MD604Z - Process for the formation of a flexible and movable perennial plant - Google Patents

Abstract

The invention relates to agriculture, in particular to a process for the formation of a flexible and movable perennial plant.The process, according to the invention, includes planting of plant in a culture pan which is formed near two planting holes, by means of two symmetrical chutes in the shape of a truncated cone made of tin, arranged horizontally, inside which is laid an oilcloth sheet and a polyethylene sheet, afterwards the chutes are filled with substrate with subsequent ramming and watering of substrate after planting and gradual removal of the chutes with the fixation of longitudinal twigs and simultaneous winding with a cord of the portions removed from the chutes. Then the culture pan is moved on the line between the planting holes, and its ends are folded and introduced into the holes, which are filled up. It follows the earthing up of planting holes and culture pan on both sides with plant fixation in a vertical position, with the possibility of its inclination while moving one side of the hummock, as well as plant movement by manually pushing one end of the culture pan after cutting of roots at the corresponding end, around the other end, with intact roots.

Description

The invention relates to agriculture, namely to a process for forming a flexible and movable perennial plant.

The process of cutting long and flexible skeletal branches to form a crown on a fruit tree capable of bearing fruit without the risk of breaking structural elements and suitable for mechanized harvesting is known [1].

The process of correcting the direction of branch growth is also known, the application of which gives the structural elements of the crown the flexibility necessary to avoid the danger of breakage under the burden of the fruit [2].

The process of guiding the crown in two oblique planes in plum trees is known, which consists of forming flexible frameworks, applying a cyclic pruning system, capable of bending under the burden of the fruit without the risk of breaking [3].

The process of forming oblique trees oriented perpendicular to the interval between rows is also known, specifically to facilitate mechanized shaking of the fruits [4].

The disadvantage of known processes is that the ability to be flexible is attributed only to certain structural elements of the crown, such as branches, but not to the integral aerial part of the tree.

The process of forming tall-trunk plants with subsequent bending along the row is also known. In the first three to four years, the trees grow vertically, and later they bend to be fixed to each other throughout the entire period of exploitation [5].

The disadvantage of the process is that tall-trunk trees can only be somewhat flexible in the first three to four years after planting.

The closest solution is the process of forming a flexible apple tree. This process involves planting the tree in a cylindrical pot, 40 cm high and 25 cm in diameter, consisting of two symmetrical parts, which is placed on the surface of the previously loosened soil. The pot, before planting the tree in it, is filled with soil. After watering and settling the soil in the pot, the symmetrical parts of the pot wall are removed, leaving the tree in place. As the tree grows, the tree extends its root system below the soil surface level characteristic of the microrelief of the given orchard plot. Starting with the third year after planting, the soil is leveled mechanically with manual finalization, as a result of which the base of the skeletal roots is exposed. The roots that are oriented towards the intervals between the rows are cut, leaving plugs up to 5 mm long on the trunk. After this, the mechanized pruning is carried out again. A trunk is formed at the tree with a height of at least 70 cm. At its base, at a height of 35 cm from the soil surface, i.e. at a height of 5 cm from the top of the earthen stump around the tree, four support branches with a length of 40…50 cm are formed crosswise, oriented strictly horizontally. The annual growths on these branches intertwine with each other in a horizontal plane, forming the basal tier of support disk-shaped branches. Immediately before harvesting the fruits, the stumps along the row are destroyed, with the earth being pulled apart mechanically with manual completion. As a result, due to the fact that the bare parts of the roots are flexible, the trees lean towards the middle of the interval between the rows. The basal layer of disc-shaped branches temporarily fixes the central axis of the tree at an angle of 45° to the soil surface. If the width of the row spacing is 4 m, and the height of the tree - 2.8 m, then the projection of the tree top returns exactly to the middle of the row spacing. In this case, the trees of two neighboring rows can be tilted in the direction of a single row spacing. This creates conditions for harvesting fruits by shaking using specific assemblies of mechanisms. After shaking the fruits, the trees are brought back and fixed again in a vertical position by mechanized soil compaction [6].

The disadvantage of the process is the need to form four additional branches at the base of the trunk, which makes it difficult to form and maintain the size and structure of the aerial part of the tree. In addition, the tree cannot be moved to one side or the other from the initial planting site without being substantially stressed.

The problem that the claimed invention solves consists in giving the fruit tree the ability to be flexible and at the same time moveable to any place from the initial planting site, avoiding substantial stress.

The process of forming the flexible and movable perennial plant includes planting the plant in a vegetation pot that is formed around two planting holes, using two symmetrical truncated conical metal grooves with a length of 0.70...1.45 m and a diameter at the ends of 50 and 15 cm, respectively, placed horizontally, with the large-diameter ends facing each other, inside which a tarpaulin sheet and a polyethylene sheet are laid, after which the grooves are filled with substrate, with subsequent tamping and watering of the substrate after planting and the gradual removal of the grooves with the attachment of longitudinal twigs and the simultaneous wrapping of the freed portions of the grooves with a string. After that, the vegetation pot moves along the line between the planting holes, and its ends are bent and inserted into the holes, which are plugged, then the planting holes and the vegetation pot are planted on both sides, fixing the plant in a vertical position, with the possibility of tilting it when moving one side of the planter at a distance of 50 cm in the direction of tilt, as well as moving the plant by manually pushing one end of the vegetation pot after cutting the roots at that end, around the other end, with the roots intact.

At the same time, the vegetation pot is of a bitronconical shape, with a diameter in the middle of 45 cm, at the ends of 12 cm, and a length of 1.4…2.9 m.

The result of the invention consists in ensuring the possibility of giving the structure of perennial plants the ability to be flexible and movable, which substantially facilitates and simplifies the technology of their care and exploitation.

The invention is explained by the drawings in figures 1-13, which represent:

Fig. 1, sheet metal grooves used to build the vegetation pot;

fig.2, vegetation pots filled with substrate, with trees planted in the middle of them, and placed next to the future row of plants (next to the planting holes);

Fig. 3, vegetation pots where the ends are bent and inserted into the planting holes;

Fig. 4, cross-section of the vegetation pot in close proximity to the plant;

Fig. 5, cross-section of the vegetation pot in close proximity to its end;

fig.6, the vegetation pot with tree in vertical position;

Fig. 7, the vegetation pot with the tree in an inclined position towards the middle of the interval between the rows;

Fig. 8, horizontal projection of the plantation with the distance between rows greater than that within the rows;

Fig. 9, horizontal projection of the plantation with the same planting distance in the row and between the rows;

Fig. 10, possible scheme for moving the plant-bearing vegetation pot;

Fig. 11, cross-section of the vegetation monolith (former vegetation pot) made up of substrate densely covered with roots, starting with the fourth year after planting the plant;

Fig. 12, appearance of the vegetation monolith bandaged with a narrow polyethylene film;

Fig. 13, the appearance of the vegetation pot with the tree placed in close proximity to its right end, where:

1 - right groove;

2 - left groove;

3 - handle;

4 - tree trunk (tree);

5 - projection of the planting hole;

6 - vegetation pot;

7 - temporary connection with plastic string of the end of the vegetation pot;

8 - left end of the vegetation pot;

9 - right end of the vegetation pot;

10 - soil surface;

11 - earthworm;

12 - plastic string;

13 - outer wall made of oilcloth foil;

14 - inner wall made of polyethylene film;

15 - bent upper edge of the inner wall;

16 - longitudinal rod;

17 - substrate;

18 - vertical root;

19 - layer of plant debris as mulch;

20 - cross-section of the horizontal skeletal root;

21 - cross-section of the horizontal semi-skeletal root;

22 - lateral earthen mound in initial position;

23 - position of the lateral mound of earth moved from the vegetation pot at a distance of 50 cm;

24 - position one (initial) of the flattened crown of the tree;

25 - second position of the flattened crown of the tree;

26 - direction of technological traffic between rows of trees in position one;

27 - direction of technological traffic between rows of trees in the second position;

28 - direction of rotation of the vegetation vessel (tree carrier) around the right end 9;

29 - direction of rotation of the crown around the right end of the vegetation pot;

30 - alternative direction of rotation of the vegetation pot around the end 9;

31 - alternative direction of rotation of the tree crown around the end 9;

32 - direction of rotation of the vegetation pot from position p2 around the left end 8 to position p3;

33 - direction of rotation of the vegetation pot from position p3 around end 9 to position p4 or p5;

34 - direction of rotation of the vegetation pot from position p4 around end 9 to position p5;

35 - direction of rotation of the vegetation pot from position p5 around end 8 to position p6;

36 - direction of rotation of the vegetation pot from position p1 around end 9 to position p2;

37 - covering made of vegetable remains;

38 - spiral bandaging of the vessel with a narrow strip of polyethylene foil;

39 - thin wire root cutting line;

40 - longitudinal slat;

41 - vertical skeletal roots with a thickness between 11 and 15 mm;

42 - vertical skeletal roots with a thickness between 4 and 10 mm;

43 - vertical roots with a thickness of less than 3 mm;

44 - thin wire for cutting roots, located under the left side of the vegetation pot;

45 - thin wire for cutting roots, placed on the right side of the vegetation pot;

46 - direction of wire pulling in the root cutting process;

47 - funnel for capturing rainwater or artificial irrigation, made of plastic sheeting (polyethylene or oilcloth);

48 - layer of plant debris.

The invention is carried out in the following way.

In the Republic of Moldova, the agricultural lands of various joint-stock companies and LLCs are small, (except for economic agents that lease), on average they do not exceed the area of 15…20 ha. Most farmers, however, own lands whose areas, on average, do not exceed 2 ha. In such land conditions, economic agents that practice agribusiness are interested in exploiting agricultural lands to the maximum. In addition, the requirements of the market economy vary greatly from year to year. Economic agents are forced to react promptly in terms of changing the structure of plantations and plant cultivation technologies, which prompts them to reorganize agricultural areas. The circumstances listed above urgently require the development of agricultural procedures that would give horticulturalists the opportunity to impart to plants, at the appropriate time, the properties of being flexible and mobile. One such process is the development described below, which constitutes a process for forming a flexible and movable perennial plant.

With the help of two symmetrical truncated-conical grooves made of sheet metal, on the right and left, 1 and 2 (fig. 1), the vegetation pot 6 (fig. 2) is formed ad hoc, along with the planting holes 5 as a separate operation in the process of establishing the plantation, in which the perennial plant is planted, for example, the apple fruit tree. The length of the grooves, of each one, depends on the expected size of the distance between the plants in the row. It is, when the distance between the plants in the row is: 1.5 m - 0.7 m; 2.0 m - 0.95 m; 2.5 m - 1.2 m; 3.0 m - 1.45 m. The truncated-conical grooves have a diameter of 50 cm at one end, and 15 cm at the other end. Each groove is equipped with handles 3. To form a vegetation pot, both grooves are needed. They are placed consecutively in a line "end to end" - with the ends with a large diameter one after the other at a distance of 10 cm, next to and along the line of the future row of trees (at a distance of 25 cm from the edge of the holes), between two holes 5 made in advance (see Fig. 2). The parameters of the holes are: diameter - 0.7 m; depth - 0.6 m. Inside the grooves (see the cross-sections of the pot in Fig. 4 and 5), thus placed on the soil surface, first a sheet of hard oilcloth (which consists of fabric) 13 is laid (the outer wall of the future pot), then a polyethylene sheet 14 (the inner wall of the future pot). The cavity of the pot thus formed is filled with substrate, which is soil (collected from around the pits) fertilized with organic and mineral fertilizers. In the middle of the pot, between the ends of the grooves, simultaneously with filling with substrate, the tree 4 is planted. The substrate is immediately tamped and lightly watered. After the substrate has settled, the grooves are manually pulled in parts by the handles 3. The pulling of the grooves is carried out gradually, from the left and right of the planted tree, as the portions of the pot freed from the grooves are tied (temporarily, for a few minutes) with strings 12. After the final removal of the grooves, two longitudinal twigs are fixed to the pot on each side by ties, made from fragments of branches obtained from the spring pruning process of fruit trees. When fixing the twigs to the pot, the strings 12 temporarily tied a few minutes ago are used. One by one they are untied, and then used to fix the longitudinal rods to the body of the vegetation pot. The final formation of the vegetation pot is completed by making temporary constriction connections 7 at both ends (left and right). The next technological operation is to fill the holes with fertilized soil up to a level of 10 cm from the soil surface, accompanied by a light compaction and watering. After the integral body of the vegetation pot, already bearing a fruit tree, is moved by manual pushing, into the exact overlapping position on the line of the future row of trees. The distance of movement of the vegetation pot towards the row line does not exceed 60 cm. After the movement, the left and right ends of the vegetation pot will hang freely exactly in the middle of the holes, respectively - left and right. Both ends of the pot are released from the strangulation ties 7. Then, with the same ropes, the ends are tied back, but without strangulation. The ends of the pot finally take the shape of a cylinder with a diameter of 12 cm. The next operation involves the final filling of the holes with fertilized soil. Due to the bending of the ends towards the depth of the soil, the substrate in the vegetation pot communicates without interruption with the fertilized soil in the left and right holes (fig. 3). After the final filling, the soil in the pot and holes is moistened, then tamped (see tamping 11, fig. 3). To ensure a strictly vertical position for the tree, the vegetation pot is tamped with soil 22 on both sides (along the row) (fig. 6). The tree planting operations are completed with a final watering of the substrate in the vegetation pot through the longitudinal opening at the top of it. This opening extends only to the left and right portions of the pot, which bend towards the depth of the soil. The opening at the top of the pot is 10 cm wide at the tree trunk and gradually narrows to 0 cm near the portions that bend towards the depth of the soil. To prevent excessive evaporation of water from the pot, the top opening is lined with plant debris as mulch 19 (fig. 4 and 5). This layer of mulch prevents erosion of the substrate in the pot during the frequent watering during the first vegetation, which is carried out through the top opening. After the substrate in the pot is saturated, the water drains into the holes where the tree roots will concentrate towards the end of the first year of vegetation. The trees, thanks to the lateral scythes 22 (fig. 6), maintain their vertical position throughout the entire period of operation. In case of damage, the lateral scythes 22 can be promptly restored manually or mechanically. The scythes, even if they do not deteriorate, must be periodically renewed (fortified). For this, there is no need for special traffic of the tractor in the aggregate only with the scythe machine. It is rational for the scythe to be formed simultaneously with other technological operations, such as soil cultivation operations and tree treatment with protective solutions. For this purpose, scythe knives are installed on the left and right sides of the agricultural machine (be it a cultivator or a sprayer).

To harvest, for example, apples, with machines whose technological scheme provides for shaking the fruit, it is necessary, only for the appropriate moment, that each tree in the plantation tilts towards the middle of the interval between the rows. In the case of the claimed process, for the trees to tilt for the mechanized shaking of the fruit, it is enough that the lateral support, from the direction of tilting of the tree, is moved to position 23 at a distance of 50 cm from the vegetation pot (fig. 7). Due to the fact that the roots in the portions at both ends of the vegetation pot possess flexibility, the tree tilts together with the pot (for a moment not supported by the support), i.e. it becomes flexible and can often be lifted and dropped suddenly by the organs of the harvesting machine, thus performing the shaking of the fruit. After harvesting the fruit, the trees are brought back to a vertical position by mechanized shaking of the vegetation pots.

Often the horticulturist is willing, under the pressure of the need to grow other plants, the fruits of which have been oversupplied by the market in the last few years, to move the fruit trees to one side at short distances, within the boundaries of the plantation territory. Such a change in the structure of all plantations as a whole on the land plot in his possession, as well as of the fruit plantation in particular, can be carried out if the claimed process of forming a flexible and movable perennial plant is applied.

The tree with the roots thus formed can be gradually moved over short distances, without causing it substantial stress, by cutting the vertical roots, which emerge from one end of the vegetation pot. For example, in plantations where the crown of the trees is flat, and the distance between the rows is greater than that between the plants in the rows (fig. 8), when it is necessary to move the trees, the roots emerging from the left end 8 of the vegetation pot are cut. Then, the vegetation pot 6 carrying the tree, is manually pushed by the end 8 (become mobile) to the left or to the right around the end 9 with the roots left uncut, following the trajectories 28 (for the left row) and 30 (for the right row). The mobile end of each pot moves at an angle of 90° to the initial line of the plant row. The movement is possible due to the flexibility of the roots left uncut at the ends 9 of the pots, which allow them to be rotated up to 90° (in some cases even more - up to 180°). The ends 8 of all pots are placed strictly on one line, which are subsequently mulched with soil, ensuring the trees a vertical position. The twisted roots of the ends of the pots 9 continue their life uninterruptedly, and new vertical roots quickly develop from the ends 8. As a result of this agrotechnical maneuver, the structure of the plantation changes radically. The rows of plants have a completely different direction, which allows the horticulturalist to carry out soil cultivation not only in the direction 26, but also in the direction 27. After changing the structure of the plantation, soil cultivation machines with a substantially increased working width will be used in the directions 26. In addition, in the strips of land with the technological traffic direction 26, being of an increased width, intercalary crops can be grown. Over time, the structure of the plantation can be restored to its initial state by applying the same procedure of moving the pots (plants). In plantations of the same type, as is the case illustrated in figure 8, the pots of vegetation bearing trees on all the initial rows can be moved analogously only in one direction, i.e. only to the left or only to the right, which represents a new situation with its own specifics regarding the structure of the plantation.

A possible variant of moving the trees by applying the same procedure, i.e. restoring (changing) the initial structure of the plantation, where the distance between the rows is the same as the distance between the plants in the rows, is illustrated in Figure 9. In this case, the vegetation pots with the trees rotate around the pot ends 8. The trees on all the rows rotate only in one direction - to the right (it is possible to move all the trees to the left as well). If in the initial state of the plantation the technological traffic is carried out in the direction 26, then after the movement - in the direction 27.

Gradually, from year to year, the trees (and the entire plantation in its entirety) can be moved to relatively large distances, in order to free up a portion of land for the cultivation of other plant species, according to the requirements of the moment. Figure 10 illustrates, for example, a variant of moving the tree over five years in a row. To move the vegetation pot 6 carrying the tree from the initial position p1, the same procedure described above is applied, in this case the following movements are performed. From position p1 to position p2 the pot rotates around the pot end 9 following the trajectory 36. In the following year - from position p2 to position p3 the pot rotates around the pot end 8 along the trajectory 32, in another year - from position p3 to position p4 the pot rotates around the pot end 9 along the trajectory 33, then - from position p4 to position p5 the pot rotates around the pot end 9 along the trajectory 34, in the following year - from position p5 to position p6 the pot rotates around the pot end 8 along the trajectory 35. It should be noted that from position p3 the pot can be moved directly to position p5 along the trajectory 33, i.e. the pot rotates at an angle of 180°, provided that the thickness of the vertical roots in the place of twisting does not exceed 15 mm and that they have an increased twisting capacity, which is characteristic of young trees. Roots thicker than 15 mm can only be rotated at an angle of 90° in relation to the initial position. In older trees, in order to ensure the necessary twisting capacity, one year before the movement is carried out, the roots that emerge from the end of the pot around which the movement is expected to be carried out are cut, but the pot is not moved in the current year. The movement will be carried out the following year, when the new roots that have emerged at that end will be thin and, therefore, quite flexible in terms of twisting. We also mention that the rotation of the pots (trees) can be carried out not only strictly at an angle of 90° or 180°, but at any angle up to 180°, depending on the requirements of the moment, the configuration of the agricultural land in possession, as well as the set of relationships between plantations of different types (taking into account the plant species and the specifics of the structure) located on this land.

Periodic cuttings of the roots under the left or right ends of the vegetation pot, in the alternation required at the moment, are carried out at a depth of 5…10 cm.

At the end of the third year after planting, the horizontal skeletal roots and their branches very often cover the substrate in the vegetation pot, forming a hard monolith, called the vegetation monolith, which cannot disintegrate on its own. Therefore, in the spring of the fourth year after planting, this monolith is freed from: the longitudinal rods 16, the outer wall 13 and the inner wall 14.

Immediately after this, the vegetation monolith is covered with a layer of plant debris 37, then bandaged with a narrow strip of polyethylene 38 (fig. 11, 12). At the base of the tree trunk 4, a funnel 47 is installed to capture rainwater or artificial irrigation water, which is filled with a layer of plant debris 48. The bandage strip and the funnel are made ad hoc from the materials 13 and 14 from which the vegetation monolith (former vegetation vessel) has just been freed. The covering of plant debris protects the monolith with its roots from extremes of temperature in summer and winter, and minimizes the unproductive evaporation of water.

In the eighth year after planting, the funnel 47 and partially the bandage 38 (up to the place of bending of the ends 8 and 9) are removed from the vegetation monolith. At the ends of the monolith, in the places of downward bends, the bandage is preserved. Further, under the action of the environment, the vegetation monolith (in the bare part) falls apart. That is, the substrate on the roots is dissipated. As a result, the roots in the former vessel (then monolith) of vegetation remain bare. The bare parts of the roots over time become hard and lose their flexibility, while the parts of the roots at the ends, which remained covered by the substrate and bandage, retain their ability to be flexible.

Using sheet metal grooves, analogous to those described above (Fig. 1), the vegetation pot 6 (Fig. 13) can be formed, in which the perennial plant is planted not in the middle (as described in the text above and illustrated in Figures 2, 3, 8, 9, 10, 12), but at one end. Otherwise, all technological operations are the same. In this case, the movement of the vegetation pots of the plants does not differ much from the schemes illustrated in Figures 8, 9, 10. Only the movement distance will be slightly greater, and reaching the expected (final) movement boundary faster. In the first two years of development after planting (after the formation of the vegetation pot carrying the substrate and the plant) the spread in the soil is allowed only of the roots that come out of the left end 8, marked with the number 41 (Fig. 13). In the third year after planting, in the basal part of the vegetation pot, the walls are perforated to allow the roots 42 and 43 to spread into the soil. The roots 43 are cut in the spring each year by pulling a thin wire or with any available tool and device. The roots 42 are cut only when it is necessary to rotate the end 9 around the end 8. And the roots 41 are cut when it is necessary to rotate the end 8 around the end 9.

Periodic cuts, in the alternation required by the moment, of the vertical roots 41 and 42 that emerge from ends 8 and 9 of the vegetation pot are made at a depth of 5…10 cm, and of those 43 at a depth of 2…3 cm.

1. Agafonov N.V. Scientific principles of placement and formation of fruit trees. Moscow, 1983, pp. 93-102, 133-137, 156-159

2. Cimpoieş Gheorghe. Management and cutting of trees. Chisinau, Ştiinta, 2009, p. 40-45

3. Coroid A. St. Procedure for managing the crown in two oblique planes in plum. Collection of scientific papers "Research in fruit growing", vol. 2, AŞM Printing House, Chişinău, 2003, p. 75-78

4. Богдан И. G. Possible schemes of technological processes of apple harvesting. Agriculture of Moldova, 2003, no. 8, p. 32-33

5. Кудрявец Р.П. Pruning fruit trees and berry bushes. Moscow, Agropromizdat, 1991, p. 108-109

6. Богдан И. G. Method of forming flexible apple trees. Agriculture of Moldova, 2003, no. 9, p. 9-10

Claims (2)

1. Process for forming a flexible and movable perennial plant, which includes planting the plant in a vegetation pot that is formed around two planting holes, using two symmetrical truncated conical metal grooves with a length of 0.70…1.45 m and a diameter at the ends of 50 and, respectively, 15 cm, placed horizontally, with the large-diameter ends facing each other, inside which a tarpaulin sheet and a polyethylene sheet are laid, after which the grooves are filled with substrate, with subsequent tamping and watering of the substrate after planting and the gradual removal of the grooves with the fixing of longitudinal twigs and the simultaneous wrapping with a string of the portions released from the grooves; After that, the vegetation pot moves along the line between the planting holes, and its ends are bent and inserted into the holes, which are plugged, then the planting holes and the vegetation pot are planted on both sides, with the plant fixed in a vertical position, with the possibility of tilting it when moving one side of the planter at a distance of 50 cm in the direction of tilt, as well as moving the plant by manually pushing one end of the vegetation pot after cutting the roots at that end, around the other end, with the roots intact. 2. Process according to claim 1, in which the vegetation pot is of bitronconical shape, having a diameter in the middle of 45 cm, at the ends of 12 cm, and a length of 1.4…2.9 m.