RU2199198C1 - Drained soil cultivation method - Google Patents

Abstract

FIELD: agriculture. SUBSTANCE: method involves cultivating field surface; forming ridges and applying mineral fertilizer. Field surface cultivation involves compacting soil portion along bed axes, applying mineral fertilizer onto compacted portions and forming ridges over fertilizer. Width of compacted strips is at least 0.7 the width of bed base. EFFECT: reduced washing out of fertilizer from bed body into base and furrows. 2 cl, 1 dwg

Description

 The invention relates to the field of agriculture, and more specifically to methods for processing drained lands.

 There are many known methods of cultivating drained land described in the book by Eggelsmann R. Guidelines for drainage. L .: Kolos. 1984, p. 80-83 and Aleksashin V.A., Alpatiev A.V., Andreeva R.A. et al. / Composition. Bryzgalov V.A. Handbook of vegetable growing. L .: Kolos. 1982, p. 352-353. The treatments are aimed at accelerating the discharge of surface and soil waters outside the drained area.

 A disadvantage of the known processing methods is the increased removal of mineral fertilizers and pollution of the water intake, groundwater.

 The closest in terms of technical features and the achieved result is a method of processing drained lands, including processing the surface of the field, applying mineral fertilizers, planting them in the soil by cultivation or harrowing, forming ridges. The method is described in the book: Aleksashin V.A., Alpatiev A.V., Andreeva R.A. et al. / Composition. Bryzgalov V.A. Handbook of vegetable growing. L .: Kolos. 1982, p. 355.

 A disadvantage of the known processing method is the increased leaching of mineral fertilizers from the body of the ridge to the furrows and to the base of the ridge. This is due to the fact that fertilizers are evenly distributed in the body of the ridge and the base has increased loosening and water permeability. During irrigation and precipitation, filtration flows pass through the body of the ridge. They wash fertilizers into furrows and subsoil horizons. Fertilizer discharges pollute the environment and the water intake.

The aim of the invention is to reduce the leaching of mineral fertilizers from the body of the ridge to the furrows and subsurface horizons of the base of the ridge, the elimination of environmental pollution
This goal is achieved by the fact that during processing, the surface areas of the field are compacted along the longitudinal axis of the ridges, then mineral fertilizers are applied to the compacted areas, and ridges are formed above them. The width of the compacted sections of the field is not less than 0.7 of the width of the base of the ridge.

The proposed technical solution characterizes the following set of essential features:
1) field surface treatment;
2) the application of mineral fertilizers;
3) formation of ridges
and distinguishing features:
4) during processing, the surface areas of the field are compacted along the longitudinal axis of the ridges;
5) then, mineral fertilizers are applied to the compacted areas;
6) ridges are formed above the densified areas;
7) the width of the compacted strips is not less than 0.7 of the width of the base of the ridge.

 The specified set of essential features is sufficient, and each of them is necessary to achieve the objective of the invention.

 Surface treatment of the field provides for its alignment. This ensures uniform distribution of fertilizers over the field surface. The formation of the ridge gives the field surface increased slopes from the axis of the ridges to the furrows. This accelerates the discharge of irrigation and rain excess water from the field surface, which eliminates the overmoistening of the surface of the drained area. The application of fertilizers ensures even distribution of fertilizers on the field surface. Filtration flows of discharged water are directed from the surface of the ridge to the furrows and to the base of the ridge. They intensively dissolve mineral fertilizers and carry out solutions into the water intake, subsurface horizons and groundwater.

 Distinctive features provide a decrease in the intensity of leaching of mineral fertilizers by reducing the speed of filtration and the duration of contact of fertilizers with filtration flows. The compaction of a portion of the strip of the field surface under the base of the ridge significantly reduces the rate of filtration into subsurface horizons, and the placement of mineral fertilizers with a thin layer on the compacted surface at the base of the ridge reduces the contact time of water flows filtered through the body of the ridge. This significantly reduces the intensity of the discharge of mineral fertilizers from the body of the ridge. Fertilizers on compacted areas in the soil do not close up, but cover them with the base of the formed ridge.

 In the absence of irrigation and precipitation, fertilizer solutions due to capillary rise are suitable for seeds or seedlings that are placed at the surface of the ridge.

 When the width of the compacted strip is less than 0.7 of the width of the base of the ridge, a substantial amount of fertilizer is washed out of the body through the un-compacted part of the base. Increasing the width of the compacted strip over 0.7 from the width of the base of the ridge increases the cost of compaction without significantly reducing the leaching of fertilizers from the body of the ridge.

 Thus, the distinctive features in comparison with the prototype provide a reduction in the discharge of mineral fertilizers from the body of the ridge by reducing the filtration rate through its compacted base and reducing the contact time of fertilizers with filtration flows when placing fertilizers unevenly in the body of the ridge, and with a thin layer on the compacted base.

 The drawing is a perspective view of a sectional view of a field profile processed by the proposed method. When treating the surface 1 of the field, sections 2 of the surface 1 of the field are densified along the longitudinal axes of 3 ridges 4 separated by grooves 5. Then, fertilizers 6 are applied to the densified sections 2, which are covered with the base of the formed ridge 4. The main directions of the filtration flows through the body of the ridge 4 are shown by arrows 7 .

 An example of the implementation of the method of processing drained lands.

The site is located in the Moscow region. It is drained by systematic horizontal drainage. The interdental distances are 14 m. The depth of the drains is 1.0 m. The soil is mechanically composed of loamy soil. The surface of 1 field is leveled by the combined RVK-3.6 unit. The compaction of sections 2 of the surface 1 of the field along the longitudinal axes of 3 ridges 4, separated by grooves 5, the application of fertilizers 6 to the densified sections 2 and the formation of ridges 4 is carried out simultaneously with a converted furrow cutter - profiler BON-5.4. BON-5.4 was additionally equipped with sealing rollers and a mechanism for supplying mineral fertilizers to the densified areas of the field. The length of the rollers is 1.1.1 and 1.3 m. BON-5.4 simultaneously forms three ridges 18–25 cm high and 1.4–1.6 m wide. The width of the compacted strip under the base of the ridges varies from 1.0 to 1.3 m (0.6–0.8 of the width of the base of the ridge). The thickness of the compaction layer varies within 3-4 cm. The permeability of the compaction layer is 0.15 m / day. 5 times less water permeability of the unconsolidated field surface, which is 0.75 m / day. Mineral fertilizers were applied to the compacted surface at the rate of nitrogen 110, potassium 70 and phosphorus 40 kg / ha of the active substance. Then, ridges 1.6 m wide and 22 cm high were formed over the compacted strips. Watering was carried out at a rate of 200 m ³ / ha.

 The washing out of nitrogen fertilizers from the body of the ridge to the furrows and to its base was recorded. The amount of nitrogen fertilizer leaching in the active substance was 18 kg / ha with a width of the compacted strip 0.6 of the width of the base of the ridges, 11 kg / ha with the width of the compacted strip 0.7 of the width of the base of the ridge and 10 kg / ha with the width of the compacted strip 0.8 of the width of the base of the ridge.

In the same area, a prototype method was implemented. The field plot was leveled by the VRK-3.6 combined unit. Fertilizers were applied in doses of the active substance per hectare: nitrogen 110, potassium 70 and phosphorus 40 kg. BON-5.4 aggregate formed ridges. Watering was carried out at a rate of 200 m ³ / ha. The leaching of nitrogen fertilizers in the active substance from the body of the ridge was 35 kg / ha.

 Amager cabbage was grown on the drained massif. Yields in areas with different processing technologies did not differ significantly.

 Thus, the proposed technical solution in comparison with the prototype provides a 3.5-fold reduction in the leaching of nitrogen fertilizers from the body of the ridge due to compaction of its base and application of fertilizers to the compacted surface.

Claims (2)

 1. A method of processing drained land, including processing the surface of the field, forming ridges, applying mineral fertilizers, characterized in that during processing, the surface areas of the field are compacted along the longitudinal axis of the ridges, then mineral fertilizers are applied to the compacted areas and ridges are formed above them.  2. The method of processing drained lands according to claim 1, characterized in that the width of the compacted strips is not less than 0.7 of the width of the base of the ridge.