RU2248734C1 - Method of generating gas fumigant (options), composition for generating gas fumigant (options), and fumigation processes (options) - Google Patents

Abstract

FIELD: food industry.

SUBSTANCE: invention aims at eradicating vermin in foods, packings, vehicles, and processing and storage areas as well as at controlling field vermin. Method comprises generation of phosphine-based gas fumigant using composition containing metal phosphide and substance inhibiting reaction of metal phosphide with ambient air moisture and contact of composition with ambient air moisture accompanied with dispersion of composition and interaction of droplets of composition with ambient air moisture to release phosphine. Alternatively, method involves contacting (i) composition constituted by adsorbed phosphine-containing substance and substance inhibiting release of adsorbed phosphine with (ii) ambient air moisture accompanied with dispersion of composition and interaction of droplets of dispersed composition with ambient air moisture to reduce phosphine vapor tension on the surface of droplets of composition resulting in release of gaseous phosphine. Another option comprises contacting composition constituted by substance containing absorbed phosphine with ambient air moisture accompanied with dispersion of composition and interaction of droplets of dispersed composition with ambient air moisture to reduce phosphine vapor tension on the surface of droplets of composition resulting in release of gaseous phosphine. In phosphine-based gas fumigant generation composition, metal phosphide and phosphine release inhibiting substance are used in states allowing composition to be dispersed. In the other option, substance containing phosphine in adsorbed state and phosphine release inhibiting substance are used are used in proportions allowing composition to be dispersed. In yet another option, composition is constituted by substance containing absorbed phosphine. Fumigation process envisages use of apparatus providing generation of gas fumigant by way of depressurization of composition-containing vessel, feeding composition into dispersing device of apparatus to be dispersed in contact with ambient air, and precipitating particles of dispersed composition on the surface of fumigation object, after which each precipitated particle of composition release gaseous phosphine with maximum of its concentration field near the surface of fumigation object. Alternatively, maximum of phosphine concentration field is created within internal space of the object and simultaneously this space is filled with dispersed composition capable of adsorbing and/or absorbing phosphine gas from the space. Phosphine-loaded composition particles are precipitated on the surface of fumigation object to provided maximum concentration of phosphine near this surface.

EFFECT: enhanced fumigation efficiency in poorly sealed rooms.

10 cl, 9 ex

Description

The invention is intended for the destruction of pests in food products, mainly in grain, tobacco, quarantine objects, containers, vehicles and premises intended for their processing, storage or long-term transportation, as well as for the destruction of field pests.

The destruction of field pests, as well as food pests during storage and long-term transportation, remains a serious problem. When solving it, the main attention is paid to the following main points: the complexity of fumigation work, including waste collection and disposal, fire and explosion safety of fumigation, environmental safety (harmlessness of fumigation products and waste from its use).

One of the most important factors is the effectiveness of fumigation work, depending on the method of their implementation and the fumigation agent used.

From known means for fumigation:

• chloropicrin;

• metal chloride;

• methyl bromide;

• drugs that produce phosphine,

of greatest interest to consumers is the fumigant gas containing phosphine.

At present, many methods and devices for producing phosphine-based fumigant gas are known. One known device for producing phosphine-based fumigant gas is a device in which a fumigant gas is generated by forcing a humidified diluent gas through a layer of metal phosphide. In this case, the moisture of the diluent gas interacts with the metal phosphide and a gas is produced - phosphine.

The disadvantages of such solutions are their complexity and high energy consumption, due to the need to pump through the device gas, specially prepared in advance (humidification, heating).

In addition, an important problem is the creation and maintenance of the fumigation facility, whether it is an elevator, a warehouse, a grain processing enterprise, or an open area inhabited by field pests, of the concentration field of the fumigant gas for a time sufficient to accumulate an effective dose of the toxic effect of the gas fumigant on insect pests anywhere in the fumigation facility.

It should be noted that it is especially difficult to maintain the existence of an effective concentration field of the fumigant gas in empty rooms that are difficult to seal (warehouses, grain processing enterprises, silo and silo rooms of elevators, working towers of elevators, etc.), since the fumigant gas filling internal volumes of these rooms, quickly blown out through the "leakage" of the premises, as well as in open spaces.

Closest to the claimed methods of generating a fumigant gas, device and composition for its implementation and methods of fumigation are solutions that implement the application of Germany No. 3047373, MKUCOI D 25/06 - 1982; prospectus form Degesch GMBH, Bundesrepublir, Deutschland, 1985.

They describe tablet preparations based on metal phosphides, which, when in contact with ambient air, produce gas phosphine and gases, diluents, carbon dioxide and ammonia.

The method provides the production of a fumigant gas in the form of a mixture of phosphine with carbon dioxide and ammonia and involves the use of metal phosphide, ammonium carbate, a binder and moisture as starting reagents. In this case, the metal phosphide, binder and ammonium carbate are pre-mixed, structured in the form of geometric shapes (tablets, balls, etc.) and the resulting structured composition is contacted with ambient air. The ambient air moisture interacts with the structured composition and, as a result of the chemical interaction of moisture with the metal phosphide, phosphine gas is produced, and with ammonium carbate, carbon dioxide and ammonia are produced.

A device for generating a fumigant gas is an airtight shell - a bottle having an overlapping opening (bottle neck with a twisting stopper).

A composition for generating a phosphine-based fumigant gas (as a mixture of phosphine gas, carbon dioxide and ammonia) includes mixed metal phosphide, ammonium carbate and a binder.

The fumigation method involves the inclusion of a device for generating a fumigant gas by contacting the structured composition with ambient air, manually distributing the individual structural units of the composition, for example tablets, as uniformly as possible over the fumigated object, the interaction of tablets with ambient air moisture to produce phosphine and gases - diluents and filling the entire volume of the fumigated object with phosphine gas.

The disadvantages of such technical solutions to the problem of fumigation are:

- the need to fill the fumigant gas evenly over the entire volume of the fumigation object, although pests insects live on the internal surfaces of the fumigation object, so the fumigant gas located in volumes remote from the walls of the fumigation object is used inefficiently;

- the presence of a uniform concentration of phosphine gas in the entire fumigation object leads to its large losses during air exchange through leaks in the fumigation object with the air surrounding the space of the fumigation object;

- the great complexity and duration of fumigation associated with the manual distribution of tablets according to the volume of fumigation and manual assembly of the decomposition products of the tablets after their decomposition, in the process of fumigation;

- a large amount of structured elements of the composition do not allow them to evenly cover all the internal surfaces of the fumigation object;

- a large amount of structured elements of the composition (for example, tablets) leads to the fact that the central part of the tablet does not decompose due to the fact that it is shielded by the decomposition products of its peripheral layers, as well as to the possibility of creating a phosphine gas concentration in the air higher than the one at which spontaneous combustion of a mixture of air with phosphine (26 g / m ³ ) occurs, which forced the authors of the composition to introduce into its composition a substance that, like metal phosphide, interacts with air moisture, but does not produce phosphine, but gases - phosphine diluents (carbon dioxide and ammonia), this is ammonium carbate.

In order to eliminate the mentioned disadvantages it is proposed:

- exclude the structuring of the composition, and make it in

the composition that allows you to disperse it;

- introduce into the composition of the device for generating fumigant gas a unit for dispersing the composition;

- to exclude from the composition of the composition a substance that is designed to produce diluent gases (carbon dioxide, ammonia), this is ammonium carbate;

- to introduce into the composition of the substance a substance that slows down the interaction of metal phosphide with ambient air moisture;

- to allow the use in the composition of the composition instead of metal phosphide, which produces phosphine gas when it is in contact with ambient air due to its chemical interaction with air water vapor, substances that retain phosphine due to physical forces in the sorbed state, which release phosphine gas when contacting them with ambient air by reducing the vapor pressure of phosphine at its surface.

The exception is the structuring of the composition, the manufacture of the composition in the form of a system that allows its transformation into a state with a large surface, i.e. dispersion, as well as the introduction of the device for generating gas fumigant node to disperse the composition can eliminate the following disadvantages:

- eliminates the need to fill with fumigant gas uniformly the entire volume of the fumigation object, since it becomes possible to cover the entire inner surface of the fumigation object with a thin layer of a composition that produces phosphine gas, which, in turn, allows you to create an effective concentration of phosphine gas near all the inner surfaces of the fumigation and insects live, and not entirely in the whole object of fumigation;

- eliminate the time-consuming operations of manual distribution of the structured composition (tablets) over the fumigation object, because aerosol particles of the composition themselves diffuse and evenly settle on all the internal surfaces of the fumigation object, or replace the time-consuming operations of manual distribution of tablets with simpler operations of applying thin films of the composition to the internal surfaces of the fumigation object using sprayers;

- reduce the consumption of phosphine gas, increase its efficiency and reduce gas losses during fumigation in conditions when air exchange occurs through leaks of the fumigation object, because effective concentration is created only near the inner surfaces of the fumigation object, and not in its entirety;

- eliminate the possibility of the formation of undecomposed residues of metal phosphides due to the shielding effect of decomposition products, because in thin layers or particles of a small size, decomposition products cannot be formed in quantities sufficient for the screening effect;

- expand the scope of fumigation with phosphine gas, extending it not only to fumigation objects that are difficult to seal, but also to open spaces, i.e. to destroy field pests, such as locusts, Colorado potato beetles, etc., since a droplet of the composition falling on the body of a locust or other insect will create and maintain an effective concentration near the body of the insect, where its respiratory organs are located, regardless, there is an insect inside a certain volume or in open space, which was previously impossible due to the high volatility of phosphine gas, as well as grain in the stream, which loads ships, cars, cars, and other vehicles, as well as e warehouses, silos of elevators and other storage tanks.

The exclusion from the composition of the composition of a substance that emits diluent gases (ammonium carbamate) when interacting with air moisture, and the introduction of a substance that slows the release of phosphine gas from the composition, along with the exception of structuring the composition, ensures that the phosphine gas is diluted with ambient air to such an extent that eliminates the creation of phosphine gas concentration exceeding the auto-ignition limit (26 g / m ³⁾ in the thickness of the air layer, wherein the oxidation chain reaction of phosphors may occur air oxygen at its actual moisture, which leads to cheaper formulation and reduction of the composition, which must be distributed to the fumigating object.

The option of replacing the metal phosphide composition with a substance that holds the phosphine gas in a physically bound state (adsorbed, absorbed) allows us to exclude a strong dependence of the composition's performance on environmental humidity.

The introduction of a substance that slows down the production of phosphine gas into the composition and the dispersion of the composition during its contact with ambient air allows the grain to be treated in a stream with a dispersed composition when it is loaded into the holds of vessels, which allows combining fumigation with the loading process, eliminating laborious placement operations tablet forms of a structured composition in the thickness of the grain, exclude facts when the tablets do not have time to decompose during the passage of the vessel to the destination I.

The technical result of the invention is to ensure the efficiency of fumigation of empty rooms with poor sealing, reducing the consumption of phosphine gas, eliminating the dependence on ambient air humidity, simplifying the implementation of fumigation, including shipboard, increasing its environmental friendliness, making it cheaper, and expanding the scope of fumigation phosphine gas in open spaces, including for the destruction of field pests.

The specified technical result is achieved as follows.

In a method for producing a phosphine-based fumigant gas, comprising using a composition containing metal phosphide, contacting the composition with ambient air, interacting the composition with ambient air moisture to produce phosphine, a substance slowing the interaction of metal phosphide with air moisture is introduced into the composition according to the invention environment, mix it with the composition and in the process of contacting the composition with ambient air, it is dispersed.

In the method for producing a phosphine-based fumigant gas, the composition containing the phosphine in the adsorbed state and the substance slowing the release of phosphine in the adsorbed state are contacted with the ambient air, in the process of contacting it with the ambient air, the composition is dispersed and phosphine is obtained.

In this case, a substance that inhibits the release of phosphine in an adsorbed state may contain phosphine in an absorbed state.

In a method for producing a phosphine-based fumigant gas, a composition containing phosphine in an absorbed state is contacted with ambient air, in the process of contacting it with ambient air, it is dispersed to produce phosphine.

A composition for producing a phosphine-based fumigant gas comprising metal phosphide according to the invention further comprises a substance that slows down the interaction of metal phosphide with ambient air humidity, and metal phosphide and a substance that slows down the interaction of metal phosphide with ambient air moisture, are taken in ratios allowing to disperse the composition to aerosol particles.

The composition for producing a phosphine-based fumigant gas contains phosphine in an adsorbed state and a substance that slows down the process of releasing phosphine in an adsorbed state, the substance containing phosphine in an adsorbed state and a substance that slows down the production of phosphine are taken in ratios allowing dispersion of the composition .

In this case, a substance that inhibits the release of phosphine in an adsorbed state may contain phosphine in an absorbed state.

Composition for generating a phosphine-based fumigant gas, characterized in that it contains phosphine in an absorbed state with the possibility of dispersing it.

In a method for fumigating a phosphine-based fumigant gas, comprising depressurizing a container with a composition for generating a phosphine-based fumigant, contacting the composition with ambient air, producing a fumigant gas and creating a concentration field of the fumigant gas, according to the invention, the composition is dispersed , fill the fumigation object with the dispersed composition, particles of the dispersed composition are placed on the surfaces of the fumigation object due to the diffusion of the particles of the comp zitsii and / or due to inertial forces, by each placed on the surfaces of the particles of the composition prepared and phosphine gas concentration field-creating fumigant gas with a maximum concentration at the surface of phosphine gas fumigation object.

In the method of fumigating with a phosphine-based fumigant gas, comprising producing a fumigant gas, creating a phosphine gas concentration field in the fumigation object, according to the invention, in the process of creating a phosphine gas concentration field in the fumigation object, a dispersed substance capable of adsorbing and / or absorbing gas is supplied to the object phosphine from the volume, absorb phosphine gas from the volume of particles of the dispersed substance, place particles of the dispersed substance on the surfaces of the fumigation object and create the end Phosphine gas abstraction field with maximum phosphine gas concentration at the surfaces of the fumigation object.

Using such methods of fumigation with a phosphine-based fumigant gas, it is possible to destroy field pests, locusts, etc., by dispersing the composition of the areas containing pests, and also to fumigate grain transported in ships, wagons, and other vehicles and stored grain by processing dispersed composition of the flow of grain, which are loaded with vehicles or grain, loaded into storage in warehouses, elevators and other containers, as well as empty rooms that are difficult to seal.

The invention is as follows.

A unit is introduced into the device for producing a fumigant gas, including an airtight shell with a blocked opening, which disperses it in the process of contacting the composition with ambient air, and connect it to the airtight shell with blocked channels.

A phosphine-based fumigant-gas generating device comprises a sealed container, which is connected to a dispersing unit using an overlapping channel, which disperses the composition to particles of 20 microns or less for the diffusion principle of deposition of particles of the composition on the surface, or to particles larger than 20 microns for inertial mechanism of deposition of particles on the surface.

The operator includes a dispersion unit and opens an overlapping channel connecting the hermetic container with the dispersion unit. The composition through the channel due to the injection effect or due to pressurization enters the dispersion unit, disperses and contacts the ambient air, as a result of which phosphine gas begins to be released.

The method of fumigation using this device is as follows.

The dispersed composition obtained as described in the previous paragraph, if its dispersion degree is 20 μm or less, is poured into the internal volume of the fumigation object, where mainly due to diffusion it precipitates on all surfaces, and each settled particle continues to produce phosphine gas, in As a result, a concentration field of phosphine gas is created inside the fumigation object near the entire inner surface of the fumigation object, where insect pests live.

In the case of dispersing the composition to 20 μm or more, the operator directs the bell of the dispersion unit to the inner surfaces of the fumigation object and sequentially processes the entire inner surface of the fumigation object, coating it with droplets of the composition, mainly by the inertial deposition mechanism, which, when emitting phosphine gas, create a concentration field of the phosphine gas in a thin layer of air near the entire inner surface of the fumigation object.

In the same way, the fumigation method is implemented when processing the flow of grain loaded into the holds of ships, wagons and other vehicles, as well as in warehouses, silos, elevators and other containers.

In the same way, a method of fumigation of the areas of open spaces where insects, locusts and other pests live is implemented.

In addition, for the destruction of pests in the premises, the following variant of the fumigation method can be used.

The internal volume of the fumigation object is filled with phosphine gas and at the same time a dispersed composition capable of adsorbing and / or absorbing phosphine gas from the volume. The dispersed composition absorbs phosphine from the bulk, settles on the surface and creates a concentration field of phosphine gas with a maximum concentration near the surface of the fumigation object.

Examples of carrying out the invention.

Example 1

A metal phosphide powder, for example aluminum, is taken and mixed with a hydrophobic liquid, for example cyclooctane. A suspension is obtained in which the powder content can be from 3 wt.% Of the total weight of the suspension to the maximum value at which the operability of the dispersion device used, the resulting suspension composition (up to 50-70%), is maintained.

Such a composition is stored in sealed packaging. To carry out the fumigation of the object, the hermetic package with the composition is connected to the dispersion device using an overlapping channel. The operator turns on the dispersion unit and opens an overlapping channel connecting the sealed container with the dispersion device, the composition, due to the injection effect or due to pressurization, enters the dispersion unit where it is dispersed, and the resulting aerosol particles are poured into the fumigation object. The fumigation object is filled with aerosol, in which the dispersion phase is particles of aluminum phosphide, impregnated and surrounded by a layer of hydrophobic liquid - cyclooctane, which slows down the mass transfer of water molecules in the air to the surface of the metal phosphide and also slows down the mass transfer of phosphine molecules formed as a result of a chemical reaction metal phosphide with water molecules penetrating the surface of the metal phosphide. Thus, a diffusion barrier is created around each particle, and the process of phosphine release is slowed down.

Aerosol particles, settling evenly on the surface of the fumigation object, continue to slowly release phosphine gas, and therefore at the surfaces, namely insects, the maximum concentration of phosphine gas is created and maintained, which destroys insect pests.

Example 2

A powder of a metal phosphide, for example magnesium, is taken, it is mixed with a hydrophobic liquid, for example, cyclooctane, previously saturated with phosphine gas, by, for example, bubbling phosphine gas through it, i.e. the metal phosphide powder is mixed with a hydrophobic liquid containing phosphine in an absorbed state. In this case, each aerosol particle obtained from such a composition will be able to release more phosphine gas than the aerosol particle of Example 1 by the amount of phosphine absorption capacity of cyclooctane, which impregnates and envelops the aerosol particle.

Example 3

A metal phosphide powder, for example zinc, is taken and a layer of solid polymer material is applied to the surface of each particle, for example, it is wetted with a solution of alkyd resin in a volatile solvent, for example, a solvent, and dried. A polymer film covering each particle of metal phosphide plays the role of a diffusion barrier that slows down the release of phosphine.

Dispersion is carried out as in example 1.

Example 4

A powder is taken from a material capable of retaining phosphine gas in an adsorbed state, for example porous coal, and saturated with phosphine gas, for example, passing phosphine gas through a layer of porous coal. In this case, the slowing down of the phosphine gas evolution process is due to the increased retention capacity of the pores of the sorbent.

Example 5

A powder is taken from a material capable of holding phosphine gas in an adsorbed state, for example, porous modified silica gel, saturate it with phosphine gas, by passing phosphine gas through a layer of porous modified silica gel, mix it with a hydrophobic liquid, for example cyclooctane, in the ratio as described in example 1 .

Example 6

A liquid capable of absorbing phosphine gas, for example cyclooctane, is taken and saturated with phosphine gas, for example, sparging phosphine gas through a liquid, a liquid containing phosphine gas in an absorbed state is obtained.

Example 7

A powder is taken from a material capable of holding phosphine gas in an adsorbed state, for example, passing phosphine gas through a layer of porous coal, and mixing it with a hydrophobic liquid, for example cyclononan, previously saturated with phosphine gas, for example, sparging phosphine gas through this liquid in the ratio as indicated in paragraph 1.

Example 8

Magnesium phosphide powder is taken and mixed with a hydrophobic liquid - cyclononan in such proportions that the whole powder is impregnated and wetted, but remains in a loose state.

Example 9

A powder is taken from a material capable of retaining phosphine gas in an adsorbed state, for example, porous coal, and mixed with a hydrophobic liquid, for example cyclooctane, in such proportions that the whole powder is impregnated and wetted, but remains in a loose state.

The invention provides the efficiency of fumigation of empty rooms with poor sealing, reducing the consumption of phosphine gas, eliminating the dependence on ambient air humidity, simplifying the implementation of fumigation, including shipboard, increasing its environmental friendliness, reducing the cost of its implementation, as well as expanding the scope of fumigation with phosphine gas fumigation of open spaces, including for the destruction of field pests.

Claims (10)

1. A method of generating a phosphine-based fumigant gas, comprising using a composition containing metal phosphide, contacting the composition with ambient air, interacting the composition with ambient air moisture to produce phosphine, characterized in that a substance inhibiting the interaction of metal phosphide is introduced into the composition with the moisture of the ambient air, mix it with the composition and disperse it in the process of contacting the composition with the ambient air. 2. A method for generating a phosphine-based fumigant gas, characterized in that the composition containing phosphine in the adsorbed state is contacted and the substance slowing the release of phosphine in the adsorbed state with ambient air, in the process of contacting it with ambient air, the composition is dispersed and get phosphine. 3. The method according to claim 2, characterized in that the substance that inhibits the release of phosphine in the adsorbed state contains phosphine in the absorbed state. 4. A method for generating a phosphine-based fumigant gas, characterized in that the composition containing the phosphine in the absorbed state is contacted with ambient air, in the process of contacting it with ambient air, it is dispersed to produce phosphine. 5. A composition for generating a phosphine-based fumigant gas comprising metal phosphide, characterized in that it further comprises a substance that slows the interaction of metal phosphide with ambient air humidity, the metal phosphide and a substance that slows the interaction of metal phosphide with ambient air moisture, taken in ratios that allow dispersing the composition to aerosol particles. 6. A composition for generating a phosphine-based fumigant gas, characterized in that it contains phosphine in an adsorbed state and a substance that slows down the process of phosphine release in an adsorbed state, the substance containing phosphine in an adsorbed state and a substance that inhibits phosphine release are taken in ratios to disperse the composition. 7. The composition according to claim 6, characterized in that the substance that inhibits the release of phosphine in the adsorbed state contains phosphine in the absorbed state. 8. Composition for generating a phosphine-based fumigant gas, characterized in that it contains phosphine in an absorbed state with the possibility of dispersing it. 9. A method of fumigation with a phosphine-based fumigant gas, comprising depressurizing the container with a composition for generating a phosphine-based fumigant, contacting the composition with ambient air, producing a fumigant gas and creating a concentration field of the fumigant gas, characterized in that in the process by contacting, the composition is dispersed, the object of the fumigation is filled with the dispersed composition, the particles of the dispersed composition are placed on the surfaces of the fumigation object due to the diffusion of the particles of the compo itsii and / or due to inertial force by each disposed on surfaces of the particles of the composition prepared and phosphine gas concentration field-creating fumigant gas with a maximum concentration at the surface of phosphine gas fumigation object. 10. A method of fumigation with a phosphine-based fumigant gas, comprising producing a fumigant gas, creating a phosphine gas concentration field in the fumigation object, characterized in that when the phosphine gas concentration field is created in the fumigation object, a dispersed substance is fed into the object capable of adsorbing and / or absorb phosphine gas from the volume, absorb phosphine gas from the volume with particles of the dispersed substance, place particles of the dispersed substance on the surfaces of the fumigation object and create the end tratsionnoe phosphine gas field with a maximum concentration of phosphine gas fumigation at the surfaces of the object.