RU1790871C - Method for sowing plants in containers - Google Patents

Abstract

Usage: in agriculture and forestry, viticulture in the cultivation of vegetatively propagated tree and shrub plants. SUMMARY OF THE INVENTION: A container with a bottom of finely porous material and walls impervious to the root system and substrate is used for propagation. The volume of the container corresponds to the size of the landing we. The container is filled with a fine sand immune medium. For rooting, disinfected planting stock is used. When a seedling is planted in a permanent place, the top edge of the container is placed 5-10 cm above the soil level. 3 ill. Yo

Description

The invention relates to the field of agriculture and forestry, mainly to the cultivation of grapes, suitable crops and other vegetatively propagated tree-shrub plants.

A known method of growing seedlings of fruit crops and grapes in cups or other containers of polymer material without a bottom, where steamed sawdust is used as a substrate, and the resulting seedlings are planted in the soil together with these containers.

Close to these developments for the solution of certain technological processes and a container for the development of the roots of the transplanted plant, containing a non-woven porous bag of staple synthetic fibers.

The disadvantage of these methods is that they do not protect plants from infection with nematodes, phylloxera and / or / other root aphids, both when growing seedlings and after planting them in a permanent place.

A known method of protecting plants by growing them in an immune environment, in particular grapes in fine-grained sand with certain water-physical properties.

The disadvantages of this method are the very low natural fertility of such soils, and the fact that they are of limited distribution in areas of industrial cultivation of grapes and other agricultural crops and are located in arid zones.

Xi

U O 00

x |

The purpose of the invention is to protect woody-shrub plants and grapes from quarantine pests of the root system, to ensure high survival and viability of plantings under conditions of possible infection by quarantine pests.

The goal is achieved by rooting disinfected cuttings in special containers with a known immune substrate in which these zooparasites do not develop, i.e. in a sandy environment characterized by certain water-physical properties and subsequent planting of the resulting planting material on a plantation together with the immune environment without disturbing the lump on the roots of the seedling.

Fig. 1 (positions A, B, C and D) shows the steps of planting cuttings in containers with an immune medium; Fig. 2 is a variant of growing seedlings in said containers by the hydroponic method; in Fig.Z - a method of planting such seedlings on a plantation.

For rooting in the immune environment, disinfected shanks are used in CC containers, in which the upper half of P is waxed and the eyes in the lower part of X can be blinded. Before planting the shank, the container is loaded with sand for 1/3 of the container’s volume, then onto the sandy bed of the submarine formed vertically in the middle of the container, the stem to be rooted is set and buried in the sandy bed so that the second top of the stem of the eye is placed 1-2 cm below the top edge of the container so that after full loading and the sand container okazals eye at the substrate surface, as is customary in the conventional method for preparing kornesobst- governmental seedlings, whereafter the container is filled to the brim immune medium and for rooting becoming t. At the same time, the methods for rooting cuttings can be very diverse: in or out of greenhouses, conventional or hydroponic on a pallet or platform P with a corrugated GD bottom, as shown in Fig. 2. The seedlings thus obtained are transported to the place of constant planting directly in containers with the substrate both in the summer in vegetative form and after deciduous fall, i.e. in a state of biological rest.

Planting the seedlings obtained is carried out directly in containers with the immune environment. For this purpose, planting seedlings are prepared in advance with slightly larger horizontal dimensions,

than containers - in order to conveniently place the container tightly in me and fill up the remaining space between the container and the soil. The containers are set in mu so that the top edge of the container is about 5-10 cm higher than the soil level of the site. Such a rim provides some protection of the top layer of the sandy soil from mixing with the soil and the consequent increase in the water holding capacity of this layer, which could create conditions for the formation of root-collectors in this zone of the plant (on the root), which become the object of primary infection by the pest. The height of the rim is selected taking into account a possible increase in the level of the surrounding soil during loosening or its shrinkage during the period between such treatments. An increase in the height of the rim is undesirable, since in this case the bottom of the container will come into contact with a less moist soil layer and worsen the water regime of the immune zone of the root zone.

CC containers are a container with a height of about 50 cm and less than 25-30 cm across (i.e., its dimensions are close to the size of planting m for a number of tree-shrub plants), the walls of which, at least the bottom of the MTD, are made of finely porous , easily accessible for penetration of roots and moisture, but not passing through the pores of the substrate, material. Various containers can be used as containers for growing root crops in the immune environment, for their transportation and planting on plantations synthetic polymeric compounds, as well as a suitable pouch size of fabric or non-fabric material. The main requirement for the chemical composition of the container material is its possible chemical decomposition in the soil should not cause an abiotic change in the composition of the soil solution.

Example 1. To determine the effectiveness of the invention, 50 pieces were used as containers. plastic buckets that have served their time, at the bottom of which large holes have been made, and before filling the sandy soil, the bottom of the bucket is lined with a piece of kapron fabric. The rooting of grape cuttings in containers with the immune environment was carried out in an open area. After rooting, transportation to the planting site was carried out on the site of a vineyard infected with phylloxera. Experienced seedlings are planted in us instead of the remote root shrubs of bushes that were heavily infected with phylloxera.

Over the three years of observation of these plantings, the penetration of a quarantine pest into the immune environment and to the roots of grapes has not been established. By the end of the third growing season, the experimental bushes had 9-10 pieces of normally developed shoots, while the surrounding bushes were strongly inhibited, and in the control plantings of the same-age plants without a container with an immune substrate 36% of mature bushes died over the years, the rest were also suppressed by the pest .

Claims (1)

SUMMARY OF THE INVENTION A method for planting plants in containers, including rooting and growing seedlings in containers filled with a substrate, with a bottom made of finely porous material permeable to 5 0 plant gratings and impermeable to the substrate, followed by transplantation of rooted seedlings to a constant place of growth together with a container, characterized in that, in order to protect tree-shrub plants and grapes from quarantine pests of the root system, to ensure high survival and viability of plantings in conditions of possible infection with quarantine pests, disinfected planting material is used for rooting, and immune is used as a substrate for acceleration medium based on fine-grained sand, and the container is made in such a way that its walls are impervious to the root system and substrate and the volume corresponds to the size of the planting, and when planting seedlings at a constant place of growth, the upper edge of the container is 5-10 cm above the soil level . FIG. 1