RU2105709C1 - Method and device for building gauge pressure in propellant system - Google Patents

Abstract

FIELD: packing; aerosol packages. SUBSTANCE: method comes to desorption of gaseous propellant from sorbent saturated with propellant and introduced into medium including liquid, its saturated vapors and propellant. Prior to saturating the sorbent with propellant, substances featuring sorption heat in sorbent higher than that in propellant are removed from sorbent. When introducing the sorbent into medium, sorbent is isolated from medium components featuring sorption heat in sorbent higher than that in propellant. Device has housing, dispensing valve, liquid, propellant, sorbent saturated with propellant, all placed in housing. Sorbent is placed inside capsule whose case is made for passing the propellant. Capsule is made in the form of diaphragm with holes which diameter exceeds minimum size of propellant size of propellant molecule and is less than minimum size of molecule of liquid component featuring sorption heat in sorbent higher than that in propellant. EFFECT: improved quality of packing. 12 cl, 3 dwg

Description

 The invention relates to packaging equipment and can be used, for example, in aerosol containers used for applying paint and varnish coatings, in medicine, mainly for the prevention and treatment of respiratory diseases and local anesthesia, in the perfume industry, as well as in everyday life for spraying products household chemicals and others.

 A known method of creating excess pressure in the propellant system by desorption of the gaseous propellant from the sorbent, which is saturated with the propellant and introduced into the medium, including liquid, saturated liquid vapor and propellant. (International application PCT / RU92 / 00129, with an international filing date of 06/26/92, a priority date of 06/29/91, and international publication number WO 93/00277 of 01/07/93 B 65 D 83/14).

 A device is known for creating excess pressure in a propellant system, comprising a housing, a dispensing valve installed in an opening on the housing wall, a liquid, a propellant, a sorbent saturated with propellant placed inside the housing. (International application PCT / RU92 / 00129, with an international filing date of 06/26/92, with a priority date of 06/29/91, with international publication number WO 93/00277 of 01/07/93, B 65 D 83/14).

 This method and device allows to provide a high degree of filling with spray liquid.

 At the same time, the medium can have a composition of components that are absorbed by the sorbent, reduce its saturation with the propellant, and the necessary composition of the sprayed liquid changes, which is especially important for compositions with a certain ratio of components, for example, in medicine.

 A known method of creating excess pressure in the propellant system by desorption of the gaseous propellant from the sorbent, which is saturated with the propellant and introduced into the medium, including liquid, saturated liquid vapor and propellant. (U.S. Patent N3964649, NKI 222/399, publ. 22.06.76).

 A device is known for creating excess pressure in a propellant system, comprising a housing, a dispensing valve installed in an opening on the housing wall, a liquid, a propellant, a sorbent, a saturated propellant placed inside the housing, while the sorbent is placed inside the capsule, the housing of which is configured to pass the propellant . (U.S. Patent N3964649, NKI 222/399, publ. 22.06.76).

 In this technical solution, the capsule body is made hydrophobic, eliminating the effects of liquid on the sorbent and passing the propellant through the walls of the body.

 However, the creation of such housings for a multicomponent sprayed liquid may be impractical, and such hydrophobic bodies should be appropriately selected for each composition of the sprayed liquid and the propellant used. Moreover, although such housings make it possible to separate the sorbent from the sprayed liquid, they do not prevent the vapors from penetrating this fluid through the housing and thus do not exclude contact of the vapor with the sorbent, which, when absorbed by the sorbent, reduces its saturation with the propellant, and the necessary composition of the components of the sprayed material is disturbed. liquids.

 The problem solved by the invention, improving the quality of the composition of the sprayed liquid and ensuring the repeated use of the device.

 The technical result that can be obtained by carrying out the invention, the selective exclusion of the penetration of the components of the medium, in addition to the propellant in the sorbent.

 To solve the problem with achieving a technical result in the known method of creating excess pressure in the propellant system by desorption of the gaseous propellant from the sorbent into the medium, which is saturated with the propellant and introduced into the medium, including the liquid, saturated liquid vapor and the propellant, according to the invention, the heat of sorption of the medium components is determined in the sorbent before saturation with the sorbent propellant, substances having a heat of sorption greater than the propellant in the sorbent are removed from the sorbent, and when introduced SRI sorbent in an environment isolated from the components of the sorbent medium having a greater heat of adsorption than the propellant in the sorbent.

An embodiment of the method is possible in which it is advisable to use activated carbon as a sorbent, CO ₂ , Ar, N ₂ , O ₂ , N ₂ O as a gas, water, mineral water, sweet water, juice, whipped cream as a liquid, protein cream, wine, beer, water-alcohol and alcohol solutions, pastes, emulsions and suspensions.

An embodiment of the method is possible, in which it is advisable to use zeolite or silica gel as a sorbent, CO ₂ , Ar, N ₂ , O ₂ , N ₂ O as a gas, anhydrous medical alcohol, confectionery and perfume solutions, pastes, as a liquid, emulsions and suspensions.

A variant of the method is also possible, in which it is advisable to use zeolite and / or activated carbon as a sorbent, CO ₂ , Ar, N ₂ , O ₂ , N ₂ O as a gas, and an anhydrous alcoholic solution as a liquid.

 To solve the problem with achieving a technical result in a known device for creating excess pressure in a propellant system containing a housing, a dispensing valve installed in an opening on the housing wall, a liquid, a propellant, a sorbent saturated with propellant that are placed inside the housing, while the sorbent is placed inside the capsule, the body of which is configured to pass the propellant, according to the invention, the capsule is made in the form of a membrane, the dimensions of the through pores in which are made larger than mini the smallest size of the molecule of the propellant and less than the minimum size of the molecule of the liquid component with a greater heat of sorption than the propellant in the sorbent.

 A possible embodiment of the device, in which it is advisable that the membrane would be made in the form of a layer located on the surface of the sorbent.

 A possible embodiment of the device, in which it is advisable to use pyrolytically deposited carbon as the layer material.

 An embodiment of the device is also possible, in which it is advisable that an insulating layer is applied to the membrane, made with the possibility of its destruction when the capsule is placed inside the housing.

 A possible embodiment of the device in which it is advisable to use sugar or gelatin as the material of the insulating layer.

 A possible embodiment of the device, in which it is advisable that the insulating layer was made of a gas-tight film, and the capsule or housing is equipped with a tearing element installed with the possibility of interaction with the film and its mechanical destruction.

 A possible embodiment of the device, in which it is advisable that the gas-tight film was made of polyethylene or cellophane or metal foil.

 Due to the isolation of the sorbent from medium components having a heat of sorption greater than the propellant in the sorbent by means of a capsule in the form of a membrane, the size of the through pores of which is larger than the minimum size of the propellant molecule and smaller than the minimum size of the molecule of the component of the sprayed liquid with greater heat of sorption than the propellant in the sorbent, it is possible to solve the problem to improve the quality of the composition of the sprayed liquid and to ensure the repeated use of the device, for example aerosol packaging.

 These advantages, as well as features of the present invention will become apparent during a subsequent review of the following best embodiments of the invention with reference to the accompanying drawings.

 In FIG. 1 shows a device for generating overpressure in a propellant system; in FIG. 2 the implementation of the membrane in the form of a layer on the surface of the sorbent; in FIG. 3 is the same as in FIG. 2, the sorbent is made in the form of a tablet with an additional insulating layer.

 The method of creating excess pressure in the propellant system (Fig. 1) consists in desorption of the gaseous propellant from the sorbent 1, which is saturated with the propellant and introduced into the medium, including liquid 2, saturated vapor of the liquid and the propellant. According to the invention, the heat of sorption of the components of the medium (liquid 2, saturated vapor of the liquid and the propellant) is determined, before saturation of the propellants of the sorbent 1, substances having a heat of sorption greater than the propellant in the sorbent 1 are removed from the sorbent 1, and when the sorbent 1 is introduced into the medium, isolate the sorbent 1 from the components of the medium having a greater than the propellant heat of sorption in the sorbent 1.

 Thus, the essence of the method lies in the possibility of high-quality preservation of the composition of a multicomponent medium, at least part of which may have a greater heat of sorption than the propellant in sorbent 1.

Determination of the heat of sorption of the components of the medium is carried out by any known methods, for example, according to literature (reference) data or experimentally, and those components of the medium that have a heat of sorption greater than the propellant are established. Such components of the medium with respect to the sorbent 1 zeolite saturated with the propellant: CO ₂ and / or Ar and / or N ₂ or O ₂ and / or N ₂ O can be water or water vapor having a high sorption heat in zeolite, which specified gases.

Such components of the medium with respect to the activated carbon sorbent 1 saturated with the propellant: CO ₂ and / or N ₂ , and / or Ar, and / or O ₂ , and / or N ₂ O can be: ethylene glycol, methyl, ethyl, propyl, butyl alcohols, benzene and its derivatives, which have a higher sorption heat in activated carbon than these gases.

Such components of the medium with respect to sorbent 1 activated carbon and / or zeolite saturated with a propellant: N ₂ and / or O ₂ can be CO ₂ , which also has a higher heat of sorption in sorbent 1.

 Therefore, so that the components of the medium with a heat of sorption greater than the propellant in the sorbent 1 cannot change their composition, additional measures must be taken.

 To maintain the quality of the composition of a multicomponent medium, it is necessary and sufficient: firstly, to remove substances from the sorbent 1 that have a sorption heat greater than the propellant in the sorbent 1 (due to which the maximum degree of saturation of the sorbent with the propellant is achieved, the uniformity of maintaining excess pressure in the propellant system) ; secondly, when the sorbent 1 is introduced into the medium, it is necessary to isolate the sorbent 1 from the components of the medium that have a heat of sorption greater than the propellant in the sorbent 1 (thereby eliminating the absorption of the components of the medium by the sorbent and preserving the qualitative and quantitative composition of the medium).

As specific examples of the method, you can specify the following examples from the fields of technology (perfumery, medical, food, etc.), where the preservation of the composition of the medium is required. So, for example, when diethyl or dimethyl ethers are used as components of a sprayed liquid, to improve solubility (increase composition uniformity) in an aqueous medium of poorly soluble components, it is necessary to reckon with the possibility of displacement of the propellant by ether molecules from sorbent 1. In the case of access of liquid vapor to sorbent 1, the quality of which is used activated carbon, ether molecules, which, in accordance with the table, have a higher sorption heat than, for example, CO ₂ , used as a opellant will be absorbed by sorbent 1, displacing the propellant from it. Such a mechanism will impoverish the sprayed liquid 2 over the ether and thereby lead to the risk of precipitation, coagulation or crystallization of poorly soluble components, which in turn will lead to a change in the composition of liquid 2. This example is most typical for the perfume industry. In the same way, water vapor will behave if zeolite is used as a sorbent, and alcohol solutions used in pharmaceuticals or the food industry as liquid 2.

Comparative characteristics of the heat of sorption of various substances in the gas phase on activated carbons and zeolites, as well as the diameters of their molecules, presented in the table, are based on several literature sources. (Dubinin M.M. Isirikyan A.A. Heat of adsorption of water vapor on activated carbon. Izv. Akad. SSSR, Ser. Chem. N10, 1989, from 2183-2186; Serpiokova E. N. Industrial adsorption of gases and vapors. M. Higher School, 1969, p. 40; Isirikyan, A.A., Energy of Homogeneous Sorption Systems, Abstracts of Conference 4, Theoretical Issues of Adsorption, M. Nauka 1985, p. 40; F. Stoecli D. Hugnenin, A. Greppi, T. Jakubov et al On the adsorption of CO ₂ by activ carbons. CHIMIA, 47 (1993), N 6, pp. 213-214; Stephen Brunauer. The adsorption of gases and vapors, Princeton, 1945; RC Reid, JM Prausnitz , TK Sherwood. The properties ofgases and liquids. Mc GrawHill. Third edition. NY 1977).

 It is important to note that the creation of hydrophobic shells of the sorbent 1 to preserve the composition of the components of the medium is not required for the above approach, since components having a lower heat of sorption in sorbent 1 will not replace the propellant molecules.

 There are various options for protecting the sorbent 1 from the penetration of medium components having a greater heat of sorption than the propellant, for example, by creating diffusion or molecular shells around the sorbent 1.

 The best option for implementing the proposed method is a device for creating excess pressure in the propellant system (Fig. 1), comprising a housing 3, a dispensing valve 4 installed in the opening of the wall of the housing 3, liquid 2, a propellant, a sorbent 1 saturated with a propellant that are placed inside body 3, while the sorbent 1 is placed inside the capsule 5, the body of which is made with the possibility of transmission of the propellant.

 According to the invention, the capsule 5 is made in the form of a membrane, the dimensions of the through pores 6 in which are made larger than the minimum size of the propellant molecule and smaller than the minimum size of the molecule (see table) of the liquid component 2 with a greater heat of sorption than sorbent in the sorbent 1.

 In FIG. 1 also shows a tube 7 for supplying a spray liquid 2 to a dispensing valve 4.

 In membranes made in this way, it is possible to exclude the penetration of component molecules with a greater heat of sorption than sorbent in sorbent 1.

As can be seen from the table, in the case of using zeolite as sorbent 1 and 2 as a sprayed liquid, compositions containing water, membranes providing passage of the propellant with a diameter of the molecule, are larger than that of water, for example, CO ₂ , Ar, O ₂ and others can pass water molecules to the sorbent 1, the heat of sorption of which in the sorbent is higher than that of the above propellants. Thus, the sorbent 1 will absorb water with the corresponding displacement of the propellant. This will lead to a change in the composition of the sprayed liquid 2, i.e. to the loss of its quality characteristics.

 In most of the considered variants of the combination of sorbent - propellant medium systems, as can be seen from the table, the use of a membrane prevents the use of a membrane whose through pore size is larger than the size of the propellant molecule, but smaller than the components of the medium that have a higher heat of sorption in the sorbent than the propellant. the possibility of absorption by the sorbent 1 of the components of the medium displacing the propellant from the sorbent 1. In particular, when using 1 zeolite as an adsorbent, as an oxygen propellant, and as an liquid 2 of an anhydrous alcohol solution used, for example, in pharmaceuticals, the use of a membrane with the above characteristics isolates the zeolite with oxygen from alcohol vapor having a high heat of sorption zeolite. In the absence of such insulation, alcohol vapors could displace oxygen from the zeolite, which would lead to a sharp increase in pressure in the housing 3 of the aerosol package and the violation of the limits of its safe operation. When the body volume 3 of the aerosol package, unfilled with liquid 2 and equal to 25 ml, the initial pressure of 0.7 MPa and the amount of oxygen propellant adsorbed in zeolite (sorbent 1), equal to 1 g (calculated on the displacement of 200 ml of liquid), the pressure in the package increases caused by the displacement of oxygen by alcohol, will be 2.8 MPa, which will lead to the destruction of the housing 3.

 A membrane with a through pore size of 6 smaller than that of alcohol molecules will prevent the penetration of alcohol into sorbent 1, i.e. will provide a solution to the problem.

Such membranes can be made of porous Victor glasses, polymeric materials (polyethylene, silar, carbosil, polyacrylonitrile and others), including those based on porous substrates and a diffuse coating. In particular, a sharp improvement in selectivity is achieved by introducing liquids into the polymer, in which the solubilities of the separated gases vary significantly. For example, a membrane with a porous dacron matrix 10 microns thick, impregnated with a solution of CsHCO ₃ with the addition of NaAsO ₃ as a catalyst, is known. The matrix is placed between two sheets of silicone rubber, bearing mechanical loads. The separation coefficient for a mixture of, for example, CO ₂ —O ₂ was 2345. (US Patent 4,230,463, B 01 D, publ. 1973).

 In addition to this option, it is possible to make the membrane in the form of a layer 8 located on the surface of the sorbent 1, as shown in FIG. 2.

 Such a layer can be obtained, for example, by the deposition of carbon on the surface (in surface pores) of sorbent 1 during the pyrolysis of methane or benzene, while it is possible to realize a structure exhibiting a molecular sieve effect (selectivity of throughput).

 It is possible to obtain a change in the size of micropores 6 in the range of diameters of 3.75–4.14 A, which is quite sufficient for the sorbent 1 to not be able to sorb substances having a heat of sorption greater than the propellant in the sorbent 1. Modification of the carbon sorbent 1 by carbon deposition during pyrolysis, for example, methane, at the same time does not change the total volume of micropores, but reduces the size of the entrances to micropores. (Dubinin M.M. Fedoseev D.V. Vnukov S.P. Polyakov N.S. Izv. Academy of Sciences of the USSR. Ser. Chem. N11, 1983, p. 2485-2487).

 An additional embodiment of the device is possible (Fig. 3), in which an insulating layer 9 is gas-tight, made with the possibility of its destruction upon placement of the capsule 5 inside the housing 3.

 This insulating layer 9 is designed to exclude the interaction of the sorbent 1, saturated with the propellant, with the environment before placing the capsule 5 inside the housing 3.

 The insulating layer 9 can be made of foil, then the capsule 5 or the casing 3 must be equipped with an element (not shown in Fig. 1) for breaking the metal foil when the capsule 5 is placed inside the casing 3.

 The insulating layer 9 may be made of a material capable of dissolving it with liquid 2 when the capsule 5 is placed inside the housing 3. For example, if dissolved sugar is included in the composition of the medicine used as liquid 2, the membrane may be coated with a thin insulating layer 9 sugar, which then dissolves in liquid 2. If the composition of the paint and varnish composition used as liquid 2 contains a solid soluble dye, the membrane can be coated with a thin layer of this dye, which then grows oryaetsya chemical solvent liquid 2.

 A device operates to create excess pressure in the propellant system in the same way as known.

 When placing the capsule 5 inside the housing 1 and sealing it in the propellant system, excessive pressure is created due to the release of the propellant from the sorbent 1. Liquid 2 through the tube 7 enters the transfer valve 4 and is sprayed outside the housing 3 when it is opened.

 By isolating the sorbent 1 from medium components having a greater heat of sorption than the propellant in the sorbent 1 by making the capsule 5 in the form of a membrane, the dimensions of the through pores 6 in which are made larger than the minimum size of the propellant molecule and smaller than the minimum size of the molecule of the liquid component with a larger than the propellant, by the heat of sorption in the sorbent 1, it is possible to realize the selective exclusion of the penetration of the components of the medium, except for the propellant into the sorbent.

 The invention can be industrially applied in aerosol containers for various purposes: in medicine, in perfumery, etc.

Claims (12)

 1. The method of creating excess pressure in the propellant system, including the desorption of gaseous propellant from the sorbent, which is saturated with the propellant and introduced into the medium, including liquid, saturated liquid vapor and propellant, characterized in that the heat of sorption of the components of the medium in the sorbent is determined before saturation with the sorbent propellant , substances with a heat of sorption greater than the propellant of sorption in the sorbent are removed from the latter, and when the sorbent is introduced into the medium, the sorbent is isolated from the components of the medium with a greater m propellant, heat of adsorption in the sorbent. 2. The method according to claim 1, characterized in that activated carbon is used as a sorbent, as a gas of CO ₂ , and / or Ar, and / or N ₂ , and / or O ₂ , and / or N ₂ O, and as a liquid, water and / or mineral water and / or sweet water and / or juice and / or whipped cream and / or protein cream and / or wine and / or beer and / or one-alcohol and alcohol solutions and / or pastes and / or emulsions and / or suspensions. 3. The method according to claim 1, characterized in that as the sorbent use zeolite or silica gel, as a gas of CO ₂ and / or Ar, and / or N ₂ , and / or O ₂ , and / or N ₂ O, and as a liquid, anhydrous alcoholic medical and / or confectionery and perfume solutions, and / or pastes, and / or emulsions and / or suspensions. 4. The method according to claim 1, characterized in that as the sorbent use zeolite and / or activated carbon, as a gas of CO ₂ and / or Ar, and / or N ₂ , and / or O ₂ , and / or N ₂ O, and as a liquid - anhydrous alcoholic solution.  5. A device for generating excess pressure in the propellant system, comprising a housing, a dispensing valve installed in an opening on the housing wall, a liquid, a propellant, a sorbent saturated with propellant that are placed inside the housing, while the sorbent is placed inside the capsule, the housing of which is configured transmitting propellant, characterized in that the capsule is made in the form of a membrane, the size of the through pores in which are made larger than the minimum size of the propellant molecule and less than the minimum size of the mole Cule component of the liquid with a greater than the propellant, the heat of sorption in the sorbent.  6. The device according to claim 5, characterized in that the membrane is made in the form of a layer of material located on the surface of the sorbent.  7. The device according to claim 6, characterized in that the pyrolytic deposited carbon is used as the material of the layer.  8. The device according to claim 5, characterized in that the membrane is additionally equipped with a gas-tight insulating layer, made with the possibility of its destruction when the capsule is placed inside the housing.  9. The device according to claim 8, characterized in that the insulating layer is made of a material capable of dissolving a liquid.  10. The device according to claims 8, 9, characterized in that sugar or gelatin is selected as the material of the insulating layer.  11. The device according to claim 8, characterized in that the insulating layer is made of a gas-tight film, and the capsule or body is equipped with a tearing element that is installed with the possibility of interaction with the film and its mechanical destruction.  12. The device according to paragraphs. 8 and 11, characterized in that the gas-tight film is made of polyethylene or cellophane or metal foil.

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