RU2307505C1 - Agent for controlling of suctorial insects and method for production thereof - Google Patents

Abstract

FIELD: organic chemistry, in particular agent for controlling of sanguivorous insects.

SUBSTANCE: claimed agent contains (mass %): liquid insecticide soap 0.5-1.0; Atremia sp. hydrolysate 0.5-1.0, and balance: water. Method fro production of said agent also is disclosed.

EFFECT: working emulsion with increased moistening activity and effectiveness; improved agent for aphis controlling.

2 cl, 4 tbl, 4 ex

Description

The invention relates to the field of agriculture and can be used in gardening, horticulture and floriculture of open and protected soil.

Known chemical agents for controlling sucking pests, which are various pesticides (Prokofiev M.A. Protection of Siberian gardens from pests. - M., 1987. - 239 p.). Pesticide residues pollute the environment and agricultural products, worsen its quality.

The closest in technical essence and the achieved result (prototype) is a means of combating sucking pests, in particular aphids, using liquid household insecticidal soap from rapeseed oil (RF Patent No. 2222572, publ. 2004.01.27).

As a working solution for treating plants using a 1% aqueous solution of this insecticidal soap.

The disadvantage of this tool is the decrease in efficiency in the processing of densely populated aphid colonies due to their incomplete wettability, as well as an insufficiently wide spectrum of action.

The technical task of the present invention is to increase the effectiveness of the drug by expanding its spectrum of action and the method of its production.

The stated technical problem is achieved in that a cyst hydrolyzate Artemia sp. Is added to a liquid insecticidal soap from rapeseed oil. This hydrolyzate is obtained by sequential treatment of cysts of Artemia sp. potassium hydroxide and phosphoric acid. So, to obtain this hydrolyzate to 1 kg of cysts Artemia sp. add 10 l of a 40% aqueous solution of potassium hydroxide and the mixture is kept at room temperature for 120 hours. Then, a 40% aqueous solution of phosphoric acid is gradually added to this mixture until a pH of 7.5-9 is reached.

Cysts Artemia sp. have the following characteristics: the diameter of the egg is 180-200 microns and 1 g of cysts contains 240,000-270,000 eggs; and are characterized by the following composition (wt.%): dry matter 94.1% (including crude protein 58.5; crude fat 6.5; chitin 8.5); B vitamins; amino acids (lysine, methionine, cysteine, tryptophan); 35 fatty acids and trace elements - Cu, Zn, Co, Mn. Cysts Artemia sp. live in the salt lakes of Western Siberia.

Introduction to liquid insecticidal soap hydrolyzate Artemia sp. improves the wettability of densely populated colonies, which allows to obtain high efficiency against various types of aphids, and the content of a set of 35 fatty acids in the hydrolyzate of Artemia sp. increases the selective toxicity of liquid insecticidal soap against aphids. At the same time, this composition with the hydrolyzate of Artemia sp. non-toxic to the natural enemies of aphids - various types of ticks. In addition, the hydrolyzate of Artemia sp. contains nutrients for weakened plants - potassium phosphate, amino acids and chitosan - a plant growth stimulator.

The tool is prepared as follows. To obtain a mother liquor, 50 ml of a hydrolyzate containing Artemia sp. Is added to 50 g of green soap, placed in a container of a tissue grinder PT-1 and mixed for 8-10 minutes. A liquid, creamy brown mass is obtained. The volume of the concentrate is adjusted to 10 liters, a 1% working solution is obtained, which is used for spraying from a backpack sprayer with a flow rate of 0.1-0.5 liters per plant in garden and vegetable crops and 1 liter per 1 m ² in melons and gourds.

Studies have shown that the tool is most effective at concentrations of 0.5-2.5%. Moreover, the most effective composition with a content of 1-2%. When its concentration decreases from this value, a smaller fraction of aphid colonies is wetted and the processing efficiency decreases. With increasing concentration, the death of natural aphid pests begins and signs of leaf burn appear.

Tests of one hydrolyzate of Artemia sp. at a concentration of 0.3-1% showed its weak acidic activity against various types of aphids due to poor wettability of objects.

Addition of Artemia sp. in insecticidal soap increases the activity of the drug, enhancing its toxic effect, possibly due to the content in its composition of fatty unsaturated acids that are absent in the insecticidal soap.

The drug was tested on seedlings of apple, blackcurrant, viburnum, and raspberry, in plantings of cabbage and cucumbers, as well as on indoor plants. Experiments on spraying these crops were carried out in 4 replicates.

Pest death was recorded 1 day after treatment by viewing under a microscope MBS-9 ten damaged leaves and young shoots in each repetition and counting the number of live and dead individuals. In this case, the population density of aphid colonies was taken into account. Colonies with up to 30 individuals were classified as low-populated, over 250 individuals - as highly populated.

The data obtained were processed according to the method of K.A. Gara (Methods of testing the toxicity and effectiveness of insecticides. - M., 1963. - 286 p.)

A search by the applicant for scientific, technical and patent sources of information and prototypes selected from the list of analogues [1] made it possible to identify distinctive features in the claimed technical solution. Therefore, the claimed method of obtaining satisfies the criteria of the invention of "novelty." An additional search by the applicant for known technical solutions in order to detect features similar to those of the distinctive part of the formula of the claimed production method showed that these signs are absent, therefore, the claimed technical solution meets the criterion of "inventive step".

The criterion of the invention "industrial applicability" is confirmed by the fact that the proposed method of obtaining a means of combating sucking pests allows you to get in industrial production a drug that is quite simple to manufacture and relatively cheap due to the lack of expensive equipment in the technological scheme, but with a pronounced selective effect and growth-promoting properties.

The inventive tool and method for its preparation is illustrated by the following examples.

Example 1. In a 40 L reactor equipped with a propeller stirrer, 15 L of insecticidal soap obtained from rapeseed oil and 15 L of Artemia sp. with pH = 8.5. The stirrer is turned on and the mixture is stirred for 30 minutes. Then this mixture is dosed into a reactor with a volume of 4 m ³ , which contains 2970 l of water. The mixture is stirred for 40 minutes. Thus, a working solution for treating plants is obtained.

Table 1 presents data on the effectiveness of the claimed funds against various types of aphids in horticultural crops under laboratory conditions.

Table 1
The effectiveness of drugs against various types of aphids in horticultural crops. Preparations Concentration,% Population The death of aphids,% green apple gooseberry viburnum raspberry shoot Rapeseed oil insecticidal soap (prototype) one low one hundred 95.4 one hundred 97 high 90.8 29.3 97.3 5.7 Rapeseed oil insecticidal soap + hydrolyzate Artemia sp. (50/50) 0.5 low 87.4 85.6 90.0 63,2 high 85,4 74.5 88.9 41.8 one low one hundred one hundred one hundred one hundred high 99.7 97.7 96.9 96.5 1,5 low one hundred one hundred one hundred one hundred high 99.3 98.4 97.3 98.6 2 low one hundred one hundred one hundred one hundred high 99,2 99.3 97.8 99.1 2.5 low 95.2 95.4 95.1 96.0 high 93.3 92.1 93.2 94.6 Control - no processing - low 0 0.2 0 0.9 high 0.3 6.9 2,5 3,5 NDS 0.05 - low 5,4 20.3 6.9 10.5 high 6.8 25.8 8.7 13,4

As can be seen from table 1, the maximum effectiveness of the proposed means of combating colonies is upon administration of a liquid insecticidal soap with cyst hydrolyzate in a concentration of 1-2% and depends on the density of colonization of aphid colonies. This concentration provides 100% processing efficiency for all types of aphids at a low population density of colonies and 96.5-99.1% at a high degree of colonization. A further increase in the concentration of the hydrolyzate is impractical due to the fact that the processing efficiency is reduced.

Example 2. The drug obtained by the method in example 1 was tested in the field (table 2). At the same time, we observed the development of plants.

table 2
Acidic activity and development of apple trees on different treatment backgrounds. Variety Firebird. Preparations Concentration,% The death of aphids,% Growth, m 06/23/05 07/13/05 total from the point of damage Rapeseed oil insecticidal soap (prototype) one 92.3 93.1 8.1 4.1 Rapeseed oil insecticidal soap + hydrolyzate Artemia sp. one 95.0 95.8 13,2 7.0 Control - no processing - 3,1 12,4 5.3 0.8 NDS 0.05 - 5,4 7.9 3.8 1,6

These data show that liquid insecticidal soap in its pure form caused the death of the pest at the level of 92.3-93.1%, while a mixture of liquid insecticidal soap with the hydrolyzate of Artemia sp. increased processing efficiency to 95.0-95.8%.

Further observations of the development of experimental plants showed that by the end of the growing season of the apple tree when treated with liquid insecticidal soap, the growth was 8.1 m per plant, and against the background of spraying with liquid insecticidal soap, additionally containing Artemia sp. - 13.2 m. The growth rates from the point of damage are especially characteristic. Against the background of treatment with liquid insecticidal soap, additionally containing the hydrolyzate of Artemia sp. the increase was 7 m, which is 1.7 times higher than in the prototype and 5.8 times higher than in the control. These data indicate a significant stimulating effect of liquid insecticidal soap containing hydrolyzate Artemia sp. in comparison with the prototype.

Biochemical analysis of the fruits showed that the treatment of the apple tree with liquid insecticidal soap, additionally containing the hydrolyzate of Artemia sp. contributed to an increase in the accumulation of solids, in comparison with the prototype from 11.6 to 14.8%. Differences in the content of sugars, acids and vitamin C were insignificant (table 3).

Table 3
The biochemical composition of apple fruits on different processing backgrounds. Variety Firebird. A drug The concentration of hydrolyzate,% Solids,% Sugar,% Acidity% Sugar Acid Index Vitamin C, mg /% Rapeseed oil insecticidal soap (prototype) one 11.6 11.5 1,1 10.5 14.9 Rapeseed oil insecticidal soap + hydrolyzate Artemia sp. one 14.8 11.9 1,2 9.9 16,2 Control - no processing - 13,4 9.8 1,1 8.9 14.8

Thus, liquid insecticidal soap, additionally containing Artemia sp. Hydrolyzate, possibly due to increased wetting activity, increases the efficiency of processing densely populated aphid colonies in various garden crops, has a stimulating effect on the development of apple trees and increases the content of dry soluble substances in fruits.

Example 3. The drug obtained by the method in example 1, was tested in the field on plants of vegetable and melons (table 4).

Table - 4
The effectiveness of liquid insecticidal soap preparations against various types of sucking pests. A drug Concentration,% The death of pests,% Larvae of predatory gall midge (natural enemies of aphids) cabbage aphids gourd aphids shields cucumbers watermelons Rapeseed oil insecticidal soap (prototype) one 82,4 74,2 70,4 73.3 0 2 one hundred 94.6 92.4 90.1 35.8 Rapeseed oil insecticidal soap + hydrolyzate Artemia sp. one one hundred 97.4 98.0 99.0 0 2 one hundred 98.6 97.6 one hundred 0.3 Control - no processing - 8.0 10.1 7.6 2.1 0.1 NDS 0.05 - 13.6 18.9 16,4 8.3 0.3

The effectiveness of liquid insecticidal soap at a concentration of 1% on cucumbers and watermelons against melon aphids was 70.4-74.2%, and only when the concentration of the working solution was doubled, the efficiency increased to 92.4-94.6%.

An additional introduction to the insecticidal soap of Artemia sp. allows to obtain high processing efficiency (97.4-90%) at 1% concentration of the working solution.

Testing the effectiveness of liquid insecticidal soap with an additional content of Artemia sp. showed the possibility of using it not only against various types of aphids, but also against scrubbing on indoor plants with an efficiency of up to 99% at a concentration of working solution of 1%, while insecticidal soap in its pure form (prototype) ensures death at the level of 73.3% . When the concentration of the working solution of insecticidal soap is doubled, the efficiency increases only to 90.1%, that is, it is lower than when treating plants with a mixture of soap and hydrolyzate Artemia sp. at a concentration of 1%.

The high insecticidal effect of soap containing Artemia sp. Hydrolyzate is probably due to the presence of arachidonic acid in it, which has an insecticidal effect. Tests have shown that, thanks to its high wetting activity, a composition containing liquid insecticidal soap and Artemia sp. Hydrolyzate can be used to protect against brushing on almost all indoor plants, regardless of the level of hydrophobicity of the leaf surface.

Example 4. The drug obtained by the method in example 1, was tested for toxicity in relation to the useful entomo- and acarofauna of garden crops.

The results showed that a 1% working solution of the drug, containing insecticidal soap and cyst hydrolyzate of Artemia sp., Is not toxic to predatory mites on the apple tree, as well as to larvae of various types of predatory gall midges on fruit, berry, vegetable and melon cultures. They fully remain viable at a concentration of working solution - 1%, while an effective concentration of liquid insecticidal soap - 2% causes the death of predatory gall midge larvae by 35.8%.

Thus, a method of controlling sucking pests based on the use of liquid insecticidal soap from rapeseed oil, additionally containing as a biologically active additive, Artemia sp. in comparison with the prototype, it has a wider spectrum of action and can be used not only for combating aphids, but also with scabies on indoor plants. It also allows you to reduce the effective concentration by half, and demonstrates the selective effect in relation to beneficial insects.

The use of insecticidal soap, additionally containing Artemia sp. Hydrolyzate, to protect the apple tree from green apple aphids has a stimulating effect on plant development and increases the dry matter content in fruits.

Claims (2)

1. A means of controlling sucking pests, including liquid rapeseed oil insecticidal soap, characterized in that it additionally contains Artemia sp. in the following ratio of components, wt.%: liquid insecticidal soap 0.5-1.0 hydrolyzate Artemia sp. 0.5-1.0 water rest 2. The method of obtaining funds according to claim 1, characterized in that to obtain funds dry cysts Artemia sp. treated with a 40% aqueous solution of caustic potassium in a volume ratio of 1: 5 at room temperature for 120 hours, adjusted to pH 8-9 by adding a 40% aqueous solution of phosphoric acid, mixed with an equal volume of rapeseed oil insecticidal soap and 99 volumes of water are added per 1 volume of the resulting mixture.