSR author's certificate N 1584781, cl. A 01 B 79/02, 1990.

 2. USSR author's certificate N 1286124, cl. A 01 B 21/08, 1987.

 3. Copyright certificate of the USSR N 1500177, cl. A 01 B 79/00.

Claims (4)

 1. A method of growing potatoes, including planting tubers, planting care by inter-row cultivations with loosening, hilling and combing in the pre-emergence and post-emergence periods, characterized in that during the earthing operation, the underground part of the plants creates a stressful situation, orienting it according to the center of the ridge by affecting the roots and shoots of the stems of the plants from the side of the sides of the ridge equal in magnitude, oppositely directed and dynamically acting on the plants in an arcuate trajectories from their lower part to the upper by forces generated by ridges of ridges rotating symmetrically with respect to the vertical axis of the ridge, working surfaces of which are made in the form of shorting discs, with special adjustment of the angle of attack of shorting discs immediately after the earthing operation with the grinding soil to the tops of the ridges by rotating dumps of hillers, during which the projection onto the horizontal axis of symmetry of the ridge of the linear velocity vector of each of soil pulled onto the ridge of the soil is directed forward, the soil is separated in the upper part of the ridge with the action of the separating elements of the drums rotating from adhesion to the soil and the soil moving forward with deceleration and, as a result, the projections of the linear velocity vectors of the soil particles moving in the upper part of the ridge are changed , on the contrary, with a controlled decrease in the height of the soil layer above the tubers to 0.01 - 0.5 m for each pass of the device for growing potatoes and the separation of weeds from the soil, and in During the process of the hilling operation, preceding the separation of the soil in the upper part of the ridge, for each pass of the hills they provide an increase in the height of the soil layer above the potato tubers in the ridge by no less than 0.02 - 0.51 m, depending on the row spacing.  2. A device for growing potatoes, including nibblers with bow parts and dumps, characterized in that the nose parts of the hibbers, made in the form of slitters, are installed on the front beam of the device, on the rear beam of the device are rigidly fixed dumps made in the form of rotating from coupling with the soil zagregachi discs, with the ability to adjust the angle of attack of the latter, the front beam of the device is connected to the rear beam using spring-hinged nodes and flexible stabilizers, each of the spring-hinged nodes It is made in the form of a spring mechanism installed between the lower hinge frame and the upper screw mechanism, the front part of the spring mechanism is pivotally connected to the bracket of the front beam, its rear part is connected to the bracket on which the rear removable beam of the device is mounted, each of the flexible stabilizers is mounted under the spring hinged and connects the removable bracket of the front beam and the lower part of the rear beam, to the rear beam of the device using the lower rigid and upper flexible rods pivotally connected device for soil separation in the upper part of the ridge, made in the form of ribbed drums located on a horizontal axis with separating elements mounted on the edges of the drums. 3. The device according to claim 2, characterized in that the angle of attack of the spinning disks is set within 2 - 85 ^o depending on the distance between the horizontal axes of adjacent ridges. 4. The device according to claim 2, characterized in that the ribs of the drums with loosening elements of the device for separating the soil are parallel to the axes of the drums, and the separating elements on the ribs of the ribbed drums can be made in the form of teeth of round, rectangular or other cross-section with an installation angle with respect to to the perpendicular ribs of the drums in its upper point 0 - 180 ^o .

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