HU230304B1 - Carriers for pesticides and process for the preparation of pesticide-films with good adhesiveness - Google Patents

Abstract

The present invention provides a polymerizable film containing drying oils for use in plant protection products carriers, and adherent, controllable, pesticidal agents containing such carriers It applies. The present invention also relates to a process for forming a plant protection product film comprising such a carrier.

Description

FIELD OF THE INVENTION

The present invention can be used in a plant protection agent for a carrier for the polymerization of Ilim-forming oils containing drying oils, and for a carrier containing such carriers. BACKGROUND OF THE INVENTION This invention relates to a process for the preparation of a plant protection product containing such a carrier,

LITERATURE BACKGROUND

An important aspect of modem plant protection is that the materials used cause the least possible environmental impact while achieving the desired effect. Therefore, it is extremely important to facilitate the absorption of the applied active ingredients and to maintain the effects for a sufficient period of time. After application, plant protection products are often rendered prematurely ineffective by their environmental effects. Among other environmental effects, esd, leaching, bidrolytic processes and light effects greatly impair the desired results. This is the reason that nowadays the primary properties of a given active ingredient are transitory, and the role of colloids created by physical and chemical enhancements has increased. Equally important is the use of interdispersed oils in various technical fields. For a long time, various mineral oil derivatives, such as paraffin oils and petroleum oils, have been used as adhesives. However, they are increasingly unacceptable from an environmental point of view, and, in addition, are significantly re-emulsified and washed away and may cause scorching effects on the environment. Animal fats, and its use is not fortunate from a public health point of view.

Drying oils have long been used in the comb industry and in corrosion protection. Drying oils bind the protective pigments (e.g., iron oxide red or organic pigments and the like) to the metal or other surfaces to be protected, thereby forming a hard, abrasion resistant layer.

Hungarian patents 223091 and 223092 relate to plant protection products with improved shelf-life and efficacy, which are defined in claim 1 as an organic or inorganic germicidal active ingredient, a vegetable oil, preferably rapeseed or sunflower oil, antioxidant sulfur TMTD (tetramethyl), in addition, they also contain other additives. These formulations are fundamentally different from the plant protection agents of the present invention in that they contain TMTD. TMTD is a potent antloxidant compound which is administered by the authors to inhibit rotting and to improve shelf life. However, TMTD significantly slows down the polymerization processes and therefore cannot produce high quality Olm in its presence. Accordingly, no polymerization or foam formation was observed with these formulations and is not mentioned in the cited documents.

Hungarian patent application P060010S discloses compositions having enhanced action and stability, comprising various fungicidal active ingredients, and also vegetable oil, preferably rapeseed or sunflower oil, in addition mineral oil, oleol, light-absorbent and anhydrous. there are also mineral oils that do not polymerize under environmental conditions. The formulations used in the tests described in Description A contained 1: 1 to 1: 3 mineral: vegetable and vegetable oils. Breasts of such ratios cannot be produced by drying oils in the form of a solid Smooth. Accordingly, the formation of a polymer / aleol or a well-adherent solid backing layer is not reported or implied herein.

International Publication No. WO2 / 11119891 discloses compositions of a carrier oil of high mineral oil content, which have been used for pesticide application on rubber crops and other crops \ alo ktjmteansam.

U.S. Patent Application Publication No. US07 / 0053947 discloses pubic, moss and algae compositions containing desiccant and semi-desiccant vegetable oils, which are used as additives in antioxidants. These compositions differ from the present invention in that they contain antioxidants and adjuvants that assist the composition.

[alpha] -Lamilone Jbestie Seb, 37, 141-146 (1993)] summarizes the properties of mineral and vegetable oils for use in pesticides. The document focuses on volatile derivatives and solutions to prevent oxidation of oils.

The aim of our work was to develop a plant protection product which, when applied to foliage or other plant surfaces, becomes irreversibly protective film, thereby increasing its effective efficacy.

The above object is achieved by the use of a carrier containing drying vegetable oils. As a result, the plant protection product is transformed into a solid Sime in the natural environment, resulting in an enhanced plant protection effect.

The pesticide and coating coat that we developed containing the Slmim / Oo carrier promotes absorption and regulates the release of the active ingredient, while not inhibiting plant metabolic processes such as uptake and release of water and electrolyte, and respiration.

SUMMARY OF THE INVENTION

The present invention is based on the discovery that the drying air undergoes polymerization in the open air, which solidifies it. This property is useful in pesticides which, when applied as an oil or oil-in-water suspoemulsion to the plant or its environment, disappear within a few hours / pads and coatings are used to provide a highly effective, well-adherent pesticide,

Találntány the ^present: invention thus can be used in plant protection poHmerizálhafo, ilmképző carrier forms.

The present invention relates to a vehicle for use in plant protection products comprising as a film-forming oil a drying or over-drying vegetable oil, optionally foci and a non-or slightly acidic vegetable oil as a steeping oil.

In some embodiments of the present invention, the drying or over-drying vegetable oil is selected from the group consisting of sunflower oil, soybean oil, pumpkin seed oil, poppy oil, nut oil, cottonseed oil, linseed oil, hemp oil, grape seed oil, sesame oil, shea oil and non-vegetable oils; rapeseed oil, palm oil, olive oil, ricirmsohi and mixtures thereof.

The present invention also relates to pesticides comprising an active ingredient of the present invention, optionally one or more active ingredients and additives commonly used in the manufacture of the pesticide.

In certain embodiments of the invention, the plant protection agent is a highly adherent plant protection agent with adjustable properties.

In certain embodiments of the invention, the plant protection agent is a plant protection agent having a controlled release, controlled release, controlled release, absorption, atmospheric oxygen uptake, and / or antioxidant action,

In certain embodiments of the invention, the plant protection agent optionally comprises, but is not limited to, one or more of the active ingredients of fongield; elemental lubricant, copper hydroxide, resoxychloride, copper oxide, copper sulfate on base, captan (N-l-trichloromethylthio) tetrahydrophthalic acid, tebuconazole {(RS) -1-p-chlorophenyl-4.4- dimethyl-3- (1H, 2,4-triazol-1-dmole> pethan-3-ol), thiopyanate methyl (dimethyl-4,4 '- (o-phenylene) bis (C 3 -thioallophonate)}.

In embodiments of the invention, the plant protection agent of the present invention is, for example, a meadow, a pesticide synsperm, a dressing or a wash oil composition.

The invention further relates to a process for the preparation of a polymerized plant protection product which comprises dispersing the plant protection product of the invention in the field of application and allowing the plant oils present in the substance to undergo polymerization for several hours or days to form a polymerized plant protection product. we get a needle,

In some embodiments of the invention, the plant protection agent film of the invention is formed on a plant or its root, stem or leaf or seed or field or other growing medium,

DETAILED DESCRIPTION OF THE INVENTION

The invention thus relates to a solidifying Elmet-forming compound which can be used in plant protection products. This oil is a dehydrating or winter-drying vegetable oil, optionally peel off and optionally a non-flocculating oil. or lightly dry vegetable, contains oil.

It will be appreciated that the carriers of the present invention, without the addition of separate initiators, will be converted into a solid film upon exposure to the natural oxygen content of the air and form a film with a highly adherent surface property. When used in plant protection products, these pesticides form a solid tilm coat which is well adhered to the treated area, for example a plant.

In some embodiments of the invention, the plant is a drying or winter-drying plant; oil; sunflower oil, soybean oil, pumpkin seed oil, poppy seed nut oil, cottonseed oil, linseed oil, hemp oil,, oloo 'agave oil, sesame oil, oleaginous oil and mixtures thereof, and non-or slightly dehydrated vegetable oil, rapeseed oil, palm oil, palm oil, selected

The drying oil used in the carrier according to the invention is preferably but not limited to sunflower seed oil or linseed oil.

According to the intended use of the composition of the invention, the consistency of the Smlayer can be controlled. This is usually done with, but is not limited to, non-drying or low-drying oil, in addition to rhyme-forming oil.

The surfactant solubility of the base layer is added to the esterified vegetable oils and optionally other solvents. controlled,

In embodiments of the invention, the plant protection agent of the invention is, for example, a spray.

pessimistic suspoemulsion, dressing or lotion oil composition. However, the plant protection agent of the present invention is generally well applicable in many fields of agrochemistry.

The compositions of the present invention exhibit a significant increase in efficacy and potency. The solidifying Sm causes the contact pesticides to surface mist and promotes the absorption of systemic pesticides. In addition, the properties of the resulting coating can be varied over a wide range according to the nature of the particular plant protection product or the nutrient used for the particular plant or soil.

The plant protection agent containing the film forming agent of the present invention also provides improved protection to environmental oxygen-sensitive active ingredients by both the covering effect of the film and the slow uptake of oxygen and by the natural anti-coding effect of vegetable oils.

The carrier emulsifier of the present invention optionally contains plant leitin. Oleitin is an antioxidant substance which is widely used in the food and pharmaceutical industries as preservatives, enamels and sciators. Are you surprised by that? we have come to the realization. Despite these properties of olein, hogs do not inhibit drying oils, polymerization processes, and film formation, and are thus advantageously used in the flin forming vehicle of the present invention. In the presence thereof, a thin, weather-resistant film is formed relatively quickly, i.e. at least a few hours or a day. In addition, by hanging on its antioxidant effect, it protects the formed grass and inhibits unwanted processes such as rotting, and has a protective effect on oxygen-sensitive drugs.

For example, as vegetable herbicides for use in the carrier of the present invention, for example, soybean lecithin or cracked, commercially available formulations may also contain the appropriate vegetable oil. An example of such a preparation is the Lecleo MASO IPM mentioned in the additional tray.

A. In the compositions of the invention, the weight ratio of drying oil to non-drying oil is preferably not more than 5: 1 and the weight ratio of fecithin to vegetable oils is generally about 1: 5 to 1; in the range of 1:20 to 1.50.

The plant protection composition of the present invention is generally in the form of an emulsion or a suspension.

Formulations of suspoemulsion form A generally contain from about 3% to about 30%, preferably from about 15% to about 20%, by weight of a softener oil, (1-8% by weight film-setting oil and (1.3-3% by weight lecithin emulsifier, and 1-5% by weight). preferably containing 2 to 3% by weight of an ethoxylic fatty acid emulsifier.

The suspoemulsion composition comprises, for example, one or more of the fungiide selected from the group consisting of: elemental sulfur, copper hydroxide, captan, thiolhnate-methyl, techconazole). These are examples of advantageous examples! the following combinations; sulfur / copper hydroxide, sulfur / thiophanate methyl / tebncona.zol, copper hydroxide. tebuconazole.

The syndrome emulsion composition may contain excipients such as emulsifying agent, anti-foaming agent, thixotropizing agent, pH adjusting, pH stabilizing, dispersant, viscosity adjusting and protecting colloid, auxiliary agent, freeze-thinner, freeze-thinner, freeze-dried, freeze-dried, application. Suitable emulsifiers for the saspo emulsions of the invention include, for example, a modified ethoxylated fatty acid (e.g., marketed as Emulsion AG 1SC) or an ethoxylated fatty acid (e.g., Alkamuls VO / 20O3), antifoam such as aqueous silicone emulsion (e.g., Emuidon ED), e. g., Attagel 50), as a pH adjuster, e. g., nitric acid monohydrate, e. g., as a pH stabilizer, e. Violet chalk) as a dispersant by example! ethoxylated trisirenedphenol salts (e.g. Soprophor EL), polyaryl phosphate and Aeram salt (abbreviated PÖE, e.g. Bmulson AG TEST), condensed alkylnaphthalene synphenate (e.g. Madeol MW or Supragd MNS / 00), lignin sulfonate (e.g. AM 320) or polycarboxylate (e.g. Geropon T / 36}, viscosity adjusting and protecting colloids such as xanthan gum (e.g. Kelelt AP), bactericides such as sodium benzoate, antifreeze agents such as oleopmpdene glycol, an antiseptic such as silicic acid additive (S), Suitable solvents for the active compound include, for example, transdermal esters of vegetable oils, such as rapeseed oil ester or oaphor boron methyl ester, for example, 1-methoxypropanol and the like.

The composition of the invention may also be in the form of an emulsion-forming formulation such as the wash oil compositions shown in the examples. They generally contain a bulking agent, including drying oil, modified-ethoxylated fatty acid and leciline emulsifiers, and a film adjuster. The plant protection agent of the present invention is generally used as an emollient in emulsion form. 50 to 00% by weight of a styling oil, 0 to 2% by weight of a shim adjusting oil, 7 to 7% by weight of lecime and S-18 by weight of a modifiable ethoxylsil fatty acid emulsifier.

I hate it. ready.kliíhl ilii

Preparation of an emulsion-forming premix

There is a need for an emulsion pretension that is harmoniously matched to the other components of the synspoemulsifier. This premix is prepared by dissolving the behin in a vegetable oil in a heated and cooled daplClean dish with continuous stirring.

aüáteazwk,: then. The prenux is then cooled and placed in a temporary storage container. This premix can also be used in tin itself as an emulsifying composition such as a wash oil composition.

Preparation of solsemulsion

An aqueous solution of xanthan gum containing sodium benzoate is prepared. Swelling or dissolving it is a time consuming process.

In parallel, heated and cooled with a stirrer, dissolve the dispersants in a mixture of propylene glycol and water in a duplicator, and add salt-type compounds and sodium benzoate. Then add some of the canthan gum solution and mix thoroughly. The active ingredients are added portionwise and suspended by vigorous stirring.

Mineral additives and antifoam agent, as well as an espresso mash, are added to the powder, and finally, with vigorous stirring, the oil-based emulsion-forming premix is gradually added and the mixture is passed through a disaggregator.

Grinding operations

The pre-milling is carried out in milled disc mills in two stages. The suspoemulsion is passed through mills for continuous operation of the m-type at a prescribed rate using monopumps. The mills are equipped with a water-cooled jacket. The material has a grain size of less than about 50-70 µm after the ejaculation.

The milling of the Imin is performed by one or more passages in a water-cooled bead mill, wherein the five bodies are: 1-3 mm glass: or ceramic beads held in motion by a strong and fast mixer of the mill in the suspoemulsion in the grinding space. The impact of the grinding flushes and the abrasion effect they produce reduce the solid phase to particles of an average size of 2-4 µm. After grinding, the suspoemulsion is transferred to a container where additional xylene rubber solution is added with vigorous stirring to adjust the viscosity of the product. Then, an antifoam agent is added and a small amount of water is added to adjust the exact foam material reservoir.

The product thus obtained is packaged after sampling and testing.

DRAWINGS INTRODUCTION AND EDUCATION

Figure 1 shows an electron microscopic image of a BVH-1 sprayed alfalfa spray, a primerized permefesepp formulation with thousands of fixed active ingredients in a 50x magnification.

THE 2. Fig. 4A is an electron microscopic image of BVN-1 composition on aluminum foil at 1000x magnification.

THE 3:. Figure 3A shows the previous sample taken at 3000x magnification.

Figure 4 shows the uptake of BVM-2 formulation sprayed on the supernatant at 3000x magnification.

Figure 5 shows the uptake of BVN-2 formulation by leaf spraying, freeze-drying, drying and then. gilt,

Figure 6 shows the uptake of BVM-2 composition on their living leaves. without gilding at 1 000x magnification.

The ~. Fig. 6A shows a highlighted portion of the previous formulation at a magnification of 2,000x

Figure 8 is a view of a portion close to the preceding area at a magnification of 50 x 50.

Figure 9 shows the uptake of BVN-2 formulation on live leaf at 1000x magnification. Figure 10 shows the previous leaf area. a smaller portion of the image is shown at 4,000x magnification,

Fig. 11 shows the edges of a living faecal image: in its original state, without gilding or edging, at a magnification of 500x.

Figure 12 is a photograph of a sprayed and gold plated spray liquid of preparation B VN-1 on a glass plate at a magnification of 35 × 5.

In Figure 13, in another region of the previous glass sheet, droplets of various sizes can be seen at 200x magnification.

Figure 14 is a photograph of a spray blower of BVN-1 in gold plated glass on a 200x magnification.

Figure 15 is a photograph of a penet broth blend of BVN-1 in gold plated glass. At 2500x magnification.

The figure below shows the previous gilded glass plate at 2500x magnification,

The figure Π shows the previous gilded glass plate at 5000x magnification,

Fig. 18 is a view of the spray liquid of formulation B VN-2 sprayed onto a single sheet of glass, gilded at a magnification of 1 000 times.

19. Captures of VN-3 composition bpgs are shown on a glass plate gilded at 35x magnification.

Fig. 20 shows a portion of the area shown in the previous image, magnified 250 times.

Fig. 21 shows the surface at a magnification of 1 000 times,

Figure 22 is a photograph of a spray dropper BVN-4 gilded on a glass plate,

200x magnification®.

Fig. 23 is a view of a wind from a larger droplet of the preceding preparation in 200x magnification,

Fig. 24 is an image of a solitary oil droplet in the area between the spray tip of BVM-4 and 200 magnification,

Figure 25 is a view of Figure 23 at a magnification of 500x.

Figure 26 is a comparative view of a comparative light microscope, with BVM-2 on the right side of the Ia lobe.

The invention is illustrated by the following examples.

EXAMPLES

Sulfur-Copper-Bldroxide SOS Ventilated Elemental Sulfur

Ce (OHB

Emulsin RD (aqueous silicone emulsion}

It has an average of 50 (lyophilisation agent) monohydrate

Emulson AG 18C (Mo-Ethoxylated Fatty Acid) Emulsnu AG TRST (PÖE, PolyBl-Phosphatate Ester from Kelelt AP (Lime Gum) .Miadeol MW (Condensed Alkyl Naphthalene Synphenate) Sunflower Oil

Na-behozol is monopropylene glycol

Pepper 22 1 silica additive)

Leeieo F60Ö 1PM (Plant Lecithin)

WATER

Composition (w / w) 23/1 11.5 0.8

0.5-1.0 0.2-0.4 2.0-3.0 1.5-2.5 0.05-0.15 0) 6-1.5 15.0-23.0 0-8.0 0, 03-0.08 3.0-24) 0.2-0.9 0.3-1.0 ad 100

2 »Example

Sulfur-copper-bridge rxtd snapper

KsmmgM .... .............................................. ............................ "QgSketch Modifying Membranes Elemental Sulfur 15-30

Ce (OH) ₂ 6-15

Emukfon RD (aqueous silicone emulsion) 0.8

Average of 50 (lixotroping agent) 0.5-1.0 citric acid monohydrate 0.2-0.4

Emalson AG 18C (Mediated-Ethoxylated Fatty Acid) 2.0-3.0

Em bottom AG TRST (PC®, Polyaryl Phosphates and Aerants) 1.5-23

From the East AP (Cantanese rubber) 0.05-0, 15

Madeol MW (Condensed Alkyd-Nadalin Synthetic) 0.6-1.5 Sunflower Green 15.0-23.0 Rapeseed Oil 0-8.0

Na-benzoate 0.03-0.08, muopropylene glycol 3.0-7.0

Siperate 22 (silicic acid additive) 0.2-0.0

Leeie's PHOTO IOPM (Plant Phelithine) gives 0.3-1.0 water 100

Example 3

Captan-szuszpoemakió

Component __________......__ Composition (by weight) in chaplain 31.0

KmuKio RD (\ jzes s / sbcon. Emuk e) 0.5-1.0

Geropon T / 3h (Polifearbox 1p) 1.0-3.0

Emnsonson AG 18C (madiflcial-pre-xylated fatty acid) 1.0-3.0

Elmdson AG TRST (POE. Polyaryl Phosphate Ester Andyl Salt) 1.0-4

From east AP (xanthan gum) 0.05-0.15 monopropylene glycol 3.0-9.0

Vfolet Chalk (Calcium Carbonate) 2.0-4.0 Sunflower Oil 5.0-20.0 Rape Oil 0-8.0

Ka-benzoate 0.02-0.1 π

Sipemat 880 (Silica Band Additive) Lecieo F6OC51PM (Herbal Iccitin) Water

1.0-2.5 0.3-3.0 ad 100

captan 18-40

Emulsion R1) (aqueous silicone emulsion) 0.5-1.0

Gerepors T / 36 (polycarboxylate) 1.0-3.0

Emuksen AG 18C (Modal-Covalent Fatty Acid) 1.0-3.0

Emulson AG IRR (POE, Polyaryl-Stilate Ester Amine Salt) 1.0-4

From the east AP (xanthan gum) 0.05-0.15 mmnopropylene glycol 3.0-9.0

Violes Chalk (Calcium Karosha) 2.0-4.0 for Sunflower A 5.0-20.0 Rape Oil 0-8.0

Na-phenol M 0.02-0.1

Siperoat 880 (silica additive) 1.0-2.5

Fecal F6O01PM (plant lecithin) gives 0.3-3.0 water 100

Component __________________________________________________ Composition (iörnea%)

CulOHb 13.0-30.0

Emulsion RD (aqueous silicone emulsion) 0.3-1.2

Dosage 50 (mineral additive) 0.5-2.0 bar s & v-roonohydate 0-1.4

Emisben AG 18C (mode) non-ethoxylated fatty acid) 1.5-4.0

EMUBON SECTOR TUST (PÖTE, Pellar Arctic Acid Ester Salt) 1.5-3.0

From the east AP (xanthan gum) 0.02-0.1

Madeel MW (Condensed Alkyl Fat Sultans} 0.5-2, (1 Menepropylene Glycol 3.0-9.0

Imola oil 12.0-21.0 rapeseed oil

Na benzoate 0.02-0.1

Lecseo F600 (PM (plant lecithin) 0.3-2.0)

Whiskey 22 (knuric acid additive) 0.3-1.3 water gives 100 d, Example

CulOHfe 24.0

Emulsion RD (aqueous silicone emulsion) 0.8

Additive 50 (mineral additive) 1.5 citric acid monohydrate 0.8

Emukon AG Í8C (mode fox, ethoxide fatty acid) 2.9

Emuison AG TRS'f (Substitute, PolyAR Arphosphate Ester Amis) 2.0

Celtic AP (lame rubber) 0.04

Madeol TT (condensed ascium sulphate sulphate) 0, S monopropylene glycol 6.0 sunflower oil 20.4

Na benzoal 0.04

Sipemat 22 (silica additive) 0.8

Leetco F600 (PM (Vegetable Lecithin) 0.72 Water Ad 100 Composition% Volume)

Copper Mdrosddsznszpoemukiá

Component ______________________________________________________ Composition (% by weight)

CoiOH 15-35

Emulsion RD (aqueous silicone emulsion) 0.5-1.2

Average of 50 (mineral additive) 0.5-1.8 ci of mono-Fe from 0.3 to 1.2

Bmuten AG 186 (modified, ethoxylated fatty acid) 2.0-5.0

Emuteü AG TRST (EGE, Polar! -Lastat-Ester-Amino) 1,3-3,0

About Kulir AP (hantan gum) 0, 02-02

Madeol MW (condensed cyclic naphthalene suthenate) 0.5-1.5 monopropylene glycol 3.0-9.0 sunflower oil 15.0-28.0 rapeseed oil 0-8.0

Na benzoate (1.02-02

Sipemate 22 (silica additive) 0.5-1.5

Leeico F600 1PM (Herbal Teas) 02-1.5 Water Gives 100 a Example

Sturgeon Thiophanate ~ nwtíMéb »Conazole Syndrome (8 ¥ $ -2 preparation)

KpÓpnemL · - ............................................... ... OSS ^ étel.ífomeg%)

Soprophor Fi (etovylated tristnyl phenol phosphate) 2.0

1,2-propylene carbon 4.6

Snpragd MNS 90 (Condensed Alkynaphthalene Synphonate) 1.5

Dorresperse AM 320 (bgnins2nlphenylammonium salt) 0.7 sodium benzoate 0.04

From the East AP (xanthan gum) 02 2

99.9% swallows elemental sulfur 36)) 4

97% tofophanate-methyl 162.9

97 '% tebuconazole 3.10

Sipcnnu 22 (silica additive) 0.30 sunflower oil 17

Alkamuls VO / 2003 (Ethoxylated Fatty Acid) 2.4

Lecieo F600 ΪΡΜ (sqyateline) 0.6

Geronoi FF4 (blends) 0.8

Emulsion KD (aqueous silicone emulsion) gives 0.8 deionized water 100

Sulfur Thiophanate Methyl Tehukenazole Suspension (BVN-3 Formulation) .A. The composition of Example 8 without sunflower oil.

10, Example

Component ................................................. ........ ,,. összeléfoj. ífomegőfo

Ca (OHh 13.0-30.0 tebuconazole 1.0-8.0)

Emuision R1 (aqueous silicone emulsion) 0.4-1.5

Ernuison AG 18 € (modSkali, ethoxylated fatty acid) 1.0-3.5

Emulson AG TRST (PGE, Polyaryl Phosphoester Ester Amine Salt) 1.0-4.0

From the east AP (xanthan gum) 0.02-0.1 monopropylene glycol 3.0-10.0

Borresperse AM 320 (lignite sultonate ammonium salt), 0-4.0

Na-benzoate 0.02-0.0, 1 cl tromic acid monohydrate 0.3-1.2

Versalred Fö RT (labeling liquid) 0.8-4.0

I Ceole F600IPM (lithium) 0.3-1.5

Sipernat 22 l Co-Acid Additive) 0.2-1.0 Sunflower Oil 10.0-30.0 Rapeseed Oil 0-8.0 Water Add 100

Remover wfo sens sunflower oil

Emulson AG 18C tin-dibasic-ethoxylated fatty acid) Lecieo FóOO ÍPM (vegetable Ileitin)

85.0

12.0

3.0

Example 12

KOOEM-;

sunflower oil 50-00 rapeseed oil

Emukon AG 18C (Mode Fatty Acid Oxylated Fatty Acid) Leeilee Chief) IPM (Plant Ileitin)

0-20

1-7

Example 13

Wash

ÖsszeiéteLítömepdö)

Component sunflower oil rapeseed oil

Emuidon Aö I 8C fjnodikhka (fatty acid)

Surface structures were studied using a seamung electroscope microscope. This instrument allows the application of the spraying agents on the leaf surface to be monitored, ie it is possible to detect the presence of an active ingredient (e.g. captan, copper (Π) - hydroxide, etc.) and to examine the quality of the film that fixes them. and other attributes. Thus, the observations can be used to design coating properties as desired.

Electron microscopy was performed on the formulations of Example 6 (ÖVN-1}, Example 8 (BVH-2), Example 9 (BVN-3), and Example 11 (BVN-4). The images were taken in seanning mode, usually with an accelerating voltage of 25 kV.

In Figure I the BV'N-1 composition (a copper hydroxide active substance in oil) sprayed onto aluminum foil, it is clogged detected polymerize old electron pennetcsepnjének inclusion in the supervisor's eyes located therein thousands of frozen drug N5 ~ _fold: magnification.

Fig. 2 is an electron microscopic image of BVN-1 formulation on a 10x magnification on aluminum foil. The layer is thicker at the edge of the esepp and therefore more visible. At this magnification, you can clearly see the solidified oil film bursting in vacuum, letting go of the few volatile constituents, with curved, round holes typical of flexible materials, nowhere near the rails.

Λ? Figures 1 to 4 of the previous sample are fcheteie latlvho ulod-c / eres large fasbun, where the solid active substance particles passing through the layer can be observed, and the round holes mentioned above are very visible.

Figure 4 shows the uptake of BVN-2 preparation (an oily composition with three active ingredients) permeated with aluminum foil at 3x (M). The solidified oil layer (not gold-plated) shows grains transparent with a slightly diffuse boundary as far as the electro beam penetrated the extremely fine layer and where deeper, with a faint but sharp edge, the solidified oil layer holes can be seen. These holes are prominently located above the granules and have a distinctly round shape.

Fig. 5 shows a BYN-2 formulation sprayed on a white leaf, frozen in vacuo, dried and then gilded. This pattern is completely impermeable to the epiece beam due to gold, but the surfaces appear sharp and centrifugal on the image. The freeze-dried dehydrated ductile shrinkage of the fibrous, erect plant surface is characterized by lamellar surfaces descending in layers. In this shot at 5X magnification, the grain of the drug appears to be quite small.

Figure 6 shows the uptake of BW-2 composition on my living leaf surface without gilding at 5x magnification. The image also shows the cells that make up the plant boron globe and a vent hole, as well as the dried spray in the intercellular wells with grains of the active ingredient. In this shot: oiajfihn is barely visible: (not gilded), but nature is closer to the surface.

Figure 7 shows a highlight portion of the previous image at 2X5X magnification.

Figure 8 shows a portion close to the area shown in the previous figure, magnified by SÖOÖ times. This shot of live gold plating without gilding already shows film-like structures around the particles.

Figure 9 shows the uptake of the BYN-2 formulation on a live leaf at 100x magnification. This image shows a portion of a larger drop of mistletoe between the cells of the leaf of the plant and the necroerei. hi the layer is thick and you can see where it has cracked when the leaf is folded but at the same time the active substance particle bonding plaque of the film forming material is clearly visible.

In the figure Ifi, a smaller portion of its previous foliage is shown in magnification 4x0x. Although the preparation contains live gilded leaves without gilding, it still shows a thin film of tiny holes> s at the intersection of the plant * and the haloany ags / emcs.

Figure 11 shows the edges of a live blade of grass in its original state, without gilding and edging, at Söd's close-up,

In FIG. B VN-I formulation shows a shot of glass sprayed and gilded permeate at 35x magnification. The image shows that the active ingredient particles are evenly distributed in the droplets. It can also be seen that the droplets are about a micron or less in size. as a result of surface superficiality, they are already age-shaped,

FIG. in another region of the previous glass sheet, droplets of various sizes can be seen at 20P / 0 magnification. b * en the image inside the various meietu drops π

The active ingredient beads would be visible from the outside and it would also appear that the droplets were thicker and the smaller droplets were circular. An important novelty to the above, where the number of droplets drops rapidly decreases, and in exchange of sufficient tiny droplets there is only one grain of grain or a single drop of olive oil in the spray molten. This recording really shows. These tiny droplets are the result of small droplets, even nhkroesegp, which are also adhered to the surface as a result of high velocity collisions. This is also true for the fish side in Figure 22 and Figure 26 (Projectma microscope image).

In Figure 14, the permefeeps of BVN-Ϊ formulation were plated on a glass plate with gold plating. At 2000x magnification, A smaller image, approx. A spray drop of 50 pm is visible. which contains a large number of countable truffles. At the edge of this drop, the thickening is clearly visible and there is a solitary, dried oil drop on the outside of the drop.

Figure 15 is a photograph of a spray drop of SVN-1 formulation on a glass plate, gold plated, at a magnification of 2500 times. It is made of a larger drop with a more prominent coating on the rim. Here you can clearly see the fim that connects the rubbish.

Figure 16 illustrates the previous gilded glass sheet at a magnification of 2500. here, too, the Ilim connecting the grains is on foot, and tiny holes can be seen in several places in my grass. In addition, the image also shows a solitary, dry oil droplet of about 10nm in size.

A. 1: 7 shows the previous gilded glass plate at a magnification of 500x. Here, at the edge of the drop, the active / particulate plaque-like polymer is clearly visible. The characteristic refinements of fim are perhaps most noticeable.

Fig. 18 is a view of the spray pattern of a BVN-2 formulation sprayed onto a glass plate, gold plated, firing at a magnification of 10 times. The image shows a polymer film of the active grain particles within the drop, as well as several solitary oil droplets on other parts of the glass plate.

Figure 19 shows droplets of BVN-3 preparation (oil-free, triple active spray) on glass plate, gold plated at 35x magnification (composition BVN Pesticide O recipe). The image shows that the active ingredient particles are evenly distributed over the petal droplets. Here too, it is noticeable that the smaller droplets are circular,

Figure 20 shows a portion of the area of the previous shot at a magnification of 250x, less grains in the droplets and some grains of the active ingredient. But there is no trace of oil mills.

In Figure 21, the same surface is shown in 10x magnification. Since the agent used does not contain a Slm-forming agent, only water-soluble decorative dispersants which do not evaporate in vacuo are significantly enriched at the droplet edge, A. dispersants form a brittle layer and shrink on the rigid surface of the glass to form a characteristic cracking die. This phenomenon is most noticeable in the big cases,

Figure 22 is a photograph of a dried, polarized peone oil blend of BVN-4 (an emulsion-containing oily composition) on a glass plate gilded at 200X magnification. On the gilded glass plate it is possible to examine the oil additive layer by itself. In the middle of the image there is a large droplet of spray and small oil droplets around it. Given that it is an active ingredient-free preparation, the oil droplet ratio is about 5 times that of the other samples. so there are several separate oil drops.

Figure 23 shows the wind force of the larger spray blush of the preceding preparation at a magnification of 2 × 5. Outside the spray blade, the individual oil drops are clearly visible, the semi-jelly oil blots within the large spray drop cover the surface but their meeting edges are still visible. This is the first phase of the polymerizer.

Figure 24 shows a 20d magnification of solitary oil smudges in the area between the spray blisters of the RVN-4 formulation. Inside the big drops, you can't see the details, because the current contrast and illumination were tuned to the tiny: eseppes. Here, too, we gilded a solid sample, completely in a polydimated state,

25 is a view showing FIG. Figure 5A shows a magnification of SO0. This image shows a multitude of droplets. The droplets freshly sprayed on the glass plate were initially liquid, then lost their water content and dipped / dipped but retained their shape. So, these droplets are already dripping from polymeric macromolecules and are sedentary, so they would not evaporate under vacuum. like small molecules and their surface is gold-plated. The smoothness of the glass surface allows these tiny: protrusions to be seen, and the Seanning Effect Microscope: This gilded surface is excellent for palpation of the lungs, although in this case rgv is poor in coutras.

2o. Fig. 4A is a comparative image taken with a conventional light microscope (Projeciina). To the left of the comparison image is a conventional Sulfur on the slide

Wö's dried spray broth is noticeable, with visibly coarse bristles, where the bulk of the drop has a thick, wide rim. In the right box, the. 8th

(BYH-2, an oily formulation of myo-active ingredient) is dried. In this connection, it is understood that a variety of products employ various adjuvant enhancers. Here it is apparently unnecessary. <It is clear from the image that the spray juice of the sample is still in a dropsy condition without any special adjuvant.

Somo

Claims (7)

A polymerizing film-forming vehicle for pesticides comprising a drying or semi-drying vegetable oil, optionally lecithin and a non-or slightly drying vegetable oil as a film-forming oil. 2 <_; The carrier of claim 1, wherein the drying or semi-drying vegetable oil is selected from the group consisting of sunflower oil, soybean oil, fennel oil, poppy seed oil, walnut oil, cottonseed oil, linseed oil, linseed oil, grape seed oil, sesame oil, wood oil and mixtures thereof. poorly dehydrating vegetable oil is selected from the group consisting of rapeseed oil, palm oil, olive oil, linseed oil and mixtures thereof, 3-5. The pesticide of any one of claims 1 to 6 is sprayed onto the field of application, and the vegetable oils present in the vehicle are allowed to pumperize for a few hours to a day after exposure to ambient oxygen to form a polymerized pesticide film. 3. A plant protection product which is a pesticide according to one of claims 1-2. A carrier according to any one of claims 1 to 3, optionally one or more active ingredients and additives customarily used in the manufacture of a plant protection product. A plant protection product according to claim 3, comprising one or more active ingredients selected from the group consisting of: elemental sulfur, copper-h idro siti, copper oxychloride, copper-ovid. homemade copper sulfate, captan, leboconazole, thiolanate methyl. The plant protection agent according to claim 3, which is a spray, pasteil synsemulsion, dressing or lotion composition. She. A process for forming a polymerized pesticide film, comprising: a 7. Á. She. The method according to claim 1, wherein the field of application is a plant or its root, stem or leaf, or seed or soil, or other growing medium.