RU2719720C1 - Method of erosion prevention of soil in a fallow - Google Patents

Abstract

FIELD: agriculture.SUBSTANCE: invention relates to agriculture. Method includes the main soil treatment and simultaneous creation on the field surface from the stubble residues of the blown and impermeable brushes, alternating between each other and located across the slope. During spring-summer cultivation in a fallow, before sowing winter wheat, impermeable brushes are kept on the surface of the field and moved along the slope section from the bottom upwards by a value commensurate with their width. Local soil-deepening is performed under the base of the impermeable brushes at their creation and spring-summer cultivation. During the first main tillage of the soil during creation of impermeable brushes, a preparation is applied in them to accelerate the decomposition of stubble residues, and before last cultivation, mineral fertilizers are introduced into the impermeable brushes. Local soil-deepening under base of impermeable brushes is made in form of cut slits displaced from center of base of brushes towards slope top.EFFECT: method increases erosion resistance of the fallow and productivity of winter wheat.1 cl, 1 dwg, 2 tbl, 1 ex

Description

The invention relates to agriculture and can be used in the tillage in a steam field, mainly on sloping lands.

A known method of subsurface processing of sloping lands [patent of the Russian Federation No. 2487518, class. АВВ 79/02, 13/16, 35/16, application No. 20111140904 from 10/07/2011, publ. 07/20/2013 in Bul. No. 20], carried out in two phases, in the first phase they conduct vertical non-root slitting to a depth of 0.3 m, while the cracks are staggered, in the second phase in the spring they carry out continuous surface loosening and mulching of the soil with implements with rotary working bodies to a depth sowing seeds.

The disadvantages of this method is that the gaps formed in the first phase in the autumn period, arranged in a checkerboard pattern during winter thaws, are filled with water and washed away fine earth, and when the cold is returned, ice. During the spring snowmelt, ice-filled slots do not allow melt water to penetrate into the lower soil horizons; as a result, surface runoff and wash-off of fertile soil in slope agrolandscapes form on such agraphones.

In addition, when performing the second phase of surface loosening and mulching of the soil, crop residues are located in the upper soil layer, which leads to the fact that their decomposition during the growth of field crops consumes a significant part of nitrate nitrogen, which is one of the main elements of plant nutrition, which reduces crop yields.

A known method of cultivation of crops, mainly winter wheat [patent of the Russian Federation No. 2305926, class. АВВ 79/02, application No. 2005136772/12 of 11.25.2005, publ. 09/20/2007 in Bul. No. 26], including harvesting of the predecessor, distribution of the non-grain part of the crop in the field, stubble cultivation, treatment of weeds with herbicides, early spring cultivation and leveling of the field relief, destruction of weeds in the spring-summer period, fertilizing before the last pre-sowing cultivation and sowing with a row spacing of 15 see, post-sowing rolling and destruction of the soil crust. In late autumn, at a stable subzero temperature, they are snapped to a depth of 0.40 ... 0.45 m with a gap between slots of 1.4 ... 2.8 m. In mid-May, crafts are made of narrow slots 16 ... 22 mm wide to a depth of 0.30 ... 0.40 cm in increments of 1.4 ... 2.8 m, perpendicular to slots in the late autumn period.

The disadvantage of this method is that in the early spring period during intense snow melting on sloping lands, surface treated soil in autumn and compacted soil has low water permeability, therefore, under the influence of the energy of water flows, the upper fertile layer of soil and surface covered crop residues are washed away . Slots cut in late autumn with a depth of 0.40 ... 0.45 m with a gap between the slots of 1.4 ... 2.8 m, due to the fact that in early spring they can partially be filled with ice and washed-out fine earth, do not provide reliable penetration of the flowing water into lower soil horizons. As a result, water erosion is formed on such agrophones.

In addition, during steam field treatments in the spring and summer months, the upper flattened loose soil layer, devoid of vegetation, is also easily eroded during heavy rainfall by streams of water flowing down the slope. At the same time, narrow slits cut in May, 16 ... 22 mm wide with a pitch of 1.4 ... 2.8 m, perpendicular to the slots that were perpendicular to the late autumn period, lead to runoff of water along them and erosion of the soil.

The crop residues evenly distributed in the upper soil layer in the steam field during the spring-summer period are partially decomposed, therefore, after sowing winter wheat, a significant part of nitrate nitrogen is spent on the decomposition of the remaining part of the stubble throughout its growing season. The activity of the process of decomposition of crop residues in steam fields in the summer period is significantly reduced due to the low humidity of the upper soil layer. This creates a deficit of nitrate nitrogen in the soil and leads to a decrease in winter wheat productivity.

The closest in technical essence (prototype) to the proposed method of anti-erosion tillage in a steam field [Pat. RF №2564849, IPC АВВ 79/02. Stated March 18, 2014, publ. 10/10/2015 in Bul. No. 28], which includes the main tillage and the simultaneous creation on the field surface of crop residues of blown and non-blown wings, alternating between themselves and located across the slope. At the same time, windproof scenes are kept on the surface of the steam field during spring-summer cultivations during the entire period before sowing winter wheat, and during each spring-summer cultivation windproof scenes are moved along the slope from the bottom upwards by an amount commensurate with their width, and under the base the windproof scenes during their creation and spring-summer cultivations of the steam field perform local soil deepening.

The disadvantage of the prototype is that the crop residues located in the windproof wings, which are stored on the steam field throughout the spring-summer period before the sowing of winter wheat are partially decomposed. As a result of this, after sowing winter wheat, part of the nitrate nitrogen is spent on the decomposition of the remaining part of the crop residues throughout its growing season, this creates a deficiency of nitrogen, one of the main elements of plant nutrition, in addition, the prototype method does not include mineral fertilizers in the windproof which generally reduces the yield of winter wheat.

The disadvantage of the prototype is also that under the base of the windproof wings the local soil deepening is performed without displacement towards the top of the slope from the center of the base of the wings. With this arrangement of local soil cultivation under the wings, additional time is required for the water flowing down the slope through the soil-stubble mass of the wings to the lower horizons of the soil. This leads to the fact that with an intensive supply of water, its volume in front of the wings quickly increases, overflow of accumulated water through the wings takes place and their erosion leads to an avalanche-like runoff of water and erosion.

The technical result of the invention is to increase the erosion resistance of the soil and the productivity of winter wheat.

The technical result is achieved in the proposed method of anti-erosion tillage in a steam field, including the main tillage with the simultaneous creation on the field surface of crop residues of blown and not blown wings, alternating between each other and located across the slope, while blown scenes are stored on the field surface until winter crops wheat and move them along the slope during spring-summer cultivations from bottom to top by an amount commensurate with their width, and under the base it cannot be blown when creating them and spring-summer cultivations, they perform local soil deepening, so that during the first main treatment of the steam field in the process of creating windproof wings, drugs are added to accelerate the decomposition of crop residues, and before the last cultivation of the steam field, mineral fertilizers are introduced into the windless wings, in this case, a local subsoiling under the base of the wings is performed in the form of cut gaps, which are offset from the center of the base of the wings in the direction of the top of the slope.

The prior art does not know a solution containing a set of features similar to the proposed solution.

The set of essential features of the proposed method of anti-erosion tillage in a steam field is in the following causal relationship with the achieved technical result.

In the proposed method of anti-erosion tillage in a steam field, the first main tillage is carried out with the simultaneous creation of blown and non-blown scenes alternating between each other and located across the slope on the surface of the steam field, while preparations are made to the blown scenes to accelerate the decomposition of the crop residues, located in windproof scenes, spring-summer cultivations of the steam field, in which windproof scenes are kept on the surface of the steam field and at Each cultivation moves them from bottom to top along the slope area by an amount commensurate with their width, and before the last cultivation of the steam field, mineral fertilizers are introduced into the windproof wings. This combination of features in comparison with the prototype method leads to a reduction in the time of decomposition of crop residues, the main part of which is located in windproof wings, which can significantly reduce the consumption of nitrate nitrogen in the soil for decomposition of crop residues during the growing season of winter wheat and, as a result, , additionally accumulated nitrate nitrogen and other nutrients formed during the decomposition of crop residues and introduced before the last cultivation of the vapor field mineral fertilizer, will increase the yield of winter wheat.

In addition, in comparison with the prototype method, under the base of the windproof wings, a local soil deepening is performed, in the form of cut gaps, which are offset from the center of the base of the windproof wings towards the top of the slope, which reduces the distance from the edge of the windproof wings facing the top of the slope to the cut gaps . This leads to the rapid penetration of water flowing down the slope, during heavy rains and heavy snowmelt, into the deep soil horizons, and reduces the accumulation of water volume in front of the wings, which helps to prevent water overflow through the windproof wings and their erosion by flows of flowing water, thereby increasing erosion resistance the soil.

The invention is illustrated in FIG. In FIG. schematically shows a cross section of a layer of soil treated by the proposed method.

The proposed method of anti-erosion tillage in a steam field is as follows. In the autumn, the soil cultivating implement performs loosening of the soil without turning the bed, at the same time, alternating blown and non-blown wings are created from the crop residues on the field surface, across the slope, while during the creation of windproof wings the drug is introduced into them to accelerate the decomposition of the crop residues and under the base of the windproof wings the slits are cut which are offset from the center of the base of the wings towards the top of the slope. In the spring, as weeds grow, the first cultivation of the steam field is carried out. Simultaneously with the implementation of the first and subsequent spring-summer cultivations, wind-blown scenes are stored on the field surface immediately prior to sowing winter crops and, during each cultivation, they are moved from bottom to top along the slope by a value commensurate with the width of wind-blown curtains, and gaps are cut under the base of wind-blown curtains that are offset from the center of the base of the wings in the direction of the top of the slope. When performing the penultimate cultivation, mineral fertilizers are introduced into the windproof wings. The last pre-sowing cultivation of the steam field is carried out immediately before sowing with a small time gap. At the same time, windproof wings and the mineral fertilizers and crop residues contained in them are distributed in the upper treated soil layer of the steam field. Sowing winter wheat is performed across the slope.

An example of a specific implementation of the proposed method of anti-erosion tillage in a steam field. The proposed method of soil cultivation was carried out in the conditions of the Saratov region, on the field of the Federal State Budget Scientific Institution "Research Institute of Agriculture of the South-East", after harvesting millet. The processed steam field was located on the slope of the southern exposure with a slope of 3-5 °. The soil is thin chernozem, soil moisture during cultivation in the autumn period in the arable layer was 22.3%, and soil hardness was 1.9 MPa. The stubble mass was 247 g / m ² , the stubble height was 21.4 cm. In the first half of September, continuous loosening of the soil with the formation of blown and non-blown wings was performed by a tillage implement [patent of the Russian Federation No. 2318303, cl. АВВ 13/16, А01В 49/02, application No. 2006127791 dated July 31, 2006, publ. 03/10/2008 in Bul. No. 7], additionally equipped with slit-offsets shifted from the center of the base of the formed wings to the side of the top of the slope and a device for introducing the drug into the windless wings to accelerate the decomposition of crop residues. The depth of processing by the loosening-cutting working bodies was 15.7 cm, the depth of the cuts under the base of the windproof wings was 28.6 cm. At the same time as the soil was cultivated across the slope, windrowing and windproof wings were created from crop residues, alternating between them, while non-blown backstage introduced the drug to accelerate the decomposition of crop residues STIMIX ^® NIVA A. The rate of application of the drug was 2 l / ha, the flow rate of the working fluid was 200 l / ha.

The first spring treatment in a steam field was carried out by a tillage implement additionally equipped with slithereas [patent of the Russian Federation No. 2612211, cl. АВВ 13/16, application No. 2015151672 dated 01.12.2015, publ. 03.03.2017 in Bul. No. 7], to a depth of 10 ... 12 cm. The depth of cut slits under the base of the windproof wings was 23.7 cm. Humidity in the upper soil layer of 0-10 cm was 20.3%. During the first and subsequent cultivations of the steam field in the spring-summer period, wind-blown scenes constantly moved up the slope by an amount equal to 28.3 ... 32.4 cm. The penultimate summer cultivation in the steam field was carried out by the same tillage implement with an additionally installed device for introducing granular mineral fertilizer in windproof wings. The application rate of nitrogen and phosphorus fertilizers was N ₄₀ P ₄₀ kg / ha of active ingredient.

Presowing cultivation on the steam field was carried out at an angle of 35-40 ° to the non-blown backstage to a depth of 6.7 cm. It was carried out by the KPS-4 cultivator equipped with BZTS-1,0 harrows. During the cultivation, windproof wings were evenly leveled by the working bodies of the cultivator and harrows on the treated surface of the steam field. Winter wheat was sown across the slope with SZP-3.6 seeders.

The prototype method was carried out in the same conditions, on the same field after harvesting millet, at the same time. In the autumn period, loosening of the soil with the formation of blown and non-blown wings was performed by a tillage implement [patent of the Russian Federation No. 2318303, cl. АВВ 13/16, А01В 49/02, application No. 2006127791 dated July 31, 2006, publ. 03/10/2008 in Bul. No. 7], additionally equipped with slitherels installed in the center of the base of the formed windproof wings. The average depth of cultivation by loosening-cutting working bodies was 16.1 cm, the depth of local soil-deepening by sluice was 29.3 cm. Simultaneously with the soil cultivation across the slope, blown and non-blown wings were created from crop residues. In the middle part, under the base of the windproof wings, a local soil deepening was carried out with slitherens.

The first cultivation in spring according to the prototype method in a steam field was carried out with a tillage implement equipped with flat-cutting legs to a depth of 10 ... 12 cm. The depth of the local soil deepening with gouges under the base of the windproof wings in their center was 24.2 cm. During the first and subsequent summer cultivations on the steam the field, windproof scenes moved constantly up the slope by a value of 27.7 ... 33.1 cm.

The pre-sowing cultivation of the steam field was carried out at an angle of 35-40 ° to the windproof wings to a depth of 6.7 cm with a KPS-4 cultivator equipped with BZTS-1.0 harrows. During the pre-sowing cultivation, the weeds were completely cut, while the windproof wings were evenly leveled by the working bodies of the cultivator and the harrows on the surface of the steam field. After that, winter wheat was sown across the slope with SZP-3.6 seeders.

In contrast to the prototype method, the introduction of a preparation into windproof scenes during their formation to accelerate the decomposition of crop residues and mineral fertilizers during the penultimate cultivation of the steam field, provided a more intensive decomposition of crop residues of the previous culture, increased the amount of nitrate nitrogen in the soil by the time of sowing winter wheat , which ultimately contributed to increased productivity.

In addition, since a local soil deepening was performed under the base of the windproof wings, in the form of cut gaps displaced from the center of the base of the windproof wings towards the top of the slope, the surface runoff was reduced, causing soil erosion on the slope lands.

Comparison of the proposed method of anti-erosion tillage in a steam field with the prototype method on sloping lands in the conditions of the Saratov region showed (tables 1, 2) that the total amount of rainfall in the form of rain for the period April-August was 119.2 mm. Of the 5 rains during this period, one rain was of a rainstorm character, the intensity of which was 0.18 mm / min, the amount of precipitation was 43.7 mm. The surface water runoff and soil washout on a steam field treated by the prototype method, in this case, amounted to 3.1 mm and 0.3 t / ha, respectively. In the area processed according to the proposed method, in such conditions, due to the fact that under the base of the windproof wings, slits are cut with an offset from the center of the base of the wings towards the top of the slope, less water is required to leak the flowing water into the cut holes and into deeper soil horizons time in contrast to the prototype method. In this regard, an insignificant amount of rain water was accumulating in front of the windproof wings, since it managed to seep through the wings into the cut gaps. Therefore, the overflow of water through the windproof wings in the proposed method was absent. In the prototype method, in places of depressions, there was an accumulation of water in front of the windproof wings and its overflow through them, as a result, water flow and soil erosion formed in such places.

In other cases, with precipitation, their intensity was low, water flow and soil erosion were absent in the compared methods for treating the steam field. During spring snowmelt, the surface runoff of melt water and soil runoff were completely absent in the compared tillage methods.

The introduction of the drug to accelerate the decomposition of crop residues STI-MIX ^® NIVA A in windproof wings when they are created at a dose of 2 l / ha with a working fluid flow of 200 l / ha ensured the decomposition of crop residues after harvesting from the first half of September to the end of August of the following year. millet by 75.3%. In the prototype method, this indicator in the variant without mineral fertilizers amounted to 37.9%, and with the introduction of mineral fertilizers in a dose of N ₄₀ P ₄₀ kg / ha of active substance, this indicator increased to 39.4%.

The joint application of the preparation in the steam field to accelerate the decomposition of the STIMIX®NIVA A crop residues in windproof wings during their creation and mineral fertilizers during the penultimate cultivation, provided an increase in the nitrate nitrogen content in the soil in comparison with the prototype method: in the variant without fertilizing by 24 %, in the variant with fertilizers by 9.3%. As a result, the application of the proposed method of anti-erosion tillage in a steam field made it possible to increase the yield of winter wheat in comparison with the prototype method: in the version without fertilizer by 15.8%, in the variant with fertilizer by 6.4%.

The application of the proposed method of anti-erosion tillage in a steam field on sloping lands improves the erosion resistance of the soil and the productivity of winter wheat.

Claims (2)

1. A method of anti-erosion tillage in a steam field, including the main tillage and simultaneous creation on the field surface of crop residues of blown and non-blown wings, alternating between each other and located across the slope, while during spring-summer cultivations in the steam field, winter wheat sowing, windproof wings are stored on the field surface and moved along the slope from the bottom upwards by an amount commensurate with their width, and under the base of the windproof wings when they are created and spring-summer cultivations, they perform local soil cultivation, characterized in that during the first primary tillage during the creation of windproof wings, a preparation is introduced in them to accelerate the decomposition of crop residues, and before the last cultivation, mineral fertilizers are introduced into windproof wings, while local soil deepening is performed in the form of cut gaps. 2. The method of soil treatment in a steam field according to claim 1, characterized in that the cut slots under the base of the windproof wings are offset from the center of the base of the wings to the top of the slope.

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