NL1008363C2 - Method for cleaning solid materials and device for applying this method. - Google Patents

Description

VO 2053

Title: Method for cleaning solid materials and device for applying this method.

The present invention relates to a method for cleaning solid materials, in particular textile products, in which the surface of these materials comes into contact with a surfactant in a solvent brought into a near-critical state.

By compressing a solvent in the gas phase, before it enters completely into the liquid phase, at a specific value of temperature and pressure, it will reach the critical point at which the liquid is highly compressible. The liquid phase and the gas phase are then indistinguishable from each other; the solvent is in a near-critical state at temperatures and pressures near these critical values.

If at high pressure the molecules in a medium are so close to each other that the electron clouds start to disturb each other considerably, the electrons of the different molecules will repel each other thanks to the electrical interaction. At a lesser pressure the molecules in the medium are at a greater distance from each other and due to the polarity of the molecules an attraction force will occur between the molecules. At the so-called critical pressure, the attractive forces are of the same order as the repelling forces and, due to the high compressibility of the medium, the quality as a solvent for contaminating substances thereof can be adjusted by choosing a suitable pressure. This is the reason that the cleaning of solid materials in a near critical solvent under suitable temperature and pressure has been proposed, which is therefore practiced.

Cleaning a solid material in a near critical solvent without further additives is a very time consuming process. There is then '; "·" V ".

2 also proposed a surfactant, one! so-called surfactant, this is a soap, to be added, j while the solvent is kept moving mechanically. An adsorbed layer of the surfactant then forms on the surface of the material to be cleaned, which surfactant reduces the surface tension of the material to be cleaned and of the substances to be removed, and thereby the transport of particles from the surface of the material to be cleaned. cleaning material to the solution can promote 10. However, it has been found that when this so-called equilibrium surface tension is plotted against the concentration of the surfactant, an optimum cleaning effect is obtained in the region where a change of this concentration does not affect the equilibrium surface tension. In the article by D.J.M. Bergink, Martens and G. Frens in 'Tenside Surfactants Detergents', 34 r 1 rj yrg., 1997, p. 263-266, no matter how dynamic; surface tension is important for the cleaning action of the surfactant. A mechanical movement - 1.2 generated in the solvent - exerts a force on the surface to be cleaned and, as far as a textile product is to be cleaned, on the fibers of this product. This force manifests in r -. a local stretching and contraction of these fibers, that is to say, in a larger and smaller surface. At rack

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- a transport of surfactant to the fibers will occur by diffusion, while with subsequent shrinkage and by local over-saturation due to surfactant on the fibers, a transport by diffusion; 30 to the solvent, whereby substances to be removed (dirt) are included. The mechanical movement by which: r stretch and shrink the fibers should preferably be: ir: such that the transport speed through the: - == diffusion layer can keep up with this stretching and shrinkage. The transport of the surfactant through the diffusion layer under these conditions is a measure of the dynamic f * *: ï 1 ~ Rit | ; , 1¾ _ r ':. ;, * ψ TWt * 7T *? 1 3 surface tension. From said article in 'Tenside surfactants detergents' it is shown, when not only the equilibrium surface tension but also the dynamic surface tension is plotted against the concentration of the surfactant, that an optimum cleaning effect is obtained where the equilibrium surface tension and the dynamic surface tension approximate each other in size. In this manner of cleaning with a solvent and a surfactant while exerting a relatively great force on the material to be cleaned, in particular textile products, a great wear of the product to be cleaned is obtained as a result of the applied force.

The object of the invention is, while retaining the advantages of this manner of cleaning, to provide such a method in which wear is wholly or almost completely avoided.

According to the invention, the method as described in the preamble is characterized in that the cleaning action of the surfactant (surfactant) is achieved by varying the pressure in the solvent.

In order to explain this effect, it must be realized that surfactant molecules have a part (the head) that dissolves easily in the solvent and a part (the tail) that does not dissolve under normal conditions. Under increased pressure the solubility of the 'tail' increases, ie the interaction forces between the solvent and the surfactant increase, which is reflected in the value of the 2nd virial coefficient in the Kamerlingh Onnes series development as a differentiation of the law of Van der Waals. Due to a reduced solubility in the solvent, the transport of surfactant molecules through the diffusion layer to the material to be cleaned increases. By increasing the pressure, the solubility of the "tail" and thus of the "4"! Surfactant molecules increases and a diffusion of these I molecules occurs from the material to be cleaned to the solvent taking dirt into account By pulsating the pressure in the solvent, a periodically changing solubility of the 3 surfactant molecules is obtained, which, when a textile product is used as material, has the same effect on the adsorbed surfactant molecules on the surface of the fibers in this product has as stretching and shrinking of the fibers themselves under a physical force exerted by, for example, stirring, but without the disadvantage of wear occurring. As surfactant, for example, nonanol can be used, this surfactant can be built up are thought of a 'head' formed by a 15 octane group with a value of the 2nd j virial coefficient of approximately 300 and one by one. Methanol-formed "tail" having a 2nd virial coefficient value of about 125. By using near-critical CO2 as a solvent, the "tail" solubility under pressure can be increased to an extent if corresponds to a value of the 2nd virial coefficient of about 300, therefore about

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. , H corresponding to that of the 'head'. The choice to use CO2 'is based on the consideration that this substance under ... 25 relatively easily adjustable physical conditions; (at a temperature of 31 ° and a pressure of 75 bar) r critical point have been reached. In addition, CO 2 appears to have a disinfecting effect near the critical point. For example, an alternative to CO2 can be used. 30 made from near-critical dimethyl ether, of which it. ™ critical point is at a temperature of 127 ° and a pressure of 53 bar, or near critical propane, the critical point of which is at a temperature of 97 ° and a pressure of 42 bar. However, these materials are quite flammable and require quite expensive safety measures. As an alternative to nonanol, as a surfactant in i - i'i

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Mm i mm 5 is particularly suitable for use in near-critical CO2, for example use can be made of fluorosurfactants, which are marketed under the name 'zonyl fluorosurfactants1 by Dupont 5 de Nemours.

In order for the transport of surfactant molecules to diffuse back and forth to the solid surface in such a way that a good cleaning effect is obtained, it is advantageous if the pressure in the solvent is varied with a frequency on the order of 0.1 to 10. Hz and preferably at about 1 Hz.

It has been found in practice that the pressure in the solvent can be varied by means of sound vibrations, preferably with a frequency of about 0.5 to about 10 Hz, while for varying the pressure in the solvent, preferably with a frequency of about 0.1 to about 2 Hz use can be made of a valve mechanism for pulsating mechanical pressure on the solvent.

In addition to a method for cleaning solid materials, the invention also relates to a device for cleaning solid materials for applying the method indicated above, which device is provided for this purpose with a pressure vessel in which the material to be cleaned can together with a solvent and a surfactant (surfactant), the physical conditions in the vessel during cleaning being such that the solvent is in a near-critical state. This device is then characterized in that pressure-varying means are present to bring about pressure variations in the solvent and thereby activate, under the aforementioned physical conditions, the cleaning action of the surfactant. The pressure vessel has for this purpose a supply for the solvent, a supply for the surfactant, a door or valve for the introduction and removal of the product to be cleaned, a discharge for the solvent, including surfactant and dirt, as well as means for adjusting the desired temperature and pressure in the pressure vessel. Furthermore, | pressure-varying means arranged in or outside, if desired in direct physical contact with the pressure vessel.

The pressure-varying means can be formed by a sound source in physical contact with the solvent or by a pulsator for generating mechanical vibrations which can be transferred to the solvent via a membrane.

The present invention can be used in particular for the industrial cleaning of textile products. Such an application is very attractive for cleaning large quantities of sheets and linen for hospitals, hotels, etc., which often lease these textile products from industrial laundries ► "1 '] f 1 * f' T ™ a * .. ... Τ '** · * -Ir · * · r ~ ?? * w * f.

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Claims (8)

1. A method for cleaning solid materials, in particular textile products, wherein the surface of these materials comes into contact with a surfactant in a solvent brought into a near-critical state, characterized in that the cleaning agent action of the surfactant is achieved by varying the pressure in the solvent. Process according to claim 1, characterized in that near-critical CO2 is used as the solvent. A method according to claim or 2, characterized in that the pressure in the solvent is varied with a frequency on the order of 0.1 to 10 Hz and preferably by about 1 Hz. 4. A method according to claim 3, characterized in that the pressure in the solvent is varied by means of sound vibrations with a frequency of about 0.5 to about 10 Hz. 5. A method according to claim 3, characterized in that the pressure in the solvent is varied by means of a valve mechanism controlled by a frequency of about 0.1 to about 2 Hz for pulsating a mechanical pressure on the solvent. . 6. Apparatus for cleaning solid materials for applying the method according to any one of the preceding claims, provided with a pressure vessel, into which the material to be cleaned can be introduced, together with a solvent and a surfactant, wherein during the cleaning, the physical conditions in the vessel are such that the solvent is in a near-critical state, characterized in that pressure varying means are present to cause pressure variations in the solvent and thereby, under said physical conditions, the cleaning activate the action of the surfactant. 7. Device as claimed in claim 6, characterized in that the pressure-varying means are formed by a sound source which is in physical contact with the solvent. 8. Device as claimed in claim 6, characterized in that the pressure-varying means are formed by a pulsator i for generating mechanical vibrations which can be transferred to the solvent via a membrane. »R 1 '1 --¾ ► It · r TH COOPERATION TREATY (PCT) REPORT ON NEWNESS RESEARCH OF INTERNATIONAL TYPE OF NATIONAL APPLICATION LICENSE Characteristic of the applicant ol of the gemnakoe Nw 2053 Neo-teeth application no. 1998 In vocrrangsaaum Applicant (Name) TNO Daurn of the request for an undertones of mtemasonal type Reconciled by the Authority for Intemaaonaai Onderzoenoen (ISA) to an investigation of intemaoroonaJ type segenend nr. SN 30966 NL __ I. CLASSIFICATION OF THE SUBJECT (when using different classifications, specify all classification symbols) According to the intemal classification (1PC) Int.Cl.6: D 06 L 1/00 II. FIELDS OF TECHNIQUE EXAMINED _______ Minimum Documentation Requested __ Classification System _Classification Symbols _ * _ Inc.Cl.6: D 06 L Examined Ce re oocumentaoe then the minimum documentation to the extent that such documents are contained in the study 90 c * os. 1 i NO RESEARCH MAY BE FOR CERTAIN CONCLUSIONS (comments on supplement payload) IV. ' LACK OF UNITY OF INVENTION (notes on supplement payload)! Form PC7, 'ISA'201iai CS 1S9 »