RU2420058C1 - Method to grow leaf vegetables in intensive photoculture - Google Patents

Abstract

FIELD: agriculture.

SUBSTANCE: invention relates to the field of agriculture. In the method plants are grown on peat and soil in a nutrient solution with its continuous recirculation and maintenance of nutrient elements concentration in a working solution depending on a season and its acidity. The nutrient solution is prepared on the basis of a mix of catholyte with anolyte in the ratio of 1:0.5. Additional activation of the nutrient solution is carried out in process of plants growing, a mixture of freshly prepared catholyte and anolyte is added, and oxidation-reduction potential of the nutrient solution is maintained from +100 to -40 mV. At the same time the first 10-12 days, plants are kept on a planting table, and are poured with a mixture of activated water, catholyte with anolyte 1: 0.5 with pH 9.1.

EFFECT: method makes it possible to reduce specific indices of energy intensity of leaf vegetables production.

7 tbl, 1 dwg

Description

The invention relates to agriculture, namely to plant growing protected ground.

It is known to grow Afitsion salad on the line of flowing hydroponics on a nutrient solution prepared from complex and simple fertilizers in plain water with a nutrient conductivity of 1.6-2.2 mS / cm and a long growing period of 38-39 days. Lesin S.A. "Lettuce on the line of flowing hydroponics", RGAU - MSHA, w. Potatoes and vegetables, No. 5, 2007, p.22.

The disadvantage of this growing technology is the high energy intensity of lettuce production.

It is known to grow lettuce in greenhouses on soils using simple mineral fertilizers. The main condition for selecting the composition of fertilizers is a balance in the elemental composition of the nutrient solution. To increase the biological value of the nutrient solution, extend its duration, reduce toxicity by introducing zeolite into the soil. Glushkov N.M., Plyushchikov V.G., Sinyutin A.G. TsINAO, J. Potato and vegetables, No. 7, 2002, p.26.

The disadvantage of this method of growing green crops, including and lettuce on the ground, is the complexity of the process and it is very difficult to maintain the biological value of the products for several days.

Closest to the claimed method of growing plants under hydroponic conditions, which consists in influencing the seeds or plants in the area adjacent to the roots or to the bottom of the seeds, namely in the area of the nutrient solution, ultrasound, the intensity of which averages from 10 ² to 10 ³ W / m ² . To increase the effectiveness of ultrasound, seeds or plants are stimulated with a constant and / or alternating magnetic field. An additional effect on the cellular structures of seeds and plants in the form of low-intensity ionizing electromagnetic radiation (microwave radiation) or laser (RU No. 2048058, A01G 9/26, 1995).

A disadvantage of the known invention is the high energy intensity of the process of stimulating the nutrient solution with ultrasound (up to 10 ³ W / m ² ).

The objective of the invention is the cultivation of green crops in intense light culture on a nutrient solution prepared using electrochemical activation technology (ECA) to reduce the specific energy consumption of the production of green crops.

The problem is solved in that a method of growing green crops in intense light culture, comprising growing plants on peat in a nutrient solution with its constant recirculation and maintaining the concentration of nutrients in the working solution depending on the season and its acidity; the nutrient solution is prepared on the basis of a mixture of catholyte and anolyte in a ratio of 1: 0.5, the nutrient solution is deactivated during plant growth, adding a mixture of freshly prepared catholyte with anolyte and maintaining the redox potential of the nutrient solution from +100 to -40 mV, while the first 10-12 days, the plants are kept on the seedling table and watered with a mixture of activated catholyte water with anolyte 1: 0.5, pH 9.1.

New significant features:

1. The nutrient solution is prepared on the basis of a mixture of catholyte with anolyte in a ratio of 1: 0.5;

2. Nutrient solution is deactivated during plant growing by adding a mixture of freshly prepared catholyte with anolyte and maintaining the redox potential of the nutrient solution from +100 to -40 mV.

3 The first 10-12 days, the plants are kept on the seedling table and watered with a mixture of catholyte with anolyte 1: 0.5, pH 9.1.

The listed new essential features, together with the known ones, are necessary and sufficient to achieve a technical result in all cases for which the requested amount of legal protection is requested.

The technical result consists in the fact that growing lettuce in a nutrient solution prepared on the basis of a mixture of catholyte with anolyte in a ratio of 1: 0.5 (ORP from +100 to -40 mV), allows to increase yield compared to control (in tap water) by 24.1%, to increase the quality of lettuce by increasing the dry matter by 21.3-54.4% and reduce the content of nitrate nitrogen in products by 13.4%.

Repeated use of a nutrient solution with increased biological activity based on the phenomenon of electrochemical activation (ECA) significantly affects the specific expenditure indicators of energy resources.

The increased biological properties of the nutrient solution prepared on the basis of catholyte with anolyte 1: 0.5 are characterized by an increase in electron activity due to a decrease in the ORP index from +100 to -40 mV.

The saving of the basic elements of mineral nutrition (nitrogen, phosphorus, potassium, calcium) on the formation of a crop of 1 kg of lettuce amounted to 19.5-20.5% and on the creation of 1 kg of dry matter - 19.4-20.6% (recycling) and 35 , 4-36.1% (aquatic culture), was obtained experimentally using the inventive method (see table 1, 2, 3, 4).

Water saving per 1 kg of raw biomass was 0.70-2.25 l / m ² depending on the method of growing the crop (water and flow hydroponics), Table 7.

The drawing schematically shows a device for preparing a nutrient solution based on ECA and feeding into trays in its recirculation system.

The device consists of a solenoid valve 1, a water tank 2, a liquid level sensor 3, a control module 4. The feed pump 5 supplies water to the electrochemical activator 6. The voltage to the activator 6 is supplied through the rectifier unit 7. Activated water (catholyte) flows through valve 8 into the tank 9 to a predetermined level supported by the level sensor 10. The anolyte through the valve 11 enters the tank 12. The control of the level of activated water in the tank 12 is maintained through the drain hole 13. Pumps 14 and 15 activate the mixture bath water enters the mixing tank 16. The liquid level sensor 17 in the tank 16 controls the operation of the pump 18, valves 19 and 20, sends a signal to the measuring cell 21, containing pH and EC sensors of the nutrient solution. The command from the sensor 17 is sent to close the valve 20 and open the metering pumps 22, 23, 24 for the dosed supply of mother liquors and acid from the tanks 25, 26 and 27 through the pump 18 and the measuring cell 21 and the adjusted nutrient solution through the valve 20 is fed to the trays 28 to plants and recycles in a vicious circle with a return to the mixing tank 16 and the operation of all nodes of the device is repeated again.

In the experiments conducted in 2008-2009, the Afitsion salad of the Dutch company "Rake Zvaan" was used as the culture studied, as the most adapted to the conditions of an extended daylight hours.

The lettuce was grown by sowing in special plastic containers (pots) designed for trays 28 used in salad lines. The pots were filled with peat, moistened, seedlings appeared on the 3rd day, and the plants remained on the seedling table for 10-12 days. Humidified pots with plants activated water.

Illumination of 10 kLK (around the clock) in the structure was created by Dna 3-4-4 lamps suspended in height at a distance of 1.8 m from the surface of the tray.

The temperature and humidity conditions were maintained using forced-air and exhaust ventilation. In the autumn-winter period, the temperature was maintained at 18 ± 2 ° C around the clock.

The lighting system and the fan were controlled automatically (not shown).

At the age of 10-12 days from full germination, pots with plants were put on trays 28, through which the nutrient solution prepared using electrochemical activation technology was recycled.

Plastic trays 28 were placed at a distance of 18 cm from each other.

We also conducted studies to study the effect of activated nutrient solutions on yield and quality under strictly controlled conditions using the aquatic culture method, where each lettuce plant was grown in a separate glass jar in accordance with the aquatic culture methodology.

For the electroactivation of water, a device based on the PEM-3 element (flow-through electrochemical modular), commercially available at OAO Ekran, was used.

The principle of operation of technological equipment for the preparation and supply of nutrient solution to the trays for plants, shown schematically in the drawing, is as follows: tap water heated to a temperature of + 23 ° C through an electromagnetic valve 1 enters a tank 2 to a predetermined level controlled by a level 3 sensor controlled by a module 4. After reaching the set water level in the tank 2, a signal is received from the control module 4 to close the valve 1 and turn on the water supply pump 5 to the electrochemical activator 6, to which a voltage of 80 V is supplied from the rectifier unit 7 controlled by the control module 4. Activated water (catholyte) enters through the valve 8 into the container 9 until a predetermined liquid level is reached, controlled by a level sensor 10, a control pump 5 and an electrochemical activator 6 through the control module 4. Activated water (anolyte) enters through the valve 11 into the tank 12. The level sensor 10 is configured so that when the pump 5 is turned off, the ratio of catholyte to anolyte volumes in tanks 9 and 12 is 1: 0.5. The required volume of anolyte is supported by a drain hole 13 in the tank 12. Excess anolyte goes to technological needs. After reaching the predetermined ratio of catholyte to anolyte 1: 0.5, control module 4 receives a signal for sequentially switching on the catholyte transfer pump 14 and anolyte transfer pump 15 to the mixing tank 16. The operation time of the transfer pumps 14 and 15 is controlled automatically from the control module 4 The operations for the preparation of activated water (catholyte and anolyte) are repeated cyclically and pumped into the mixing tank 16 to achieve a given liquid level, controlled by a level sensor 17, which gives the command to turn on the pump 18, open the valve 19 and close the valve 20.

The mixture of catholyte with anolyte in the mixing tank 16 begins to circulate in a closed circuit through the measuring cell 21: mixing tank 16 → pump 18 → measuring cell 21 → valve 19 → mixing tank 16 with the simultaneous inclusion of metering pumps 22, 23, 24 for feeding the mother liquors And from the tank 25, B from the tank 26 and acid from the tank 27 into the mixing tank 16.

After reaching the specified pH and EC values of the nutrient solution, determined using the sensors of the measuring cell 21, the valve 19 closes with the simultaneous opening of the valve 20 through the control module 4 and the nutrient solution is fed to the trays 28 with plants and then returned to the mixing tank 16.

Further maintenance of the specified pH and EC values of the nutrient solution is carried out using the measuring cell 21 and the operation of the respective metering pumps 14, 15 without closing the valve 20.

The next portion of activated water will not get into the mixing tank 16 only after the control module 4 receives a signal from the level sensor of the nutrient solution 17, which means a decrease in the level in the mixing tank 16 by a certain amount. Then the cycle repeats.

The results of the experiments are presented in tables 1, 2, 3, 4, 5, 6, 7.

Table 1 The cost of basic nutrients for the cultivation of salad "Afitsion", aquatic culture, EU 1.6 mS / cm Options Harvest of raw biomass, g / plant. Consumed batteries, g.d.v. /plant The cost of batteries, g.d.v. / m ² N (N-NO ₃ + N-NH ₄ ) P ₂ O ₅ K ₂ O Cao N (N-NO ₃ + N-NH ₄ ) P ₂ O ₅ K ₂ O Cao Nutrient solution on BB (control) * 86.04 0.266 0.135 0.577 0.286 7.17 3.64 15.50 7.71 The nutrient solution in the mixture (KB + AB) ** 106.77 0.263 0.133 0.568 0.285 7.09 3,58 15.30 7.69 • - BB (tap water)
** - KV + AB (catholyte + anolyte)

table 2 Savings in the basic elements of nutrition for the creation of a unit of production of Afitsion salad, aquatic culture, EU 1.6 mS / cm Options Harvest of raw biomass, g / plant. The cost of batteries per 1 kg of raw biomass, g.v. / kg Saving batteries,% N (N-NO ₃ + N-NH ₄ ) P ₂ O ₅ K ₂ O Cao N (N-NO ₃ + N-NH ₄ ) P ₂ O ₅ K ₂ O Cao Nutrient solution on BB (control) 2,32 3.09 1,56 6.68 3.32 - - - - The nutrient solution in the mixture (KB + AB) 2.88 2.46 1.24 5.31 2.67 20,4 20.5 20.5 19.5

Table 3 The cost of basic nutrients for the output of 1 kg of dry matter of the salad “Afitsion”, aquatic culture, EU 1.6 mS / cm Options Dry matter yield, kg / m ² The cost of batteries for the creation of 1 kg of dry matter, g.dv Saving batteries,% N (N-NO ₃ + N-NH ₄ ) P ₂ O ₅ K ₂ O Cao N (N-NO ₃ + N-NH ₄ ) P ₂ O ₅ K ₂ O Cao Nutrient solution on BB (control) 0.125 57.44 29.12 124.0 61.76 - - - - The nutrient solution in the mixture (KB + AB) 0.193 36.78 18.60 79.27 39.84 35.96 36.12 36.07 35.49

Table 4 The cost of basic batteries for the output of 1 kg of dry matter salad "Afitsion", recirculation, EU 1.3 mS / cm Options Dry matter yield, kg / m ² The cost of batteries per 1 kg of dry matter, g.d.v. Saving batteries,% N (N-NO ₃ + N-NH ₄ ) P ₂ O ₅ K ₂ O Cao N (N-NO ₃ + N-NH ₄ ) P ₂ O ₅ K ₂ O Cao Nutrient solution on BB (control) 0.150 47.86 25.66 108.00 49.13 - - - - The nutrient solution in the mixture (KB + AB) 0.182 37.96 20.43 85.71 39.56 20.68 20.38 20.63 19.47

Table 5 Change in the ORP value of the nutrient solution depending on the degree of its activation, recirculation, EC 1.3 mS / cm Options Indicators ORP, mV 05.16 05/19 05.21 23.05 05/24 25.05 Average per revolution Nutrient solution on BB (control) before adjustment 160,0 268.4 241.0 270,0 250,0 237.0 237.7 after adjustment 240.0 220.0 250,0 256,0 270,0 220.0 242.6 The nutrient solution in the mixture (KB + AB) before adjustment 222.0 238.1 238.0 270,0 235.0 230,0 238.8 after adjustment 60.1 -67.0 23.0 2.0 20,0 20,0 + 47 ... -67

Table 7 The coefficient of water consumption at the Afitsion salad, depending on the quality of the nutrient solution Options Growing methods Served nutrient solution, l / plant Nutrient solution consumed Harvest of raw biomass, kg / m ² Water consumption coefficient, l / kg Water saving, l / m ² l / plant l / m ² Nutrient solution on BB (control) Recirculation 2.75 1.87 50,5 4.07 12.40 - The nutrient solution in the mixture (KB + AB) - “- 2.77 1.94 52.3 4.47 11.70 0.7 Nutrient solution on BB (control) Water culture 1.74 1.36 36.8 2,32 15.86 - The nutrient solution in the mixture (KB + AB) - “- 1.83 1.45 39.2 2.88 13.61 2.25

Claims (1)

A method of growing green crops in intense light culture, comprising growing plants on peat in a nutrient solution with constant recirculation and maintaining the concentration of nutrients in the working solution depending on the season and its acidity, characterized in that the nutrient solution is prepared on the basis of a mixture of catholyte and anolyte in a ratio of 1: 0.5, the nutrient solution is deactivated during plant growth by adding a mixture of freshly prepared catholyte with anolyte and supporting the redox potential of the nutrient solution is from +100 to -40 mV, while the first 10-12 days the plants are kept on the seedling table and watered with a mixture of activated water, catholyte with anolyte 1: 0.5, pH 9.1.