RU2128417C1 - Method for applying mineral fertilizer solutions into protected ground - Google Patents

Abstract

FIELD: agriculture, in particular, plant growing. SUBSTANCE: method involves preparing solutions of mineral fertilizers, for instance acid-forming fertilizers, and correcting their pH values by thinning with biologically active cathodic water (catholyte) with pH of 9-12. As for neutral and physiological alkaline fertilizers, pH value is corrected by means of biologically active anodic water (anolyte) with pH value of 3-4, or by thinning with mixture of anodic and cathodic water to obtain optimum pH value of mixture for each specific culture. EFFECT: increased plant yield by improved assimilation of nutrient substances, increased soil fertility by increased flexible forms of assimilable nutrient elements and reduced consumption of minerals. 1 dwg, 5 tbl, 3 ex

Description

 The invention relates to agriculture and can be used in crop production of sheltered soil for fertilizing plants with solutions of mineral fertilizers.

A known method of applying liquid organic fertilizers [1], according to which the efficiency of fertilizers is increased by increasing the content of plant nutrition components in ionic form. In the hole, disposed on the one hand plants fertilized with pH ₁ 4 - 6, and into the hole on the other side of the plant fertilizer with pH ₂ 8 - 12, wherein the pH of soil must satisfy pH ₁ <pH primer <pH ₂ . Mineral nutrition reagents such as H ₃ PO ₄ , HNO ₃ , KOH, NH ₄ NO ₃ are used to change the pH of the fertilizer.

 As a result of such fertilizing between the zones, an electric field arises that provides directional transfer of ion charges, which makes it possible to intensify the supply of nutrition components to the root zone of plants.

The disadvantages of this method include:
- a decrease in plant productivity due to the possible temporary inhibition of the root nutrition of plants, caused by the fact that the introduction of strongly acidic fertilizer with pH 4-6 on the one side of the plant and alkaline fertilizer on pH 8-12 on the other hand can lead to disturbance of plant nutrition for a while, because there is acidification of the soil solution on one side of the plant and alkalization on the other side.

 Acidification of the soil solution contributes to the absorption of anions, and alkalization to cations. In this regard, on acidic soils, nitrogen and phosphorus nutrition of plants is disturbed, and the alkaline reaction of the solution causes disturbances in the absorption of potassium, magnesium, trace elements by plants, causing chlorosis and other diseases.

 Since ions of various substances have different activities, and transporting and leveling concentrations in the soil layer takes a certain amount of time, the artificial disturbance caused by the absorption of cations and anions by the roots can lead to metabolic disorders and lower plant productivity.

 In a protected ground with a small volume and high planting density of plants with a highly branched root system, the formation of holes for fertilizing near plants (at a distance of 15 cm and a depth of 15 cm) can lead to partial damage to the root system, which can also reduce plant productivity .

 In addition, cutting holes during trellis growing plants in sheltered soil is a technologically difficult operation.

 Thus, in sheltered soil, it is preferable to fertilize plants according to the conventional method by applying fertilizer solutions with irrigation water.

 Closest to the proposed invention is a widely used method for the preparation of mineral fertilizers in sheltered soil, including the preparation of uterine solutions with a concentration 100 times higher than necessary for plant nutrition, which are brought to the working solution by diluting them with tap water in a ratio of 1: 100, or preparing directly working solutions and their supply to plants.

 The composition of the nutrient solution is prepared at a given concentration for each particular cultivated crop, and in the case of substitution of soils with other substitutes, for example, mineral wool or hydroponic cultivation, the pH of the nutrient solution is adjusted to the optimum value.

 For the preparation of solutions, as a rule, low-saline water is used. If the water used for irrigation is too alkaline, mineral acids are added to it, or fertilizers having an acid reaction (gypsum, alum) are dissolved in it. Adjustment of the pH of the fertilizer solution is done by adding hydrochloric, nitric, or arthophosphoric acids to the working solution [3].

 The disadvantage of these methods of regulating the pH of water and solutions is the need to introduce additional components that change the chemical composition of the solutions and require the installation of special equipment for their dosage and supply.

 To ensure high yields in protected ground, fertilizers are applied that are 2 to 4 times higher than the doses applied to open ground.

 The introduction of high doses of fertilizer in order to increase soil fertility can contribute to disruption of chemical and biological processes, salinization of soils, change the pH of the soil solution, which ultimately leads to a decrease in plant productivity.

 The objective of the invention is to increase the assimilation of nutrients by plants while reducing the dose to make and saving chemical components in the preparation of solutions.

 The problem is solved in the present invention by the fact that in the known method of making mineral fertilizer solutions for physiologically acidic fertilizers, the preparation of their mother or working solutions, pH adjustment and dilution are made with biologically active cathode water (catholyte) with a pH of 9 - 12, and for fertilizers with a neutral (pH 7.0) and alkaline reaction (pH> 7.0) only adjusts the pH with biologically active anode water (analyte) with a pH of 3-4, or prepare solutions of these fertilizers on a mixture of catholyte and anolyte to adjust the pH about the optimal values for each cultivated crop.

 The use of biologically activated waters, such as catholyte and anolyte, as a dilution and adjustment of the pH of a solution of mineral fertilizers, namely, catholyte and anolyte, contributes to the accumulation of mobile forms of the main nutrients (phosphorus and potassium) in the soil, and therefore increases the absorption of these substances by plants and reduces the number of doses applied these fertilizers for the subsequent crop.

 In addition, the use of biological activated waters for adjusting the pH eliminates the need for the use of chemical reagents in the form of acids, and, consequently, the corresponding equipment for their dosage and supply.

 Analysis of the distinguishing features of the present invention does not allow to identify solutions that have signs that match the claimed, namely: the use of activated water to dilute and adjust the pH of fertilizer solutions when they are applied in protected ground, which allows us to conclude that the claimed method meets the criteria of inventive step.

 The drawing shows a graph of the change in pH of water and fertilizer solutions on the ratio of the mixture of catholyte and anolyte.

 As a control experiment, solutions of mineral fertilizers prepared with tap water (BB) with a pH of 6.7 - 7.0 were used.

 As biologically active water, water obtained with electrochemical decomposition in a membrane-type flow-through electrolyzer with pH 3–4 (anolyte) and with pH 9–12 (catholyte) was used.

 Changing the pH of the water was carried out by an ionomer of the I120.2 brand.

 Example 1. As a fertilizer, a solution (extract) of double superphosphate of various concentrations was used when diluting it for control case with tap water with a pH of 6.7 - 7.0 and the experimental one with catholyte with a pH of 9 - 12. A working solution of superphosphate of different concentrations was prepared according to the generally accepted cooking technology. The pH of the solution was determined for each concentration taken in the experiment (see table. 1 at the end of the description).

From the table. 1 it follows that a superphosphate solution prepared in tap water with a pH of 7.0 has a slightly acidic reaction (pH 5.7) at a concentration of 0.5 g / l, and at concentrations of 1 g / l and higher, it is acidic and acidic (pH <5.0) and, therefore, is not applicable for the subcortex of most crops grown on neutral and slightly acidic soils. You can only use a solution with a pH of 5.7 and a concentration of 0.5 for crops such as tomatoes, in which pH _opt 5.5 - 6.5, grown on soils with pH ≥ 6.0.

 You can increase the pH of a superphosphate solution by diluting it several times with water. Moreover, as can be seen from the table. 1, reaching an optimum pH, for example for tomatoes (pH 6.08 - 6.4), at a concentration of 1 g / l, it is necessary to dilute this solution with tap water 3-5 times. As a result, the concentration of this solution decreases by a factor of 3-5, respectively, which is often insufficient for top dressing. It is impossible to obtain a solution of the required concentration (for example, 1 g / l) with an optimal pH when diluted with tap water (with a pH of 7.0).

 Raise the pH of superphosphate solutions by preparing it on catholyte. In this case, it becomes possible to use solutions of higher concentrations, namely: up to 1 g / l, and in some cases (for plants like tomatoes) up to 2 g / l.

 In the case of using a working solution with a concentration of 2 g / l and diluting it with catholyte 2 times, we obtain a solution of the required concentration (1 g / l) and a pH that is satisfactory for a given culture (pH 5.97 - for tomatoes).

In addition, a more complete transition of the water-soluble form of P ₂ O ₅ from superphosphate to an aqueous extract on cathode water was noted. After 13 days of settling the superphosphate solution, 42.50% P ₂ O ₅ passed into the hood on catholyte, and 40% P ₂ O ₅ in tap water.

 Thus, it follows from experience that the use of catholyte for diluting physiologically acidic fertilizers allows one to obtain solutions of the required concentration and pH for a particular culture with a higher content of water-soluble phosphorus compounds assimilated by plants compared to solutions in ordinary water.

Example 2. For the experiments, two physiologically neutral fertilizers and their mixtures were used, for example ammonium nitrate (NH ₄ NO ₃ ) and magnesium sulfate (MgSO ₄ ) with a concentration of 1 g / l of each species, as well as a mixture of acidic (superphosphate) and neutral (ammonia nitrate) fertilizers with a concentration of 0.5 g / l of each type.

 Fertilizer solutions were prepared on tap water (control) with a pH of 6.8 on catholyte with a pH of 10.5 and on anolyte with a pH of 3.25, as well as on a mixture of catholyte with analyte in different ratios. The results of the experiment are presented in table. 2. (see the end of the description).

 If we present the results of the experiment in the form of a graph of the change in pH from the percentage ratio of catholyte (CV) and anolyte (AB) (the graph on the abscissa shows two scales: the percentage in the KB solution is from 0 to 100% and AB is from 100% to 0 ), we can conclude that to obtain a solution of each type of fertilizer (or a mixture of two types) with a given pH value, it is necessary to mix catholyte with anolyte in the appropriate proportions, for example, presented in table. 3 (see the end of the description).

 Thus, the analysis of the table. 3 and graph 1 showed that it is possible to adjust the pH of solutions of any fertilizer without using expensive hazardous chemical components in the form of acids, caustic alkalis, etc.

 Example 3. The effect of fertilizing fertilizers prepared on activated waters was studied on a tomato and celery culture, and the effect of a mixture of 2 waters (anolyte and catholyte) on the cultivation of Beijing cabbage and tomatoes.

 Plants were grown on horse peat, previously deoxidized and seasoned with a mixture of fertilizers containing nitrogen, phosphorus, potassium (N, P, K) according to the accepted technology for the preparation of nutrient substrates in protected ground.

 The peat substrate in the experiment and control for the period of sowing seeds had a uniform pH value.

 All experiments with celery and tomatoes were carried out on a shortened culture: the period of celery cultivation before harvesting was 90 days from the time of sowing or 48 days from the day of diving seedlings. The seedling period of tomatoes was 50 days, the harvesting period was 90 days.

 As a control, an option was taken when watering with tap water and fertilizing with fertilizer solutions prepared with tap water. Fertilizing in the experiment and control was carried out once in 7-10 days of the technology for growing a particular culture. When top dressing was used fertilizers containing nitrogen, phosphorus, potassium, magnesium.

 An experimental version for each cultivated culture was watered with catholyte, anolyte, or a mixture of catholyte with anolyte, bringing the pH of the mixture to 6.0. Accordingly, fertilizer solutions for each option were prepared in these waters.

 In the table. 4 (see the end of the description) shows the results of experiments when irrigated with different waters (catholyte and anolyte), and in table. 5 (see the end of the description) - the results of experiments during irrigation with mixed waters (KV + AB) with adjusting the pH to 6.0.

 From the table. 4 it follows that when growing celery on a slightly acidic substrate (pH 6.25), its growth and development is affected by watering and feeding with activated water (catholyte and anolyte). The yield increase in the catholyte variant was 17%, and in the catholyte variant it was 17%, and in the anolyte variant it was 28%. Moreover, when catholyte is irrigated, the quality of production also increases: the percentage of dry matter in celery leaves was 11.50%, which is 1.15% higher than that of control plants (10.44) and is an increase of 11% with respect to control (BB )

 Watering and top dressing with activated waters of tomato culture showed that at the stage of growth and development of seedlings, both catholyte and anolyte are stimulants (an increase in green mass was noted, a run in the appearance of buds on the 1st flower brush). However, when harvesting, the option with watering and top dressing with anode water was comparable with the control option (yield is 3% lower than the control), and in the variant with catholyte, a yield increase of 18.9% was obtained.

 Irrigation with a mixture of catholyte and anolyte resulted in an average increase in green mass growth in tomato seedlings of up to 160%, as well as an average yield increase in tomatoes by 32%, in Beijing cabbage by 29.5%.

 Thus, the use of biologically activated water for irrigation and preparation of fertilizer solutions helps to stimulate the growth and development of plants and increase the yield of certain types of plants (celery when irrigated with both catholyte and anolyte, tomatoes - when irrigated with catholyte), and the use of a mixture of activated water (catholyte with anolyte) helps to increase the yield of both green (Beijing cabbage) and tomatoes.

Agrochemical analyzes of peat soils during the experiment, for example, with tomatoes, showed that in the catholyte variant the mobility of water-soluble phosphorus increases during the growing season (the P ₂ O ₅ content in the experiment was 45.1 mg per 100 g of soil, in the control 27.7 mg / 100 g, the content of K ₂ O in the catholyte variant is 124.8 mg / 100 g of soil and in the control, 83.3 mg / 100 g of soil).

 Thus, the use of two waters (catholyte and anolyte) activated by electrochemical methods during the growing season during the growing season for fertilizer solutions of mineral fertilizers makes it possible to increase the yield of plants by adjusting the pH of the solutions and irrigation water, and therefore by increasing the digestibility of nutrients by plants , and also helps to increase soil fertility, by increasing the mobile digestible forms of nutrients (for example, superphosphate, potassium), etc. ultimately leads to the saving of mineral fertilizers.

Sources of information
1. The method of applying liquid organic-mineral fertilizers. A.S. N 1 544 298 A1, CL A 01 C 21/00, publ. 01/30/89 bul. N 4 (analogue).

 2. Gluntsov N.M. Fertilizer use in greenhouses. - M.: Moscow Worker, 1987, p. 99 - 100, 104 (prototype).

Claims (1)

The method of introducing solutions of mineral fertilizers, including preparing solutions of the required concentration, adjusting their pH, feeding to the root system of plants, characterized in that for physiologically acidic fertilizers preparing solutions and adjusting their pH is done by diluting with biologically active cathode water (catholyte) with a pH of 9 ^o 12 c, and the fertilizer to the neutral and alkaline pH adjustment is carried out by reacting a biologically active anode water (anolyte) having a pH of 3 or 4 ^o c by diluting the mixture of the cathode and anode od adding the mixture to the optimum pH for each particular culture.

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