SU1014520A1 - Plant growing method - Google Patents

Abstract

1. METHOD OF CULTIVATION OF PLANTS, including the supply of irrigation water to a plant zone in a state of mist with an electrical potential of a directional sign, microelement% carbon and carbon dioxide, in order to ensure the possibility of controlling the growth and ra; zlitiem I L L jf / -) itul- - jj; I -.- g. TEliJ v; :-); SHK Hc; - ;; -; - A i plants additionally control the characteristics of the transport. Depending on the environmental factors and the obtained characteristics of transpiration, the density of the mist in the surface layer of the plants is controlled, and the mist is formed by condensing the moisture in the plant zone. 2, the method according to claim 1, about tl and h and y -. u and u with teM that the adjustment of the fog density of the receiving layer is carried out by creating: convection zones above the surface layer. 3. The method according to p. V, which is the case with the fact that condensation (moisture produced by the creation of centers. Condensation in the surface layer.

Description

The invention relates to agriculture and can be applied to optimize conditions, accelerate plant growth and control photosynthesis. There is a known method of growing a scientific research institute in a plant that includes supplying irrigation water to a plant zone in a state of mist with an electrical potential of a directional sign, trace elements and yi-acid gas 1. The disadvantage of this method is the lack of control over the growth and growth of plants. The purpose of the invention is to provide the ability to control the growth and development of plants. This goal is achieved by the fact that according to the method of growing plants, the role of transpiration characteristics depending on environmental factors is additionally controlled according to the obtained characteristics of transpiration, the density of mist in the surface layer of plants, and the mist is formed by condensing aloe in the plant zone. Moreover, the adjustment of the fog density of the surface layer is carried out by creating convection zones above the surface layer. In addition, moisture condensation is carried out by creating condensation centers in the surface layer. FIG. 1 schematically shows a device that implements the proposed method, a plan view; in fig. 2 - time cut AA in FIG. 1. To control the growth of plants when they are grown under conditions of open ground in the subsurface layer of field 1, the size of which is determined by the agricultural crop and a set of agrotechnical measures, create a water-retaining layer 2 (by filling waterproof soil or placing film, screens, etc .). On the surface of floor 1, a means for regulating the water regime is installed, comprising a water source 3, a pump transporting the pipeline and sprinklers 6 in the form of perforated pipes with shut-off and control valves 7, the drive of which is connected via a communication channel to point 8 of the control; a means of regulating the nutritional regime, comprising a fertilizer receiver 9 connected to a mixer 10 which is hydraulically connected to the conveying pipeline 5; means of adjusting the air mode, made in the form of hemispherical tray-shaped containers 11 with side-folds, on the outer surface of which conductive elements 12 (for example, a metal strip) are electrically connected with control point 8, and in the cavity of tanks 11 are placed on the supports 13, perforated irrigation pipes 6 (sprinklers) with water-jet nozzles 14, while hemispherical lot-shaped containers 11 are installed on the telescopic pipes 15 included in the transport path its pipeline 5 which, through the controlled valve 1b, is connected to the generator rasaj 17 having an air source; means of magnetizing irrigation water, made in the form of a uniform and non-uniform magnetic field in the water movement area of the device, consisting of at least two pairs of permanently shaped 18 magnets 18 mounted at the outlet of each water jet nozzle 14, and at least two electromagnets 19 installed along the perimeter of the hydraulic tract in the case of each water jet nozzle 14; a means of measuring the parameters of the environment and physiological processes of plants, made in the form of sensors 20 of photosynthesis and gas exchange of plants placed on the field 1, biomass, temperature, humidity, connected to item 8 of the control. The method is carried out as follows. After questioning and processing the information of sensors 20 of environmental parameters (temperature, humidity, concentration of COj. In air) and physiological processes of plants (photosynthesis, biomass increase) from point 8 control, no command is issued to carry out agrotechnical measures to create optimal conditions in this phase of plant development. With an increased concentration of water condensate in the surface layer of the wasp. Subject to command from point 8 of the pack (to switch on the carbon dioxide generator 17, open the valve 16, supply CO (per 1 liter of air 4.5-5.5 mg CO) to the transport pipeline 5 3-, through valve 7 to the sprinklers 6, then through water jet nozzles 1 to the plant zone. The carbon dioxide entering the plant zone reduces convection in the surface layer and contributes to the condensation of water vapor from this layer, which also adjusts the environmental factor (CO to the optimum value for the given development phase and ensures normal flow photosynthesis of plants. About At present, with the supply of carbon dioxide to the surface layer, depending on the charge of the vapor medium of this layer, the potential of the voltage is applied to the conductive elements 12 (negative charge is supplied in the case of negative charge of the medium in the surface layer and positive in the case of positive charge ). The interaction of the charges of the conductive elements 12 and the medium prevents the outflow of the steam condensate from the surface layer. The regulation and stabilization of the level of placement of the electric field is realized by moving the tanks 11, KOTopbie p being housed is transported above the plant zone over a distance of 1/2 N to H (H is the height of the vegetation cover) by means of the pump 4 supplying water from the source.3 to the transporting pipeline 5. In addition, tanks 11 with side openings with water fill up accumulate thermal energy in this zone and thus the convection zone above the surface layer, thereby eliminating the negative effect of thermal energy and returning moisture from the environment of the surface layer and protecting the plants from physiological drought. In the case of an inefficient process flow for the formation and return of moisture from the surface layer, aerosols are prepared from particles with a size of 2-80 microns of active substances, for example, from 10-90 urea, etc. and through perforated pipelines BOfiu: e, it is supplied (sprayed) into the surface layer to form condensation centers as follows. The components of the aerosols are placed in the receiver 9, then they are mixed in the mixer 10 and with water by the pump 3 through the transporting pipeline 5 is fed into the perforated pipes 6 and 520. 4 | Through their waterjet, sprayed. Thereby it stimulates the return of moisture from the environment of the surface layer and optimizes the moisture and nutrient factors for this plant phase, which contributes to the normal flow of plant photosynthesis. In the case of extreme high solar radiation and the impossibility of overcoming the physiological drought of plants, plants are moistened by supplying tolivo water in the form of fine rain with particles of vodts within the range of 50–300 µm to the plant zone through water jet nozzles 1 of irrigators. 6, where water is supplied from the source 3 through the conveying pipeline 5 by the pump C on command from point 8 of the control. An irrigation jet entering the water jet nozzles 1 passes through a uniform magnetic field with an induction of 0.1-0.25 T, created by an electromagnet 19, and a non-uniform magnetic field created by cone-shaped magnets 18, magnetised and, falling on plants, becomes more accessible for assimilated. Feed irrigation water is concentrated in the root zone of plants due to the action of impermeable zones of 2 c. the subsoil and with high efficiency is absorbed by plants. The effectiveness of the use of the proposed method is to eliminate the frequent and excessive wetting of the floor, leading to an increase in the unfavorable period of time in the course of the photosynthesis process. The main essential features of the proposed method have been tested on arable crop (beetroot) and have shown that even partial regulation and control of environmental factors (introduction of carbon dioxide, timely regulation of the water-air regime in the habitat of plants) significantly stimulates the growth and intensive development of plants with significant water savings. For example, as a result of the elimination of the physiological drought phases, the growth of sugar beet roots relative to the control ones amounted to 25–30%. 10Y As experience shows, the timely impact on the state of the atmosphere of the surface layer reduces convective exchange, and consequently, the loss of moisture by 2 times. 20 In chalk, the proposed method is an instrument for controlling and intensifying the growth of plants associated with controlling environmental factors. .

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Claims (3)

1. METHOD OF PLANT GROWING, including feeding irrigation water into the plant zone in a state of fog with an electric potential of a directional sign, trace elements and carbon dioxide, characterized in that, in order to provide the ability to control the growth and development of plants, they additionally control the characteristics of the transpiration. depending on environmental factors and the obtained transpiration characteristics, the density of the fog in the surface layer of plants is controlled, and the fog is formed by condensation of moisture in the zone asthenia. 2. The method according to π. 1,. featuring '-. and the fact that the fog density of the surface layer is controlled by creating / convection zones above the * surface layer. 3. The method according to π. 1 ’, distinguished by the fact that the condensation of moisture is produced by the creation of centers of * condensation in the surface layer. ♦ £