RU2140136C1 - Method and combined tillage tool attached to plow or flat hoe and adapted for preparing of upper sowing water-retaining soil layer - Google Patents

Abstract

FIELD: agricultural engineering. SUBSTANCE: method involves plowing upper soil layer for depth nor exceeding 15 cm; crumbling soil lumps in plowed upper soil layer and leveling soil surface by star-wheeled rollers; crumbling soil for depth of up to 12 cm and withdrawing remaining soil lumps onto soil surface by means of power-driven needle-type disks; continuing soil crumbling and compacting at depth of up to 12 cm to obtain soil density of 1/3 g/cub cm by means of passive needle-type disks; compacting upper soil layer by means of star-wheeled rollers and leveling soil surface; ripping by rotating harrow to obtain upper mulch sheet with depth of 4-6 cm from soil aggregates of 0.5-3 mm size. As a result, compacted mid sheet preventing moisture evaporation from lower plowed layer is formed under upper mulch sheet. Tillage tools used to accomplish method have star-wheeled hoe, power-driven needle-type disks and passive needle-type disks, and rotating harrow. All mentioned tools may be hitched to plows or flat hoes. EFFECT: simplified construction, convenient operation and increased efficiency by forming water-retaining soil layer for one pass. 4 cl, 2 dwg

Description

 The invention relates to agriculture, and in particular to methods and devices for tillage, and is intended to conserve moisture in soils with insufficient moisture when preparing the upper sowing layer of the soil and increase the yield of grain crops.

 There is a known method of tillage, which includes creating depth layers of soil with different density along the depth of the arable horizon at a higher value for the middle layer, during the implementation of which the upper and lower layers in the arable horizon are loosened, and a layer of natural soil is left as a denser layer between them ( SU 622429 A, 07/18/78).

 The disadvantage of this known method is poor-quality processing of the upper soil layer, which worsens the conditions of normal development of the root system of crops and leads to a decrease in their productivity.

 A combined method of primary tillage is known, in which, to improve the quality of cutting the formation, creating a layered arable horizon, accumulating and saving moisture, nutrients and cleaning the soil from weeds, the treated area is simultaneously leveled and plowed at a certain depth of the arable layer to create a loosened surface mulch layer, and tillage unit for the implementation of this method, consisting of sequentially mounted plow, drags, roller-comkodro beater assembled from ring-spur discs (SU 125422 A, 01.30.60).

 The disadvantage of this known method is due to the imperfection of the tillage unit used for its implementation, insufficient compaction of the arable layer at a depth that cannot ensure the creation of a compacted layer that prevents evaporation of moisture from the lower layers of the soil.

 Closest to the proposed one is a method of processing the soil, including loosening the upper and lower soil layers with the creation of a compacted layer between them, the upper soil layer being compacted to a depth of 8-15 cm, and then loosened to a depth of 2 cm (SU 973051 A, 25.11. 82).

 The disadvantage of this known method is that the created top loosened soil layer has a depth insufficient for the normal development of the root system and the growth of crops and the effective absorption of surface water and moisture from the atmosphere.

 The above method is carried out using a soil treatment device, including vertically cutting knives sequentially mounted on a frame, working bodies for soilless tillage, a rotary tool and a roller, behind which there is a rotary tool, with an axis with flanges on which around them working elements are pivotally fixed, and the working bodies for soilless tillage are made in the form of deep-rippers (SU 973051 A, 11.25.82).

 The disadvantages of the aforementioned known device for processing the soil are the complexity of its design and the low efficiency of soil compaction when creating an average compacted layer, which impairs the ability of the latter to prevent evaporation of moisture from the underlying soil layer.

 The closest to the proposed content and types of tillage implements is a combined tillage device for preparation of the top sowing soil attached to plows or plane cutters, containing a supporting frame attached to the front to plows or plane cutters, ringed rollers and active needle discs with curved needles, curved needles, facing curved in the direction of rotation of the disks (SU 1521319 A1, 11/15/89).

 This well-known combined tillage device is quite simple in design and convenient to operate, but using it is impossible to form an upper sowing moisture-saving soil layer consisting of three layers: the upper and lower loosened layers and a compacted layer located between them, which prevents evaporation of moisture from the underlying soil layer .

 The objective of the present invention is to provide an upper seed moisture-saving soil layer, consisting of three layers: the upper loose mulching layer, sufficient for the normal development of the root system and the growth of crops and the effective absorption of surface water and moisture from the atmosphere, the lower coarse layer and the compacted shallow layer spread between them layer, preventing the evaporation of moisture from the underlying soil layer, using a simple in design, inexpensive, convenient, economical and efficient An effective in operation combined soil cultivating device, which ensures the formation of such an upper moisture-saving soil layer in one pass.

The solution to this problem is achieved by the fact that in the method of preparing the upper sowing moisture-saving soil layer, which includes the initial loosening of the upper soil layer and the subsequent formation of three layers from it: the upper and lower loosened layers and the compacted layer located between them, in which the upper soil layer is first compacted onto depth to 12 cm, and then loosened to a shallower depth, according to the invention, the initial loosening of the upper soil layer is carried out to a depth of at least 15 cm, and in open In the upper soil layer, first crumbling soil blocks and leveling the soil surface with ring rollers, and then crushing the soil to a depth of 12 cm and removing the remaining soil blocks to the soil surface using active needle discs and subsequent crushing of the soil and its compaction to a depth of 12 cm with a density of up to 1.3 g / cm ³ using passive needle discs, after which the top layer of soil is compacted with ring rollers with the leveling of its surface, and then loosened with a harrow drum to form the upper mulching layer of soil with a depth of 4-6 cm from soil aggregates 0.5-3 mm in size.

 In terms of the device for implementing the above method, the task is achieved by the fact that a combined tillage device attached to plows or plane cutters for preparing the upper sowing moisture-saving soil layer, comprising a bearing frame to be attached to the plows or plane cutters, ring rollers and active needle discs having curved needles, facing concavity in the direction of rotation of the disks, according to the invention is equipped with a floating frame, parallel to the bottom heated to the supporting frame by means of an articulated suspension with the possibility of adjusting its distance from the supporting frame, passive needle discs having curved needles, convex in the direction of rotation of the disks, and a mulching drum-harrow, ring rollers are mounted in rows on the supporting frame in its front and rear parts and between the rows of ring rollers there is a floating frame on which needle discs are mounted in rows, with at least one row of active needles installed in front of the floating frame disks, and in the middle and rear parts of the floating frame there are at least two rows of passive needle discs, the mulching drum-harrow attached to the rear of the carrier frame and consists of several independently rotating sections.

The sections of the drum-harrow are made with plate knives installed at an angle of 20-30 ^o to the axis of the drum-harrow and having a cutting edge sharpened at an angle of 32 ^o .

 In addition, ring rollers and needle discs are respectively mounted on a bearing and floating frames with the possibility of disks and rollers of one row entering between the disks or rollers of each adjacent row to a depth of 0.1-0.2 diameters of the disks or rollers.

 The invention is illustrated in the drawing, where in FIG. 1 shows a combined tillage device attached to plows or plane cutters for preparing the upper sowing moisture-saving soil layer, side view, in FIG. 2 - the same, top view.

The method of preparing a seed moisture-saving soil layer provides for the initial loosening of the upper soil layer and the subsequent formation of three layers from it: the upper and lower loosened layers and the compacted layer located between them, while the upper soil layer is first compacted to a depth of 12 cm, and then loosened to a smaller depth. Initial loosening of the upper soil layer is carried out to a depth of not less than 15 cm, and in the loosened upper soil layer, soil blocks are crushed first and the soil surface is flattened, and then soil is crushed to a depth of 12 cm and the remaining soil blocks are removed to the soil surface. After this, additional crumbling of the soil and its compaction to a depth of up to 12 cm are achieved with a density of up to 1.3 g / cm ³ .

 Then the topsoil is compacted with its surface leveling and loosened to form an upper mulching layer of soil with a depth of 4-6 cm from soil aggregates 0.5-3 mm in size.

A combined tillage device attached to plows or plane cutters for preparing the upper sowing moisture-saving soil layer contains a supporting frame 1 connected by the front with a floating coupling 2 to plow cutters or plows 3. On the supporting frame 1, one row of ring rollers is mounted on its axis 4 on the axis 4 5, and in its rear part, on the axis 6, another row of ring rollers 7. Between the rows of ring rollers 5 and 7, there is a floating frame 8, which is parallelly attached to the base frame 1 from the bottom by hinges hydrochloric suspension consisting of the levers 9 and 10 are pivotally attached to both ends of frames 1 and 8. The floating frame 8 is suspended from the carrier frame 1 with the possibility of regulation of its removal from the base frame 1, i.e. with the possibility of moving the floating frame 8 vertically, regulated by screws 11. At least one row of active needle discs 12 is mounted on the axis 13 in the front of the floating frame 8, and at least two rows of passive needle are placed in the middle and rear parts of the floating frame 8 the disks 14 on the axes 15 and 16. The active needle disks 12 have curved needles 17 that are turned concave in the direction of rotation of the disks 12, that is, they enter the ground with their sharpened ends for crumbling soil, and passive needle disks 14 have curved needles 18, convex in the direction of rotation of the disks 14, i.e. entering the ground with its convex backs for crumbling and compaction of the soil in depth. A mulching drum-harrow 19, consisting of several independently rotating sections 20, is attached to the back of the supporting frame 1 to prevent breakdowns when turning the device. Section 20 of the drum harrow 19 is made with plate knives 21 mounted at an angle of 20-30 ^o to the axis 22 of the drum harrow 19 and having a cutting edge sharpened at an angle of 32 ^o .

 It is advisable to make ring rollers 5 and 7 with a diameter of 460 mm, and active and passive needle discs 12 and 14 with a diameter of 435 mm for crushing the soil to a depth of 12 cm, respectively, and compaction of the soil to a depth of up to 12 cm. Ring rollers 5 and 7 and needle discs 12 and 14 are mounted on frames 1 and 8, respectively, with the possibility of entering discs 12 and 14 and rollers 5 and 7 of the same row between the discs 12 and 14 or rollers 5 and 7 of each adjacent row to a depth of E = 0.1 - 0, 2 diameters of disks 12 and 14 or rollers 5 and 7 for self-cleaning during operation in case of sticking I moistened the soil after rain. In this case, the gaps between the ring rollers 5 and 7 of the same row should be made with a value of b = 60 mm, and between the needle discs 12 and 14 of adjacent rows with a value of c = 70 mm.

 The harrow drum 19 can be made with a diameter of 380 mm and composed of 4 sections 20.

The proposed combined soil cultivating device in one pass forms a moisture-saving, non-uniform compaction upper sowing soil behind a plow or ploskorez, consisting of three layers: the upper loose mulching layer 23 with a depth of 4-6 cm from soil aggregates 0.5-3 mm in size, medium compacted to achieve a density of up to 1.3 g / cm ³ shallow layer 24 with a depth of 12 cm and the lower coarse layer 25 with a depth of at least 15 cm (the indicated depths are measured from the soil surface).

 A combined tillage device attached to plows or plane cutters works and prepares the upper sowing moisture-saving soil layer in one pass as follows.

The initial tillage of the upper soil layer is carried out to a depth of at least 15 cm using a plow 3 or a plane cutter, moved by a tractor (not shown in the figures) in front of the supporting frame 1. The loosened upper soil layer is exposed to the front row of ring rollers 5 mounted on the supporting frame 1, As a result, crumbling of soil blocks and leveling of the soil surface occur. When sequentially moving a combined tillage device behind a plow 3 or a plane cutter, the needle discs 12 and 14 mounted on the floating frame 8 rotate from the adhesion of their needles 17 and 18 to the soil. In this case, the active needle discs 12, entering the ground with the sharpened ends of the bent needles 17, crumble the soil to a depth of 12 cm and carry the remaining soil blocks to the soil surface. Passive needle discs 14, penetrating into the soil with the convex rear side of the curved needles 18, process the partially loosened soil and deepen, break the unextracted blocks, finally loosen the soil layer to a depth of 12 cm and produce focal compaction of the lower soil layer to a depth of 12 cm with reaching its density up to 1.3 g / cm ³ . The placement of the needle discs 14 on the axis 15 in the spaces between the needle discs 12 and 14 of adjacent rows on the axes 13 and 16, respectively, ensures uniform crumbling of the soil. Needle discs 12 and 14 are introduced into the soil during the operation of the device and removed from it by installing them on the floating frame 8, the movement of which in height relative to the frame 1, and, consequently, the deepening of the discs 12 and 14 into the soil is regulated by screws 11, which also allows transport the towed combined tillage device in the idle position when the needle discs 12 and 14 are raised on the ring rollers 5 and 7. In addition, the floating frame 8, on which the needle discs 12 and 14 are mounted, provides self-regulation according to the soil of the soil during the working movement of the device, and in the event of a collision of the disks 12 and 14 with solid bodies, such as large stones or boulders, the frame 8 rises, thereby preserving the integrity of the device and preventing breakage of the needle disks 12 and 14.

 When the device is working, the oncoming movement of the rollers 5 and 7 and the disks 12 and 14, which leads to their intensive self-cleaning from the soil and eliminates their sticking and clogging.

After the needle discs 12 and 14, the back row of ring rollers 7 acts on the crushed and mixed top soil layer, which compacts the top layer to an optimum density of 1.3 g / cm ³ to a depth of 12 cm and evens out its surface.

 After the rollers 7, the compacted soil surface is loosened by the drum-harrow 19, consisting of autonomously rotating sections 20 with plate knives 21, to form the upper mulching layer of soil with a depth of 4-6 cm from soil aggregates 0.5-3 mm in size.

 Thus, the proposed combined tillage device, transported behind a plow or plane cutter using a floating hitch, creates an upper sowing moisture-saving layer of a given width on low-moistened soils in one pass, corresponding to the agrotechnical requirements, ensures the formation of different density and thickness of soil layers: the upper loose mulching layer sufficient for the normal development of the root system and the growth of crops and the effective absorption of surface and moisture from the atmosphere and lower krupnoryhloy interlayer located therebetween compacted to an optimum density melkoryhloy layer preventing moisture evaporation from the underlying soil, but not interrupting the capillary wetting of the top layer of mulch krupnoryhloy bottom layer. In addition, after plowing with a plow or plane cutter, there are no time gaps between the technological operations of cultivating the soil, which reduces the evaporation of moisture from the cultivated soil.

 As a result of the application of the combined tillage device trailed to plows or plane cutters, the moisture storage in the soil is increased by 20-25% and crop productivity is increased by 15-20%. When using this device, an increase in traction is not required, which saves up to 30% of fuel, and the ability to carry out all technological operations for processing the soil in one pass of the device can significantly reduce labor costs.

Claims (4)

1. The method of preparation of the upper sowing moisture-saving soil layer, including the initial loosening of the upper soil layer and the subsequent formation of three layers from it: the upper and lower loosened layers and the compacted layer located between them, in which the upper soil layer is first compacted to a depth of 12 cm, and then loosened to a shallower depth, characterized in that the initial loosening of the upper soil layer is carried out to a depth of not less than 15 cm, and in the loosened upper soil layer, first sowing soil blocks and leveling the soil surface with ring rollers, and then crumbling the soil to a depth of 12 cm and removing the remaining soil blocks to the soil surface using active needle discs and subsequent crumbling of the soil and its compaction to a depth of 12 cm with a density of up to 1 , 3 g / cm ³ using passive needle discs, after which the upper soil layer is compacted with ring rollers with its surface leveling, and then loosened with a harrow drum to form an upper mulching soil layer with a depth of 4-6 cm from soil aggregates measuring 0.5 - 3.0 mm.  2. A combined tillage device attached to plows or plane cutters for preparing the upper sowing moisture-saving soil layer, comprising a supporting frame attached to the front of the plows or plane cutters, ring rollers and active needle discs having curved needles that are turned concave in the direction of rotation of the discs, characterized in that it is equipped with a floating frame, from below parallel attached to the supporting frame by means of an articulated suspension with the ability to control its removal from the carrier the main frame, passive needle disks having curved needles, convex in the direction of rotation of the disks, and a mulching drum-harrow, ring rollers are installed in rows on a supporting frame in its front and rear parts, and between the rows of ring rollers there is a floating frame on which are mounted rows of needle discs, with at least one row of active needle discs mounted in front of the floating frame, and at least two rows of passive needles placed in the middle and rear parts of the floating frame ring disks, while the mulching drum-harrow is attached to the rear of the carrier frame and consists of several independently rotating sections. 3. The device according to claim 2, characterized in that the sections of the drum-harrow are made with plate knives mounted at an angle of 20 - 30 ^o to the axis of the drum-harrow and having a cutting edge sharpened at an angle of 32 ^o .  4. The device according to claim 2 or 3, characterized in that the ring rollers and needle discs are mounted respectively on a carrier and a floating frame with the possibility of entry of the discs and rollers of the same row in the spaces between the discs or rollers of each adjacent row to a depth of 0.1 - 0.2 diameters of disks or rollers.

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