UA69028A - Method of presowing soil cultivation - Google Patents

Abstract

A method of soil cultivation includes differentiated forming of a sowing layer according to the magnitude of the aggregates and density of structure. The sowing layer is formed of three parts: an overseed layer is formed at a depth of 3-4 cm from aggregates of 5-20 mm with a density of 1.05-1.25 g/cm3; a seed layer is formed at a depth of 4-6 cm from aggregates of 0.25-5 mm and a density of 1.15-1.20 g/cm3; a underseed one is formed at a depth of 6-12 cm from the aggregates, which correspond to the natural structural composition of the soil, a density of which is no more than 1.35 g/cm3.

Description

Description of the invention

The invention relates to the field of agriculture, namely to the cultivation of the soil before sowing grain crops grown on loamy soils.

There is a well-known method of preparing the soil for sowing cereals, which includes early spring loosening with a disc harrow to a depth of 6-8 cm, surface treatment with cultivators with loosening paws (if the soil is excessively compacted before sowing, deep loosening is carried out with a chisel) and additional surface loosening with leveling of the soil surface with harrows and by rolling the soil with rollers |11. 70 The disadvantages of this method are the separation of technological operations, which leads to an excessive load of the engines of machine-tractor units on the ground and a significant unproductive consumption of fuel and lubricants. In addition, the seed layer, which is formed after such processing, has a uniform structure in terms of density and structural composition, which does not meet the requirements of grain ear crops |21.

There is also a known method of pre-sowing soil cultivation |Z), according to which technological operations are carried out along 72 pre-set tracks for the passage of engines of machine-tractor units. This method contributes to the reduction of soil compaction in the places where the tillage unit passes. However, the treated soil layer is also not differentiated by the density of the structure and structure, which again does not meet the optimal conditions for growing agricultural crops.

The closest to the proposed one in terms of technical essence is the method of soil cultivation, which includes the division of the seed layer into two parts: the upper (0-bsm), consisting of aggregates of size from 0.25 to Zmm and the lower, consisting of aggregates of size from 0, 25 to Zmm and with a structure density of 1.1-1.25 g/cm Z |4| taken by us as a prototype.

The disadvantage of this method is that it does not provide for the division of the sowing layer into agronomically important parts (supra-sedum, seed and sub-semal) with different parameters of the structure and density of the structure in accordance with the optimal conditions for growing grain ear crops. And it is also quite time-consuming, energy-intensive and inefficient under conditions of sufficient moisture, or in years with above-normal precipitation. The creation of a surface layer by a known method, the structure of which consists of fairly small aggregates of size from 0.25 to Zmm, requires intensive mechanical crushing, which in turn will lead to spraying and over-compaction of the soil, i.e., physical degradation. со 3о The basis of the invention is the task of improving the method of soil cultivation by layer-by-layer Ge! differentiated formation of the seed layer from 3 parts, which have optimal agrophysical characteristics in terms of the size of structural aggregates, the density of their structure and ensuring a decrease in the intensity of evaporation of moisture from the upper layer, close contact of seeds with the soil in the seed layer and slowing down of the processes of (Ge) convection and diffusion of moisture from the lower layers and, thus, the creation of favorable conditions for the growth and development of agricultural plants. oh

The task is solved due to the fact that in the known method of soil cultivation, which includes the differentiated formation of the seed layer according to the size of the aggregates and the density of the structure, according to the invention, the seed layer is formed from 3 parts: the seed layer is created at a depth of 3-4 cm from aggregates 5- 20 mm and density « 20 1.05-1.25 g/cm Z; the seed layer is formed at a depth of 4-bsm from aggregates of 5-0.25 mm and density of 1.15-1.20 g/cm 3; - the sub-seed layer is formed at a depth of 6-12 cm from aggregates that correspond to the natural structural composition of the soil and a density of no more than 1.35 g/cm 3. :z» Features common to the prototype - differentiated formation of the seed layer and formation criteria (agrophysical characteristics), but their parameters are different: From part of the seed layer, different structural composition and

The density of the structure. b The method is carried out as follows.

The main cultivation of the soil is carried out in the fall to a depth of 22-25 cm with a PLN-4-35 plow. Before sowing, the seed layer is differentiated into three parts (supra-seed, seed and sub-seed). The soil rises to a depth of 10-12 cm. Then it is arranged in the following sequence. First, a layer of 6-12 cm is formed. The density of the structure of this layer should not exceed 1.35 g/cm? (the upper level of the optimal range for grain and grain crops). Then a seed layer is formed at a depth of 3 cm, the thickness of this layer should be no more than 2-3 cm. The structural composition of the seed layer should have the following parameters.

The majority of the structure should consist of aggregates from 0.25 to 5 mm. The sum of these fractions should be at least 6095 and be in the range of 60-7595 from the sum of the structural individualities of the seed layer. The soil is sifted through sieves with a hole diameter of 0.25 and 5 mm. Such a structural composition corresponds to the largest extent to the size of the seeds of cereal grain crops. The sifted soil is placed on the seed bed

P" layer. The density of the structure in the seed layer is created in a narrow range of 1.15-1.20 g/cm. The seeds of grain crops are sown on the seed layer, a layer of soil is formed above the seeds, the structure of which is dominated by aggregates from 5 to 20 mm. The sum of these aggregates should be 50-6095 of the sum of all 60 fractions. The soil for the seed layer is sifted through holes with a diameter of 20 mm. The soil is laid over the seeds and compacted in such a way that the density of the structure of the seed layer is in the range of 1.05-1.25 g/cm 3. The seed layer obtained in this way helps to reduce the physical evaporation of the soil (unproductive consumption of soil moisture) and stabilize the structure and density of the seed layer during the growing season of an agricultural crop. The structure of the seed layer created by the proposed method 65 is shown in fig.

The proposed method can also be implemented using a known device |5). The method of pre-sowing processing is carried out as follows. The disk working bodies, rotating, feed the soil layer cut from the sides with a plow onto the grid that separates the soil and to the rotary working body. The seeds are fed through the seed tube to the coulter, which places them at the bottom of the furrow. A separating grid with rods lays down the rising soil

From the ploughshare, under the seed. The knives of the rotary working body pass between the bars of the grid, at the same time pushing the lumps of soil between the bars and cleaning the grid from stuck soil. The necessary compaction of the soil is carried out by a compactor, which ensures good contact of the seeds with the soil.

The structure of the sowing layer of the soil can be created with the help of serial tillage machines. So, loosening of the supra-seed layer and its compaction, loosening of the seed layer and its compaction, and/or creation of the density of the structure of the sub-seed layer can be carried out, for example, with discs with rollers, or sequentially installed arrow-shaped paws, spring teeth and rollers, or rotary working bodies with rollers and a harrow.

An example of the implementation of the method

Experiments were conducted in field conditions on 1x1 plots. Experiments were conducted on a site leveled according to 7/5 Bodyushchist and terrain. The soil is a typical heavy loamy, low-humus chernozem. The seed layer was formed in the following way. From the plot of the specified size, soil was removed to a depth of 12 cm (seed layer). The soil under the seed layer was placed in a pit, a sub-seed layer was created with a structure density of 1.30 g/cm 3.

The structure of this layer corresponded to the natural one (without sieving). On this layer with a depth of 6-12 cm, soil with a thickness of 2 cm was laid, first sifted through a sieve with a diameter of 5 mm, then through a sieve with a diameter of 25 mm. The sum of fractions with a size from 0.25 to 5 mm was 7095 of the mass of the entire soil of the seed layer.

The sub-seed layer was compacted by tamping in such a way that the density of the structure of this layer was 1.20 g/cm 3.

On this layer, barley seeds of the "Chornomorets" variety were sown at a rate of 500 seeds per square meter. A superseed (surface) layer was placed on top of the seed layer. The soil for this layer was separated on sieves: first it was sifted through a sieve with a diameter of 20 mm, then through a sieve with a diameter of 5 mm. The sum of all aggregates from 5 to 20 mm was 6095 masses of all structural units that make up the episperm layer. The soil was moderately compacted so that its structure density was 1.15 g/cm?. For the control version, the seed layer was formed according to a known method. The agricultural technique of growing barley according to the known and proposed methods was the same. Observation of plants and accounting of the harvest was carried out according to generally accepted methods.

The repetition of the experiment is 4 times. Field research was conducted for 5 years. The results of studies showed that the pre-sowing treatment according to the proposed method ensures better seed germination (seedlings appear 2-3 days earlier on the experimental variant than on the control), the seedlings are characterized by uniformity and completeness. This effect is due to the fact that the seeds are in close contact with the soil, the structure (а) of the seed layer corresponds to the size of the seeds and the requirements of the cereal grains (in this case, barley) to the agrophysical condition of the seed and, in general, the seed layers. During the growing season, barley according to phenological indicators was better in the variant with pre-sowing treatment according to the proposed method. The turbidity of barley sprouts was 50-6095 less also on the experimental version. This is due to the fact that the earlier and friendly seedlings of barley suppressed the growth of weeds. The results of field tests are given in table. 1.

Pre-sowing soil treatment according to the proposed method, as shown by field studies, contributes to "a significant reduction of physical evaporation from the surface of typical chernozem (by 9-2790), which preserves soil moisture reserves and promotes more efficient use by plants. It can be seen from Table 1 that the seed layer contains 3.7 mm (or 16.895) more tons of moisture than the control version (prototype). The yield of barley h was obtained by 20.595 more in the variant on which the soil was prepared for sowing according to the proposed method. Experimental verification of pre-sowing soil cultivation according to the proposed method using a combined soil tillage and sowing machine was carried out on chernozem podzolized heavy loam ("Komunar" experimental farm, Kharkiv district, Kharkiv region). Winter wheat, variety (2) "Myronivska-808" was grown. Research was conducted over 4 years. The seed layer according to the proposed method was differentiated with the following parameters: 1 - the seed layer contained aggregates from 5 to 20 mm - 4095; structure density - 0.95 g/cm3; the seed layer contained in its structure 5595 aggregates from 0.25 to Bmm, the density of its structure was 1.00 g/cm?; the sub-seed layer had a structure density of 1.15 g/cm3, "so 2 - the super-seed layer had a structure of 5095 units from 5 to 20 mm and a structure density of 1.05 g/cmU; the seed layer had a structure containing 6095 aggregates from 0.25 to 5 mm and a structure density of 1.15 g/cm?; the seed layer had a structure density of 1.25 g/cm3.

C - the episperm layer had a structure of 6095 aggregates from 5 to 2 Ohm and the density of the structure - 1.25 g/cm?; the seminal p layer had 7595 aggregates in the structure of the size from 0.25 to 5 mm and the density of the structure was 1.20 g/cm?; the seed layer had an added density of 1.35 g/cm 3.

Thus, according to the proposed method of pre-sowing processing with the help of a combined machine, a model of the seed layer was created with different parameters of the structure and density of the structure in 60 supra-seed, seed and sub-seed layers. Pre-sowing processing according to the proposed method with the help of a combined machine had positive results. The results are given in the table. 2. On the models of the sowing layer, created according to the proposed method of pre-sowing treatment, the seedlings of winter wheat appeared 3-4 days earlier than on the control version (prototype). The sowing layer created by the proposed method differs in that moisture evaporates from its surface by 10-1595 less than on the control; the water permeability of the seed layer according to the proposed method is higher by 40.8-113.996 than in the control,

the productive moisture content is 23-2895 higher than that of the control. On the options, where the seed layer was formed according to the proposed method with the help of a combined machine, significantly less weediness of winter wheat crops was observed (15-19 pcs/m2) than according to the prototype method (Zbpcs/m2, i.e. more by 58965). Thus, the seed layer of the soil, which is formed according to the proposed method, contributes to the reduction of physical evaporation of the soil and the preservation of soil moisture reserves, contributes to the intensive absorption of moisture from atmospheric precipitation and its accumulation in the soil. As a result, during the years of research, a stable increase in the yield of winter wheat grain was obtained (by 14-2695 more than in the control version). about (prototype) processing ate

Physical evaporation of moisture by rutem mm 00000000 zereztiyudentelyatov 00000000000005800000000000000520

Physical evaporation of the ox rhythm Ж 11111111

Shi nn by M plants):

Sufaatsatnyam about 000000000000000000006800000000000000000000090 and 1010000 plants):

How many Shuyans are there? 010686

F

(Se) (prototype) processing "from what with x"

Fo

Physical washing of root we 00000000010000000000800000000000000072001001 88 shi 1001 after processing) o va 72

IR e)

R

60 b5

Depth, sm a a ozh ze 2 Nganasivnevy ar: structure, and with NOV for 0-2 kt accuracy | La m

The seed layer, which is also a E si la ka seed layer: the urn is differentiated 1 6 ee Z 55 menya and psm' perel sowing Ki pe po o " t U To h Pip seed layer, which is not

In C, the soil is cultivated by sowing, as in A - vh |; i- has a moderately compacted macule of their Ryashkoya sv sya r YES Podorny layer is uniform and compacted and

Fig.

Claims (1)

The formula of the invention is the method of soil cultivation, which includes the differentiated formation of the seed layer according to the size of the aggregates and the density of the structure, which differs in that the seed layer is formed from 3 parts: the seed layer is created at a depth of 3-4 cm from aggregates of 5-20 mm with a density of 1, 05-1.25 g/cm; the seed layer is formed at a depth of 4-6 cm from 29 aggregates of 0.25-5 mm with a density of 1.15-1.20 g/cm; sub-seed - formed at a depth of 6-12 cm from aggregates that correspond to the natural structural composition of the soil, with a density of no more than 1.35 g/cm3. Official bulletin "Industrial Property". Book 1 "Inventions, useful models, topographies of integrated circuits", 2004, M 8, 15.08.2004. State Department of Intellectual Property of the Ministry of Education and Science of Ukraine. s «c) (o) (Se) - with . and? (o) se) ((c) ime) IR e) 60 b5