SU1491429A1 - Composition for treating growing grapes - Google Patents

Abstract

The invention relates to chemical means of regulating the growth and development of plants and may find application in plant growing, in particular, in viticulture. The purpose of the invention is to increase the yield. According to the invention, grape plants are treated in the growth phase with a composition containing 4% polyvinyl alcohol, 0.5-1.0% alkaline hydrolyzate of the protein-vitamin concentrate of biomass of microorganisms grown on hydrocarbon oil, and water up to 100%. An alkaline hydrolyzate is obtained by heating a protein-vitamin concentrate with caustic soda to a PH of solution 13. The use of this composition improves the yield of grape plants and reduces the negative effect of polyvinyl alcohol on the development of plants under rainfed conditions.

Description

The invention relates to chemical means of regulating the growth of plants and can be used in plant growing, in particular in viticulture.

The purpose of the invention is to increase the yield.

The experiment was carried out under the following conditions. In each treatment variant with different compositions, the film former has 20 bushes of grapes, which, prior to treatment, in early spring, line up in growth, leaving an equal load on each bush - 37 buds. All agrotechnical measures are carried out in accordance with the generally accepted guidelines for the care of the vineyard.

Each row of treatment option with metering bushes is isolated on both sides with protective untreated rows of the vineyard.

The feeding area of the grape bush is 6 m, the distance between the rows is 3 m, and between the bushes is 2 m.

Background of experience: carbamide up to 90 kg of active ingredient (ai) per hectare, superphosphate 100 kg / ha ai, potassium chloride - 60 kg / ha ai The treatment with the formulations is carried out immediately after the end of the rainy period (end of June), in the growth phase of the year, by spraying.

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The soil moisture during the treatment period is,%: at a depth of 200 mm 10.2; at a depth of 100 mm 12.1; at a depth of 25 mm 13.2.

Transpiration is determined once a week throughout the BereTaiuioH period.

The results are presented in the table.

The protein-vitamin concentrate (BVK) is a biomass of microorganisms infused on H-paraffins of oil. Its composition includes nitrogen, proteins, fat, carbohydrates, nucleic acids, ash, as well as macronutrients: phosphorus, potassium, calcium. In addition to all the listed components, vitamins are not included in the biomass composition.

Example 1. Composition of 2% PVA + 0.1% BVK + 11 0 hydrolyzate is prepared as follows. 2 kg of PVA is dissolved in 97 l of water, stirring and heating up to 80-90 seconds for 1 hour. A solution of the BVK hydrolyzate is prepared separately, for which 100 g of BVK is dissolved in 1 l of 0.5 mol / l NaOH solution, heating at 30-40 C for 6 hours

These parameters are due to the fact that the reaction is carried out until the BVK is completely dissolved and a homogeneous solution is obtained. The pH of the BVA hydrolyzate is 13. The dynamic viscosity of the BVK hydrolyzate solution is determined. With a shear stress (in the spray area of the solution) equal to Ig 1 2.9-3.6 Ig viscosities, IE P 2.6-3.3 is obtained. When using a solution of alkali lower concentration

five

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five

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The yield is 4.6 kg / bush. The transpiration intensity two weeks after the bushes are treated with an anti-transpirant is 6.01 U g / h. m

Yield within the error of experience is equal to the yield of options with water, PVA + starch, in BVK, in pure 4% PVA.

The intensity of transpiration is lower than in versions with water and BVK,)) o higher than in variants with pure 4 / PVA and PVA + starch.

Example 2. The composition of 4% PVA + + 0.1% BVK + N., 0.

The composition is prepared according to Example 1, except that a solution of 4 kg of PVA in 95 liters of water.

The yield of the variant (5.96 kg / ku (t} is higher than in the versions with water and in example 1 and within the experimental error is equal to the yield in the variants with known composition, with BVK, with pure 4% PVA. The intensity of transpiration in two weeks after treatment, it is equal to 5.5 -lO g / h-m. This value is significantly lower than for the variants with water and BVK, and is close to the transpiration intensity on variants with pure 4% PVA, according to the known composition, as in example 1.

Example 3. The composition of 5% PVA + + 0.1% BVK +.

The formulation is prepared as in Example 1 with the exception that 5 kg of PVA is dissolved in 94 liters of water.

The yield is 6.01 kg / bush, within the experimental error is equal to the yield of the variant with

do not get a homogeneous solution of measure 2. The intensity of transpiration

rolizat. The same can be said for the duration of the process. With an increase in alkali concentration above 0.5 mol-l, the hydrolyzate solution has very high pH values, which adversely affects the properties of the antistranspirant composition. With an increase in the hydrolysis temperature, the hydrolyzate solution becomes non-uniform.

does not differ from the intensity of the transport of the variant of example 2.

A further increase in the content of PVA in the composition (for example, 6–8%) is advisable, since it leads to the fact that the leaves in extreme climatic conditions of the bogaras overheat and the normal viability of fluoride is impaired. As can be seen from the data given in examples 1-3, the optimum content of PVA in the antitranspirant composition is 4%.

The prepared solutions of PVA and hydrolyzed BVK mixed. The resulting product is sprayed with pink six year old Tayfi grape bushes. To treat 1 hectare of vineyard, 800 l of the proposed composition is required, and with increasing age of the vineyard, the consumption of a cititerant increases to 1000 l

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does not differ from the intensity of transpiration of the variant of example 2.

A further increase in the PVA content in the composition (e.g., 6-8%) is impractical, since it leads to the fact that the leaves in the extreme temperature conditions of the bogaras overheat and the normal viability of the plants is disturbed. As can be seen from the data given in examples 1-3, the optimal content of PVA in the composition of the antitranspirant is 4%.

The following two examples are given to select the optimal containing 1 and BVK in the composition.

Example 4. The composition of 4% PVA + + 0.5% BVK + HjO.

The composition is prepared according to Example 2, except for dissolving

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0.5 kg BVK in 1 l 0.5 mol / l NaOH solution.

Productivity 6,61 kg / bush. This value is higher than in the variants with water, BVK, a known compound, pure 4% PVA and in example 1, and within the experimental error it is equal to the yield in example 2 and 3. The intensity of transpiration through two pedals after treatment is 4.01 1 O g / h m is the highest in comparison with the other 1 variants.

Example 5. The composition of 4% PVA + + 1, 0% BVK + NgO.

. The composition is prepared according to Example 2 with the exception that 1 kg of BVK is dissolved in 2 liters of 0.5 mol / l NaOH solution, and 4 kg of PVA is dissolved in 94 liters of water. The yield is 6.73 kg / bush, which, within the experimental error, is equal to the yield of example 4. The intensity of transpiration after two weeks after treatment is equal to 4, 3 g / h and differs little from the intensity of transradium of variant 4 .

The table shows the agrocompilation indicators of grapes for the control variant and variants with different ingredients and composition.

Increasing the concentration of hydrolysis of l BVK in the composition up to 1.0 allows a slight increase in yield in comparison with the optimal variant of PVA sovm - h

185234

337341

16.819.5

20.5519.35

9.0 8.2

244 383 16.8

18,8

5.0

6

topically with 0.5% BVK and pre-chemical, but an increase in the concentration of BVK above 0.5% is undesirable because of the increase in alkalinity of the solution and the higher cost of the composition.

The achieved effect from the use of alkaline hydrolyzate BVC in the composition is ensured by the fact that BVK plays the role of a biologically active substance. and an adhesive structuring agent that improves the quality of the films, forms grape plants and allows for more economical use

moisture, and also eliminates the inhibition of plants.

Claims (1)

Invention Formula Composition for treating grape plants, including polyvinyl alcohol and water, characterized in that, in order to increase yields, it additionally contains an alkaline protein-vitamin concentrate hydrolyzed with caustic soda to a pH of 13, in the following ratio of components, wt.%: Polyvinyl alcohol4.0 Protein-vitamin concentrate, hydrolyzed with caustic soda to a pH of 13 per initial) 0.5-1.0 Water Rest 196.1 357 18,8 18.9 202 343 19.0 18.4 214 351 287 359 18,8 18.8 19.4 220 358 19.5 20.5 24 15.8 0.8 6.01 5.5 5.6 4.01 4.4