PL241554B1 - Method of growing plants - Google Patents

Abstract

The subject of the invention is a method of cultivating plants, in which the strips cultivated (1) of the soil in which the seeds of the arable plants are to be sown are loosened to a depth of 35 cm, between these strips (1) untreated strips (3) are left, with one driving a machine equipped with a disc coulter, loosening tines, a fertilizer dosing device, press wheels, seed coulters and copying and compacting wheels, mulch is removed and placed in non-cultivated belts (3), the role is loosened in cultivated belts (1), after After loosening the soil, mineral fertilizers are placed in its loosened cultivated strips (1), then the cultivated strips are compacted (1) with the press wheel of the machine, and after compaction, seeds of cultivated plants are sown in them, and then the soil is compacted with the copying-compacting wheel a machine that maintains sowing depth and increases water infiltration. The method is characterized in that the cultivated strip (1) is divided into cultivated streams (2) and fertilizer streams (4), in which mineral fertilizer is applied with the loosening tine of the machine, the cultivated strip (1) being divided into two streams cultivated (2), horizontally, between which fertilizer is applied in one stream of fertilizer (4), and one deeper cultivated stream (2), in a vertical arrangement.

Description

Description of the invention

The subject of the invention is a method of plant cultivation, in which strips of cultivated soil, in which seeds of cultivated plants are to be sown, are loosened to a depth of up to 35 cm, uncultivated strips are left between these strips, and in one pass of the machine, equipped with a disc coulter, the tines loosening, fertilizer dosing device, pressing wheels, coulters sowing seeds and depth-following and compacting wheels, mulch is moved away and placed in uncultivated strips, the soil is loosened in cultivated strips, after the soil is loosened, mineral fertilizers are placed in its scarified cultivated strips, then the strips are compacted cultivated using the press wheel of the machine, and after compaction, seeds of crop plants are sown in them, and then the soil is compacted using the copying and compacting wheel of the machine, which maintains the sowing depth and increases water infiltration.

Known from the state of the art is a method of tillage called strip tillage, otherwise also known as the English term "strip-till". The essence of strip tillage is deep, even up to 30-35 cm, loosening of the soil strips in which the seeds are sown and leaving the soil not loosened in the inter-rows. No tillage is carried out between the harvest of the forecrop and the sowing of the next crop. If this period is long and the soil dries quickly, its surface should be covered with mulch, e.g. shredded straw. The role of mulch in strip-till technology, as in other methods of ploughless cultivation, is very important. The plant mass on the surface of the field performs similar tasks as a thin layer of loosened soil after harvesting plants in classic plowing. It protects, for example, the lower layers against excessive heating, water evaporation and drying. In the field, after tillage and sowing carried out in the strip-till technology, there are two soil spaces with different properties. The first one is a strip of loosened soil. It has much less density and compactness, it contains more air. Mineral fertilizers and seeds are placed in this belt. This soil heats up easily, and it has not been overdried with other crops before, creating favorable conditions for germination and quick, even emergence of plants. In the inter-rows, the soil is not loosened, it retains water infiltration from deeper layers. Plant residues on the surface limit its evaporation, and in winter they cause an even distribution of snow on the field, even in sculpted terrain. This has a positive effect on the wintering of plants. Strip-till technology may consist of two independent agrotechnical activities spread over time. First, strips of soil are cultivated, and then seeds are sown into the prepared soil, depending on the type of sown crops - with or without the use of satellite navigation. Modern designs of aggregates, e.g. Mzuri brand, allow you to cultivate strips of land, apply mineral fertilizers and sow seeds at the same time. Mineral fertilizers are placed in a deeply loosened strip of soil, several centimeters wide. The press wheel of the aggregate compacts this soil, and the sowing unit places the seeds in it. Behind the sowing section there are wheels that maintain the sowing depth and press the soil to increase water infiltration. Optionally, there are also spring-loaded roll aligners. In addition, such a unit can be equipped with an applicator of granules - microfertilizers, plant protection products, but with a fixed place of dosing them.

The advantages of the strip-till technology are visible mainly in unfavorable habitat conditions, such as mosaic soil or very dry soil. Then, traditional plowing is difficult, and plant emergence is delayed and uneven.

The technology of strip tillage and simultaneous sowing also has some drawbacks. It requires careful fragmentation and even distribution of post-harvest residues (straw, beet leaves, biomass of catch crops) over the entire surface of the field. Only such preparation of the field eliminates "clogging" of the working elements of the unit with plant residues and enables precise sowing, especially narrow-row sowing. If straw is harvested from the field and its surface is not covered with mulch, strip tillage and sowing must follow immediately after harvesting the forecrop. Otherwise, in the absence of rainfall, there is a deep drying of the soil and problems with the emergence of plants. Tillage systems and methods that leave a lot of plant residue on the field surface, including strip-till technology, carry the risk of changing the structure of weeds, as well as increased pressure of diseases and pests.

Strip tillage is considered to combine the positive aspects of deep tillage and no tillage. This method can be used in rapeseed, soybean, sugar beet, maize and sunflower crops. However, it creates similar soil conditions in all cultivated strips, which limits the simultaneous cultivation of plants with different requirements.

PL 241 554 B1

Cultivating aggregates for strip tillage consist, to a large extent, of tools cultivating the soil - a cultivator, and sowing seeds - a seeder, while currently the tools for strip tillage are combined with fertilizer dispensers. As already mentioned, the basic elements of such an agricultural machine are: loosening elements (e.g. loosening coulters or cutting discs), fertilizer dosing devices (e.g. fertilizer coulters), sowing devices (e.g. sowing coulters), pressing and compacting elements (e.g. or shafts). The loosening elements are placed at certain intervals from each other, causing the soil to be loosened only in the places where they work. The spacing of these elements depends on the type of plants to be cultivated. During one pass of the set, several to a dozen or so strips (depending on the number of loosening elements) of soil loosened to a depth of up to several dozen centimeters and a width of several centimeters are obtained, with soil conditions similar to the growth of plants in each strip. Strips of undisturbed soil will remain between them and they will constitute at least half or even 2/3 of the total area for cultivation.

In strip-till cultivation with the use of the aggregate, in one pass of the machine it is possible to till the soil, sow fertilizers, sow seeds of crop plants and sometimes, additionally, also sow seeds of catch crops and apply plant protection products, but with a limited choice of where to place them in the soil relative to crop seeds. Such cultivation saves a lot of fuel and working time. This system also ensures less evaporation of water from the soil, more even emergence of plants and higher yields in extreme weather conditions - dry or wet years.

The application of fertilizers in this method is precise - they are dosed only to the cultivated soil space, which means that nutrients are in the immediate vicinity of the roots of growing plants and enables their more effective use by plants. In this way, soil devoid of crops is not fertilized, which reduces the risk of environmental pollution. Fewer fertilizers are used per unit area. However, too close proximity of fertilizer to plant roots can cause their damage and death of young plants. The wide spacing of rows and the lack of plowing are conducive to pests, e.g. weed infestation and the occurrence of volunteer forecrops. Excessive use of this method in the field therefore forces a change in the direction of cultivation over time (to transverse). However, this is not always possible due to the configuration of the fields.

The purpose of this solution is to eliminate the disadvantages known from the state of the art, including the reduction of the risk of pests, the universalization of the method of plant cultivation to different habitat conditions and to different requirements of crops with regard to agricultural technology elements, as well as to increase the number of agricultural operations performed during a single pass of the machine.

This solution enables better fragmentation and arrangement of plant residues, which reduces the possibility of clogging of the aggregate elements and deterioration of their operation or damage. In addition, the possibility of arranging plant residues in different ways ensures, depending on the needs and agrotechnical conditions, faster drying of the soil or limiting its drying out.

The invention also enables more precise dosing of the fertilizer, not in the immediate vicinity of the seeds of crop plants, which reduces the contact of sown and germinating seeds with the fertilizer at different requirements of individual crops.

In addition, the invention provides the possibility of individualizing soil compaction in individual strips, which serves to obtain the same soil density in different strips (which is required to standardize the conditions for the emergence of plants of the same species) or different soil density in subsequent strips (this allows sowing plants with different requirements in terms of soil compaction in successive strips - mixtures, organic farming).

The method according to the invention also makes it possible to adjust the depth of sowing seeds and embedding plants in relation to the soil surface, which has a beneficial effect on their emergence, because the ridges formed by the sowing coulters, with the possibility of adjusting their height, protect young plants from environmental factors - wind, frost.

The invention also makes it possible to obtain different depths of sowing the seeds of the catch crop and different widths of the strip of undersown plants, thus varying the depth of covering the seeds of the catch crop with soil.

In addition, the invention provides the possibility of directing streams of microgranulates to different places in relation to the coulter sowing the seeds of the crop plant, and thus enables their precise

EN 241 554 B1 action depends on the requirements of crops, catch crops and the need to reduce the presence of pests.

The variable profile of the copying and compacting wheel, adapted to the streams of sown seeds and the type of soil, also ensures optimal conditions for plant emergence and the operation of microgranulates in various habitat conditions.

To sum up, the advantage of the method according to the invention is therefore the non-homogeneous impact of the working elements of the multifunctional, hybrid machine (agricultural aggregate) on the soil of the cultivated field. After its single passage, strips and streams of soil with different properties and agrotechnical functions are formed.

The subject of the invention is a method of plant cultivation, in which strips of cultivated soil, in which seeds of cultivated plants are to be sown, are loosened to a depth of up to 35 cm, uncultivated strips are left between these strips, and in one pass of a machine equipped with a disc coulter, loosening tines, fertilizer dosing device, press wheels, seed sowing coulters and depth-following and compacting wheels, mulch is moved away and placed in uncultivated strips, the soil is loosened in cultivated strips, after the soil is loosened, mineral fertilizers are placed in its scarified cultivated strips, then compacted the belts are cultivated with the press wheel of the machine, and after compaction, the seeds of crop plants are sown in them, and then the soil is compacted with the help of the copying and compacting wheel of the machine, which maintains the sowing depth and increases water infiltration. The invention is characterized in that the cultivated strip is divided into cultivated streams and manure streams, in which mineral fertilizer is applied by means of the loosening tooth of the machine, and the cultivated strip is divided into two cultivated streams, in a horizontal arrangement, between which in one stream of fertilizer fertilizer is applied, and one deeper stream is cultivated, in a vertical arrangement.

Preferably, the cultivated strip is divided into streams cultivated by means of a loosening tine equipped with two levels of looseners spaced on the sides of the leg.

It is also advantageous if centrally applied fertilizer is cultivated in a deeper stream.

It is good if the short mulch is placed in two streams of biomass, in each uncultivated strip.

It is better if the short mulch is laid with a disc coulter working at an adjustable angle in relation to the direction of travel.

It is good when the long mulch is placed in two streams of biomass, in each uncultivated strip.

It is also good when long mulch is placed in one biomass stream, in every other uncultivated strip.

It is also advantageous if the depth of application of the fertilizer is adjusted by adjusting the height of the outlets of the fertilizer channels of the fertilizer dosing device.

Preferably, each cultivated strip is compacted individually using a pneumatic press wheel, with compaction controlled by independent hydraulic pressure of each press wheel, adjusting the air pressure in the wheel or tire profile.

It is also good when the crop seeds are sown in one seed stream asymmetrically to the centrally placed fertilizer stream in the cultivated strip.

It is also advantageous if the crop seeds are sown in two seed streams symmetrically to the centrally placed fertilizer stream.

Preferably, the height of the ridges formed by the sowing coulter is adjusted by changing the sowing coulter.

More preferably, the seeds of the crop plants are sown by means of a sowing coulter with an asymmetric seed outlet.

It is also more advantageous if the seeds of the crop plants are sown by means of a sowing coulter with a symmetrical seed outlet.

It is advantageous if the seeds of the catch crop are sown simultaneously with the sowing of the crop seeds, the seeds of the catch crop being directed in front of, behind or next to the coulter sowing the crop seeds in one or two streams of the catch crop.

It is better if the catch crop seeds are introduced into the coulter that sows crop seeds.

PL 241 554 B1

Preferably, the stream of microgranulates containing mineral fertilizers or plant protection products is directed before or after the coulter sowing seeds of crop plants, from one or both sides of the stream of seeds of crop plants.

It is also good when a stream of microgranules containing mineral fertilizers or plant protection products is introduced into the sowing coulter and mixed with a stream of crop seeds.

It is good if the stream of microgranulates containing mineral fertilizers or plant protection products is directed to the surface of the belts cultivated behind the copying and compacting wheel.

It is also advantageous when the stream of microgranulates containing mineral fertilizers or plant protection products is directed into strips of uncultivated soil.

It is advantageous if the compaction of the soil with the depth gauge wheel is adjusted by replacing the depth gauge wheel with a wheel with a different profile.

It is also good when, after sowing, the soil is leveled with a leveling harrow, placed behind the sowing coulter, with an adjustable, sliding tine spacing and an adjustable angle of inclination of the tines relative to the soil surface.

Preferably, additionally, plant protection products, biostimulators or fertilizer solutions are sprayed with the use of spray jet guides and shields.

It is better if the working liquid of plant protection products, biostimulators or fertilizer solutions is sprayed in the cultivated strip, in the uncultivated strip or over the entire soil surface.

It is also better if the working liquid of plant protection products, biostimulators or fertilizer solutions is sprayed before or after the coulter sowing the seeds of crop plants.

It is also better if the working liquid of plant protection agents, biostimulators or fertilizer solutions is additionally sprayed before or after the leveling harrow.

The subject of the invention is presented in the examples of embodiment in the drawing, in which Fig. 1 shows a cultivation scheme in an embodiment, Fig. 2 shows one of the embodiments in the field of mulch depositing places, Fig. 3 shows an alternative embodiment in the field of mulch depositing places, Fig. Fig. 4 shows one embodiment of crop seeds sowing locations, Fig. 5 shows an alternative embodiment of crop seeds sowing locations, Figs. 6 and 7 show embodiments of catch crop seeds sowing locations, Fig. 8, 9 and 10 show embodiments in the field of directing the stream of microgranulates containing mineral fertilizers or plant protection products, fig. 11 shows another embodiment of a loosening tooth, fig. 12 shows one embodiment of a sowing coulter, fig.

In the method for growing plants according to the invention, the cultivated strips in which the crop seeds are to be sown are loosened to a depth of up to 35 cm. Between these strips 1, uncultivated strips 3 are left, and in one pass of the machine equipped with a disc coulter, loosening tines, fertilizer dosing device, press wheels, seed sowing coulters 13 and copying and compacting wheels 9, the mulch is moved away and placed in strips uncultivated 3, the soil is loosened in the cultivated strips 1, after the soil is loosened, mineral fertilizers are placed in its loosened cultivated strips 1, then the cultivated strips 1 are compacted with the machine's press wheel, and after compaction, seeds of crop plants are sown in them, and then compacted the soil is spread by means of the copying and compacting wheel 9 of the machine, which maintains the sowing depth and increases water infiltration. The cultivated strip 1 is divided into cultivated streams 2 and fertilizer streams 4, in which mineral fertilizer is applied with the machine's loosening tines.

In the embodiment shown in Fig. 1, the cultivated strip 1 is divided into two cultivated streams 2, arranged horizontally, between which fertilizer is applied in one stream 4, and one deeper cultivated stream 2, arranged vertically. In one embodiment, fertilizer is centrally applied in the deeper crop stream 2. Preferably, a loosening tooth is used equipped with two levels of conditioners 10 spaced on the sides of the leg 11, shown in Fig. 11. Also visible in Fig. 11 are the outlets 12 of the fertilizer channels. In one embodiment of the invention, the depth of fertilizer application is adjusted by adjusting the height of these outlets 12.

In the preferred embodiment of the method according to the invention, shown in Fig. 2, a short mulch or a long mulch is placed in two biomass streams 8, in each uncultivated lane

PL 241 554 B1 3. Short mulch can be laid with a disc coulter working at an adjustable angle in relation to the direction of travel.

In one embodiment, shown in Fig. 3, long mulch is placed in one biomass stream 8, in every other uncultivated strip 3.

In one embodiment, each cultivated strip 1 is individually compacted by a pneumatic press wheel, the compaction being controlled by independent hydraulic pressure of each press wheel, wheel air pressure adjustment, or tire profile.

Fig. 4 shows that, according to the invention, the seeds of crop plants can be sown in one seed stream 5 asymmetrically to the centrally located fertilizer stream 4 in the cultivated strip 1. A sowing coulter 13 with an asymmetric seed outlet 14, shown in Fig. 12, is preferably used. Alternatively (fig. 5), crop seeds can be sown in two seed streams 5, symmetrically to the centrally placed fertilizer stream 4. For this purpose, a sowing coulter 13 with a symmetrical seed outlet 14, shown in fig. 13, can be used.

The height of the ridges formed by the seeding coulter 13 is adjusted in the preferred embodiment by changing the seeding coulter 13.

In one embodiment, catch crop seeds are undersown simultaneously with the sowing of the crop seeds, with the catch crop seeds being directed in front of, behind or beside the crop seed coulter 13 in one or two catch crop streams 6. Fig. 6 shows an example of in which catch crop seeds are sown in two catch crop streams 6 next to the sowing coulter 13. Fig. 7 shows an example in which the catch crop seeds are directed in front of (fig. 7a) and behind (fig. 7b) the sowing coulter 13. The arrow indicates the direction crops. The coulter 13 is not shown in these figures. In one embodiment, catch crop seeds are introduced into the seeding coulter 13 of crop seeds.

In a certain embodiment, the stream of microgranulates 7 containing mineral fertilizers or plant protection products is directed in front of (Fig. 8a, the arrow indicates the direction of cultivation) or behind (Fig. 8b, the arrow indicates the direction of cultivation) the coulter sowing 13 seeds of crop plants, from one or two sides of the crop seed stream 5 (Fig. 9). In one embodiment, the stream of micro-granulates 7 is introduced into the seeding coulter 13 and mixed with the stream of crop seeds 5. In one of the embodiments, the stream of microgranulates 7 is directed to the surface of the cultivated strips 1 behind the copying and compacting wheel 9 (fig. 10, the direction of cultivation is indicated by the arrow). In another embodiment, a stream of microgranulates 7 is directed into strips of uncultivated soil 3.

In one embodiment, the compaction of the soil with the depth gauge wheel 9 is adjusted by replacing the depth gauge wheel 9 with a wheel of a different profile.

In one embodiment, after sowing, the soil is leveled by means of a leveling harrow located behind the sowing coulter 13, with an adjustable, sliding tine spacing and an adjustable angle of inclination of the tines relative to the soil surface.

In the method according to the invention, plant protection agents, biostimulators or fertilizer solutions can additionally be sprayed by means of guides and shields of spray liquid streams. The working liquid can be sprayed in the cultivated strip 1, in the uncultivated strip 3 or on the entire surface of the soil, in front of or behind the coulter 13 sowing crop seeds. Alternatively, the spray liquid is sprayed before or after the leveling harrow.

Of course, the invention is not limited to the shown embodiments and various modifications are possible within the scope of the patent claims without departing from the essence of the invention.

Claims (26)

Patent claims 1. A method of plant cultivation, in which cultivated strips (1) of the soil in which crop seeds are to be sown are loosened to a depth of 35 cm, uncultivated strips (3) are left between these strips (1), and in one pass machine, equipped with a disc coulter, loosening tines, fertilizer dosing device, press wheels, seed sowing coulters (13) and ground following and compacting wheels (9), the mulch is moved PL 241 554 B1 and placed in uncultivated strips (3), the soil is loosened in cultivated strips (1), after the soil is loosened, mineral fertilizers are placed in its loosened cultivated strips (1), then the cultivated strips are compacted (1) with a pressing wheel machine, and after compaction, seeds of crop plants are sown in them, and then the soil is compacted with the help of a copying-compacting wheel (9) of the machine that maintains the sowing depth and increases water infiltration, characterized in that the cultivated strip (1) is divided into cultivated streams (2) and fertilizer streams (4), in which mineral fertilizer is applied with the machine's loosening tooth, where the cultivated strip (1) is divided into two cultivated streams (2), in a horizontal arrangement, between which in one fertilizer stream ( 4) fertilizer is applied, and one deeper stream is cultivated (2), in a vertical arrangement. 2. A cultivation method according to claim 1, characterized in that the cultivated strip (1) is divided into cultivated streams (2) by means of a loosening tooth equipped with two levels of looseners (10) spaced on the sides of the leg (11). 3. A cultivation method according to claim 1, characterized in that in the deeper cultivated stream (2) the fertilizer is centrally applied. 4. The method of claim 1, characterized in that the short mulch is placed in two biomass streams (8), in each uncultivated strip (3). 5. The method of claim 4, characterized in that the short mulch is laid by means of a disc coulter working at an adjustable angle in relation to the direction of travel. 6. The method of claim 1, characterized in that the long mulch is placed in two biomass streams (8), in each uncultivated strip (3). 7. The method of claim 1, characterized in that the long mulch is placed in one biomass stream (8), in every other uncultivated strip (3). 8. The method of claim 1, characterized in that the depth of fertilizer application is regulated by adjusting the height of the outlets of 12 fertilizer channels of the fertilizer dosing device. 9. The method of claim The method of claim 1, characterized in that each cultivated strip (1) is compacted individually by means of a pneumatic press wheel, and the compaction is controlled by independent hydraulic pressure of each press wheel, regulation of air pressure in the wheel or tire profile. 10. The method of claim 1, characterized in that the seeds of crop plants are sown in one stream of seeds (5) asymmetrically in relation to the centrally placed stream of fertilizer (4) in the cultivated strip (1). 11. The method of claim 1, characterized in that the seeds of crop plants are sown in two streams of seeds (5), symmetrically in relation to the centrally placed stream of fertilizer (4). 12. The method of claim Characterized in that the height of the ridges formed by the sowing coulter (13) is adjusted by changing the sowing coulter (13). 13. The method of claim 10, characterized in that the seeds of crop plants are sown by means of a sowing coulter (13) with an asymmetric seed outlet (14). 14. The method of claim 11, characterized in that the seeds of crop plants are sown by means of a sowing coulter (13) with a symmetrical seed outlet (14). 15. The method of claim Seeds of the catch crop are sown simultaneously with the sowing of the crop seeds, the seeds of the catch crop being directed in front of, behind or next to the sowing coulter (13) of the crop seeds in one or two streams of the catch crop (6). 16. The method of claim 15, characterized in that catch crop seeds are introduced into the sowing coulter (13) of crop seeds. 17. The method of claim 1, characterized in that the stream of microgranulates (7) containing mineral fertilizers or plant protection products is directed in front of or behind the sowing coulter (13) of crop plant seeds, on one or both sides of the stream of crop plant seeds (5). 18. The method of claim 1, characterized in that the stream of microgranulates (7) containing mineral fertilizers or plant protection agents is introduced to the sowing coulter (13) and mixed with the stream of crop seeds (5). PL 241 554 B1 19. The method of claim 1, characterized in that the stream of microgranulates (7) containing mineral fertilizers or plant protection products is directed to the surface of cultivated belts (1) behind the copying and compacting wheel (9). 20. The method of claim 1, characterized in that the stream of microgranulates (7) containing mineral fertilizers or plant protection products is directed into uncultivated strips (3) of the soil. 21. The method of claim 1, characterized in that soil compaction with the ground-following-compaction wheel (9) is regulated by replacing the ground-following-compacting wheel (9) with a wheel of a different profile. 22. The method of claim 1, characterized in that after sowing, the soil is leveled with the use of a leveling harrow, placed behind the sowing coulter (13), with an adjustable, sliding tooth spacing and an adjustable angle of inclination of the tines relative to the soil surface. 23. The method of claim Plant protection products, biostimulators or fertilizer solutions are sprayed with the use of guides and shields of spray liquid streams. 24. The method of claim 23, characterized in that the working liquid of plant protection products, biostimulators or fertilizer solutions is sprayed in the cultivated strip (1), in the uncultivated strip (3) or on the entire soil surface. 25. The method of claim 23, characterized in that the working liquid of plant protection products, biostimulators or fertilizer solutions is sprayed before or after the coulter (13) sowing crop seeds. 26. The method of claim 22, characterized in that the working liquid of plant protection products, biostimulators or fertilizer solutions is sprayed before or after the leveling harrow.