MD415Z - Process for directional formation of the root system in a portable perennial plant - Google Patents

Abstract

The invention relates to agriculture, in particular to a process for directional formation of the root system in a portable perennial plant, which can be used for initiation of vineyards, orchards, dendrological and ornamental plantings.The process for directional formation of the root system in a portable perennial plant includes bedding-out of plant roots in three cylindrical containers with nutrient medium of a height of 1.5 m and a diameter of 10…12 cm, combined in the form of a vertical tripod, made of plastic material and fitted with drains and twigs as a temporary support for annual increments of the plant, which are placed on the growth site by moving away the tripod basal parts by 25…30 cm, followed by cultivation, at the same time in the 10th year after planting the cylindrical containers are removed, and before permutation of plant it is carried out pruning of roots spread beyond the container at a depth of 10…20 cm.The result consists in increasing the individual productivity of plant, raising the level of control over plant growth and development, simplifying the plant permutation technology.

Description

The invention relates to agriculture, in particular to a process for directed formation of the root system of a multiannual, permutable plant that can be used for planting vineyards, orchards, dendrological and decorative plantations.

The process of directed formation of the root system is known when cultivating the plant in a pot or tub [1].

The disadvantage of the process is the need to replant the plant every year, or even more often, in a larger pot with more substrate, due to the rapid exhaustion of the substrate due to the biological activity of the roots and the oversaturation with salts, as a result of frequent watering.

The process of directed formation of the root system is also known in the case of producing vegetative vine cuttings in which the root system is placed in polyethylene bags or paper cups [2].

The disadvantage of the process is that the vegetation pots are small in volume and the root system cannot expand in the substrate in them to induce, through correlation, the growth of the plant's dimensions to the required level, to ensure maximum utilization of its productive potential and the possibility of permuting it without stress at any time of the year or exploitation period.

The process of directed formation of the root system of the vine cord in polyethylene hoses (placed horizontally on the soil surface) in the case of the production of interchangeable cords is also known [3].

The disadvantage of the process is that the soil-filled hoses, in which the roots are embedded, are not suitable for supporting the aerial part of the plant. In turn, the roots are poorly prepared to ensure stress-free replanting of the plant at any time during the exploitation period.

Closer to the claimed process is the process of directed formation of the root system of the vine stump replaceable in a vegetative pot (partially embedded in the soil), where the height is 40…45 cm, and the diameter is 30…35 cm. Holes with a diameter of 1.5 cm are made in the metal wall of the vegetative pot, through which the roots extend radially [4].

The disadvantage of the process is that the growing pot, filled with soil and containing the roots, is not suitable to serve as a support for the aerial part of the plant. And the plant is difficult to move due to the bulky, excessively radially extended roots.

The problems solved by the process, according to the invention, are the following: transplanting without stress for the plant, permuting and replanting the plant at any time of the year and of the exploitation period.

The process, according to the invention, includes planting the plant roots in three tubular containers with a nutrient substrate with a height of 1.5 m and a diameter of 10…12 cm, joined in the form of a vertical tripod, made of plastic and equipped with drains and twigs as a temporary support for the annual growth of the plant, which are placed on the vegetation site with the removal of the basal parts of the tripod at 25…30 cm, with subsequent cultivation, at the same time in the 10th year after planting the tubular containers are removed, and before the plant is permuted, the roots extended outside the container are cut at a depth of 10…20 cm.

The tubular container can also be obtained from a polyethylene film with a length of 1.5 m and a width of 0.75 m, which is laid on the soil surface, a layer of moistened substrate with a thickness of 3...5 cm is sprinkled on it, on top of which the drain and the twig are placed horizontally, after which the film is rolled into a roll, which is tied and perforated at the lower end.

If the configuration of the land intended for planting is complicated or has a steep slope, then it is necessary to use tubular containers with higher rigidity characteristics. In this case, the tubular container can be obtained from a plastic pipe with a diameter of 10…12 cm and a wall thickness of 1.5…2.0 mm, which is cut lengthwise, forming two symmetrical pieces, which are subsequently joined and fixed transversely by ties.

The tubular container can be obtained from 10 tubes with a length of 12…18 cm and a diameter of 10…12 cm, assembled consecutively one into the other and wrapped with a polyethylene film with a width of 15 cm, by partially overlapping the coils.

Cutting the roots extended outside the containers, when permuting the plant in the first 10 years after planting, is carried out in the spring before the start of vegetation, simultaneously under all three containers at a depth of 10...12 cm, and in the second decade after planting, the cutting is carried out the first time in the spring, until the start of vegetation, only under one container at a depth of 10...12 cm, the second time, immediately after harvesting the fruit, under the other two containers at a depth of 10...12 cm, and the third time, in late autumn or the following spring, the roots are cut simultaneously under all three containers at a depth of 18...20 cm.

The result is an increase in the individual productivity of the plant, an increase in the level of control over the growth and development of the plant, and a simplification of the plant permutation technology.

The advantages of the invention consist of the following: the need to replant the permutable plant from a small-volume container to another with a larger volume is eliminated; in the case where the vertical roots are allowed to extend freely outside the limits of the container, then due to the fact that they are shortened periodically (once every two to three years or annually) by limiting cuts, it is considerably easier to extract the plant from its initial location to be subsequently permuted and replanted on a new plot of land; the exhaustion of the substrate in the container no longer constitutes a factor that must be taken into account in the process of exploiting the plant; the container, in addition to carrying the substrate where the roots are located, constitutes a permanent support for the permutable plants (especially for those of the liana type, in which the annual growths are disposed to hang freely); Due to the fact that the plant's roots are scattered throughout a block of three containers, it is possible to form a tripod-shaped support for the plant, which can be easily adapted to the terrain configuration and, if necessary, adjusted and restored to its position in space, or, on a case-by-case basis, after the plant tilts (or overturns) under the weight of the crop, ice crusts, by a storm or as a result of soil erosion.

The invention is explained by the graphic representations in figures 1...3, taking the grapevine stump as an example:

- Fig. 1, placement of materials before construction, by twisting, of the tubular container;

- Fig. 2, block of three tubular containers carrying substrate, drains, twigs and roots of the vine stump, assembled in position for transportation or temporary storage in specially arranged rooms or on the vegetation plot;

- Fig. 3, final installation of the plant-bearing container block on the exploitation site, in the tripod-shaped support position.

The names of the structural elements of the tubular containers in which the roots of the vine trunk are incorporated are as follows:

1 - polyethylene film with a length of 1.5 m and a width of 0.8 m; 2 - substrate layer; 3 - drain made of a bundle of twigs; 4 - tubular container; 5 - plant root; 6 - plant stem; 7 - temporary support for annual growths arranged to hang freely; 8 - tie; 9 - hole; 10 - film cutting line; 11 - tie; 12 - spiral of narrow polyethylene film with which the tubular container is wrapped; 13 - polyethylene film with which the upper part of the tubular plant containers is wrapped; 14 - soil surface; 15 - clod of earth.

The procedure is carried out as follows.

The roots of the plant are planted in the nutrient substrate of the block of three tubular containers located on the vegetation plot, where the plants are cared for for a short period until they take root or this process is carried out directly on the permanent exploitation land. First, the tubular containers are built. For this, on the surface of a polyethylene film 1 (Fig. 1) with a length of 1.5 m and a width of 0.75 m, spread on the soil surface, a layer of substrate 2, slightly moistened, with a thickness of 3…5 cm is pressed, then above the substrate, the drain 3 with a thickness of 3…5 cm is placed horizontally, which is a bundle of rods obtained during the spring pruning of fruit trees. After that, the film is rolled up together with the substrate and drain, thus forming the tubular container with a diameter of 10…12 cm. In turn, each tubular container 4 (Fig. 2) is tightened in the basal part by the connection 8. The polyethylene film (wall) of the container in its basal part is perforated. The diameter of the holes 9 does not exceed 3 mm. Through them, water is drained after watering the substrate. The wall of the container in its basal part, at a height of 5 cm from the connection 8, is also perforated all around along the line 10. In this case, the diameter of the holes does not exceed 1 mm. In the transport condition, the containers in the block are tightly connected to each other by the connections 11 (Fig. 2). At the permanent place of exploitation of the plant, the basal parts of the containers are fixed on the surface of the soil (preliminarily processed) detached from each other, thus giving the block the shape of a tripod (Fig. 3). Before this, the containers are shortened in the basal part by cutting along the perforation line 10.

Subsequently, the basal parts of the containers are covered with a layer of soil 15. Each container is wrapped with a narrow polyethylene film, from top to bottom. The coils 12 partially overlap. Simultaneously with this bandaging operation, the containers are wrapped, on the inside of the coils, with straw or other plant debris in order to protect them from frost in winter and to avoid overheating of the substrate during vegetation. The top part of the container block is wrapped with a narrow polyethylene film 13 in order to ensure the rigidity of the block. Watering is carried out: in the upper part of the container - directly on the surface of the substrate and through the drain 3; around the basal part of the container - in the funnel that is made each time on the surface of the soil, then after watering it is plugged. During the planting year, the plant roots completely penetrate the substrate monolith in the three containers and anchor themselves in the soil. In the following years, the roots freely extend vertically and horizontally in the soil layers. Year after year, as the plant grows, most of the skeletal roots located in the substrate in the containers, which perform their main functions: anchoring, transporting water and nutrients, synthesizing organic substances, storing reserve nutrients, thicken and become rigid to the point that they alone perform the function of a tripod-shaped support for the plant. Over time, starting with the 10th year of operation, the monolithic substrate is freed from all polyethylene films (container walls). After such a dismantling of the containers, the substrate is washed away by rain and gradually falls off the roots. The aerial parts of the roots, being exposed, become even more rigid and perform the function of support for the plant. The agro-fund in the plantation is maintained according to the agrotechnical guidelines in force for perennial plants, in which annual growths are inclined to hang freely. If in the first 10 years after planting, when the plant is young, there is a need to move the block of containers carrying the plant, as a rule, in the spring before the start of vegetation, then immediately before its extraction from the initial place, the parts of the roots extending outside the containers are manually cut off, to a depth of 10…12 cm, using a regular shovel for clearing. After such an extraction operation, while preserving the earthen lump on the roots, the plant placed (replanted) on a new place of exploitation is guaranteed to take root and quickly restores its growth and development rhythm, due to the fact that the thickest parts of the skeletal roots of the plant are preserved intact, since they are placed in the monolithic substrate in the containers. In the second decade after planting, the plant must be prepared in advance for extraction, and the cutting of the roots must be more gentle. In this case, the cutting of the roots is carried out in three operations staggered in time: the first time in spring, before the start of vegetation, the roots are cut only under one container of the plant, at a depth of 10…12 cm; the second time, immediately after harvesting the fruit (between August 15 and October 15, depending on the ripening period of the grapes and fruits), the roots are cut under the other two containers of the plant, at a depth of 10…12 cm; the third time, immediately before extraction, in late autumn or the following spring, the roots are cut simultaneously under all three containers of the plant, at a depth of 18…20 cm.

If necessary, one and the same plant can be extracted from the soil, then permuted and replanted several times.

1. Овсянников I.В. Kadochnoe amateur fruit growing. Moscow, 1951, p. 27, 28, 32-53

2. Ursu V.A. Matochniki privy vines of intensive type and accelerated reproduction of grapes. Ed. "Shtiintsa". Chişinău, 1989, p. 144-146, 148-150, 153, 154

3. Богдан И. Portable grape cordon. Приложение к ж. «Сельское Хозяйство Мольдавиии», «Фазенда. Earth. Dom. Family», № 6, 1998, p. 5-7

4. Богдан И. The way to repair the vineyard. Приложение к ж. «Сельское Хозяйство Молдавиии», «Фазенда. Earth. Dom. Family», № 4, 1998, p. 6-8

Claims (5)

1. Process of directed formation of the root system of a multiannual permutable plant, which includes planting the plant's roots in three tubular containers with a nutrient substrate with a height of 1.5 m and a diameter of 10…12 cm, joined in the form of a vertical tripod, made of plastic and equipped with drains and twigs as a temporary support for the annual growth of the plant, which are placed on the vegetation site with the removal of the basal parts of the tripod at 25…30 cm, with subsequent cultivation, at the same time in the 10th year after planting the tubular containers are removed, and before the plant is permuted, the roots extended outside the container are cut to a depth of 10…20 cm. 2. Process according to claim 1, in which the tubular container is obtained from a polyethylene film with a length of 1.5 m and a width of 0.75 m, which is laid on the soil surface, a layer of moistened substrate with a thickness of 3...5 cm is sprinkled on it, above which the drain and the twig are placed horizontally, after which the film is rolled into a roll, which is tied and perforated at the lower end. 3. Process according to claim 1, in which the tubular container is obtained from a plastic pipe with a diameter of 10...12 cm and a wall thickness of 1.5...2.0 mm, which is cut lengthwise, forming two symmetrical pieces, which are subsequently joined and fixed transversely by ties. 4. Process according to claim 1, in which the tubular container is obtained from 10 tubes with a length of 12…18 cm and a diameter of 10…12 cm, assembled consecutively one into the other and wrapped with a polyethylene foil with a width of 15 cm, by partially overlapping the coils. 5. Process according to claims 1-4, in which the cutting of roots extended outside the containers, when permuting the plant in the first 10 years after planting, is carried out in the spring before the start of vegetation, simultaneously under all three containers at a depth of 10...12 cm, and in the second decade after planting, the cutting is carried out the first time in the spring, until the start of vegetation, only under one container at a depth of 10...12 cm, the second time, immediately after harvesting the fruit, under the other two containers at a depth of 10...12 cm, and the third time, in late autumn or the following spring, the roots are cut simultaneously under all three containers at a depth of 18...20 cm.