GEL FOR REMOVING GRAFFITI AND METHOD FOR REMOVING GRAFFITIS USING THE GEL.

专利摘要:
Gel for removing a graffiti on a surface of a solid substrate, consisting of a colloidal solution comprising an inorganic viscosifying agent; one or more solvent (s); optionally at least one surfactant; and optionally at least one dye and / or pigment. A method of removing graffiti on a surface of a solid substrate, wherein the gel is applied to said surface.
公开号:FR3027310A1
申请号:FR1459884
申请日:2014-10-15
公开日:2016-04-22
发明作者:Amelie Ludwig；Frederic Goettmann；Fabien Frances
申请人:Commissariat a lEnergie Atomique CEA；Commissariat a lEnergie Atomique et aux Energies Alternatives CEA；
IPC主号:

专利说明:

[0001] GEL FOR REMOVING GRAFFITI AND METHOD FOR REMOVING GRAFFITIS USING THE GEL. TECHNICAL FIELD The present invention relates to the use of a gel to remove a graffiti, also called "tag" found on a surface of a solid substrate. The gel according to the invention may be called suction gel. The present invention further relates to a method for removing graffiti on a surface of a solid substrate using this gel. The technical field of the invention can be defined as that of the treatment of polluted surfaces, soiled, deteriorated by graffiti, "tags" in order to eliminate the graffiti of these surfaces and in particular to improve the visual appearance of these surfaces . The invention can be applied to all kinds of surfaces such as organic polymer surfaces, for example plastics; surfaces made of vitreous materials; surfaces made of cementitious materials such as cements, pastes, mortars and concretes; surfaces of raw or cooked earth; brick or tile surfaces; plaster surfaces; ceramic surfaces; natural or artificial stone surfaces; plaster surfaces; fiberglass surfaces; fiber cement surfaces; asphalt or tar surfaces; metal or metal alloy surfaces, for example steel, galvanized steel or zinc; and surfaces made of cellulose-based materials such as wood. These surfaces can be painted or not. These surfaces may be porous or not. The invention is particularly applicable to the removal of graffiti on outdoor outdoor surfaces, buildings, constructions, and objects or structures. But the invention can also be applied to the removal of graffiti from interior or exterior surfaces of aquatic vehicles such as boats; land vehicles such as cars, trucks, motorcycles, trains, subways, coaches and buses; aircraft such as airplanes, helicopters, or seaplanes; indoor or outdoor furniture such as street furniture or transit vehicle seats, etc. It should be noted that there is no limitation as to the surface on which the graffiti removed according to the invention can be found. STATE OF THE PRIOR ART For many years, the fight against the proliferation of graffiti, also called "tags", has been a growing concern for many communities and private companies in many countries.
[0002] Indeed, in addition to the deterioration of goods such as buildings, street furniture, trains, etc., the presence of graffiti can also harm the image of a city, a neighborhood or a city. enterprise by the feeling of insecurity it generates. This type of vandalism therefore has a strong social and economic impact. These graffiti are a serious problem when they cover buildings, especially monuments, which are often made of stone, bricks and other porous materials. Indeed, it is very difficult to remove graffiti from such porous materials and an inestimable cultural heritage can be irreversibly altered. It is therefore necessary to be able to treat, both preventively and curatively, materials vandalized by tags, without altering these materials, and in a reactive manner, to prevent further attacks and to prevent the painting from interacting and does not combine with air pollution, making cleaning operations more difficult. For this, different treatment techniques exist. One can distinguish on the one hand the preventive techniques and on the other hand the curative techniques.
[0003] Preventive techniques essentially include the application of sacrificial, semi-permanent or permanent film coatings that protect the surfaces and / or facilitate the removal of the paint. Curative techniques include high-pressure water blasting, sandblasting, paint application on "tagged" surfaces covered with graffiti, removal of graffiti by cleaning agents such as solvents or alkalis or by irradiation with a laser beam. All these processing techniques require a trained, qualified, and important workforce, especially for the installation of protective films, the handling and maintenance of high-pressure devices or lasers, the handling of chemicals, which makes the very expensive anti-graffiti operations. Some of these processing techniques use gels. Thus, the document DE-A1-195 27 582 [1] relates to a method for eliminating graffiti made in aerosol spray paint in which the paint is dissolved with a gel comprising anise essential oil, oil essential of odorless inula, glycerin, and silica. The gel of this document is not a gel that can be described as aspirable gel. In addition, the gel of this document has a dissolving action on the graffiti, which must subsequently be eliminated by an additional washing-type operation.
[0004] Document FR-A1-2,683,541 [2] relates to a cleaner for painted surfaces stained with graffiti, which may be in the form of a gel, and which comprises one or more solvents chosen from butanol, isopropanol, ethanol, butyrolactone, cyclohexanone, N-methylpyrrolidone, dimethylformamide, butyl acetate, ethylglycol acetate, ethoxypropyl acetate and butylglycol, one or more strong oxidizers, and there % by weight of at least one substance capable of forming a gel such as bentonites, silicas and cellulose derivatives. The gel of this document is not a gel that can be qualified as an aspirable gel, it comprises powerful oxidizers that can damage the surfaces, and its effectiveness is, it seems, low.
[0005] Furthermore, in this document, there is no description of the method that is used to apply or implement the gel. Document FR-A-2,737,218 [3] describes a cleaning composition in the form of a gel for removing chewing gums and graffiti which comprises a carbon-based solvent, a gelling agent, a polar solvent and optionally a miscellant.
[0006] The gelling agent may be in particular finely divided silicon dioxide, the solvent of ethanol, and the carbonaceous solvent is chosen from gasolines C, E, F, and A. The gel of this document has the major disadvantage of containing a carbonaceous solvent which is selected from carcinogenic compounds.
[0007] In addition, the gel of this document is not, it seems, a gel that can be described as aspirable gel and its effectiveness is, it seems, low. In addition, the method of application of the composition of this document on gums and graffiti is not specified. In particular, it is not sought in this document specifically to obtain a sprayable gel.
[0008] BE-A3-1014037 [4] relates to a method for removing graffiti, in which a gel comprising a mixture of carbonaceous solvents, a polar solvent and a gelling agent is sprayed onto the soiled surface and allowed to dry the gel. A gaseous compound, such as carbon dioxide ice cubes, or pressurized dry steam is then sprayed onto the surface where the dry gel is located, and the surface is generally rinsed. The gelling agent may in particular be finely divided silicon dioxide, and the mixture of carbonaceous solvents is chosen from gasolines C, E, F, and A. The gel of this document has the disadvantage of containing a carbonaceous solvent chosen from compounds toxic, carcinogenic, which therefore presents a danger for the operators. The gel of this document is not, it seems, a gel that can be described as suction gel, and the method of this document therefore comprises a final rinsing step that produces significant amounts of liquid effluents. US-A1-2007 / 0181166 [5] relates to a method for removing graffiti, which uses a viscous gel consisting of a mixture of various solvents and surface-active agents, for example a mixture of N-methyl- 2-pyrrolidone, dipropylene glycol mono-methyl ether, 2-methoxy-2-propanol, 2-methoxy-1-methylethyl acetate, polyglycol ether and fatty alcohols, and heavy naphtha solvent . The surface on which the graffiti is located is first moistened, then the gel is applied to the graffiti with a brush or a trowel and rubbed to make it penetrate the graffiti. The gel is then removed using a sponge or a damp cloth. This gel includes certain compounds such as heavy naphtha which are carcinogenic. This gel is an essentially organic gel that includes only organic and non-mineral viscosifying agents. This gel is not a gel that can be described as aspirable mineral gel and its elimination after the treatment is done wet is tedious. WO-A1-99 / 09134 [6] relates to a cleaning composition for removing long-chain compounds such as bitumen, tar, wax and chewing gum which comprises an inert gel matrix therein which is enclosed a non-aqueous liquid solvent in which the long-chain compound is soluble. The matrix of the gel is formed for example by a silica or a clay. The solvent may be chosen from saturated and unsaturated hydrocarbons, alcohols, glycols, aldehydes, ketones, ethers, terpenes, phthalates, esters, or halogenated hydrocarbons. Claim 7 lists at least 38 solvents among which ethyl acetate is incidentally mentioned. The gel of this document is not a gel that can be described as aspirable gel. Furthermore, in this document, there is no description of the method that is used to apply or implement the gel. The only example given in this document concerns the elimination of chewing gum whose composition is very far from that of graffiti which are generally paint. There is no mention or suggestion in this document that the gel described therein can be used to solve the specific problem of graffiti removal. GB-A-1,487,737 [7] relates to a composition in the form of a gel for removing aerosol-type paint graffiti which comprises an organic solvent comprising a compound comprising an ester group and a compound comprising an ether group and an alcohol group, a soluble gelling agent in both water and an organic solvent and a surfactant which leads to the formation of an oil-in-water emulsion when the composition is dispersed in water. Among the many compounds that can constitute the organic solvent, ethyl acetate is incidentally mentioned on page 2, lines 17 and 18.
[0009] The gelling agent, viscosity of the composition is a derivative of water-soluble cellulose such as hydroxypropyl cellulose. Finely divided solid adsorbents such as silica or fumed alumina may optionally be added to the composition to act as a solid adsorbent for inorganic pigments and not as viscosifiers.
[0010] Silica and alumina are therefore not used in the compositions of this document as inorganic viscosifying agents. Only the cellulose derivative such as hydroxypropylcellulose acts as a viscosity agent and is an organic viscosity agent. The gel of this document is not a mineral gel and is not aspirable.
[0011] In fact, the gel can be applied by brush or trowel, left in contact with the graffiti and is then rinsed with water using a hose or a brush and Consequently, in the context of nuclear decontamination, gelled formulations which make it possible to overcome the problems related to the pulverulent character of the dry waste, and to increase the efficiency of the process a gel have been the subject of documents FR-A1-2 827 530 [8] and FR-A1-2 891 470 [9]. These documents describe inorganic colloidal gels called "suction gels", specifically formulated to be sprayed, then to dry by fracturing, while trapping and confining radioactive contamination in the form of non-pulverulent, aspirable, directly packable and storable flakes. Document [8] describes a gel consisting of a colloidal solution comprising an inorganic viscosifying agent, generally silica or alumina, an active treatment agent which is, for example, an acid or an inorganic base such as sodium hydroxide or potash, and optionally an oxidizing agent having a normal redox potential Eo greater than 1.4V in a strong acid medium such as Ce (IV), Co (III), or Ag (II).
[0012] The document [9] describes a gel consisting of a colloidal solution comprising an inorganic viscosifying agent, generally silica or alumina, a surfactant, an acid or an inorganic base, optionally an oxidizing agent having a normal potential. oxidoreduction Eo greater than 1.4V in strong acid medium such as Ce (IV), Co (III), or Ag (II). These inorganic colloidal gels, because of the different constituents used in their composition have a rheology that allows their spraying on a contaminated surface, then their adhesion to this surface, even vertical, without sinking. This thus allows prolonged contact between the contaminant and the active decontamination agent, without the mechanical properties of the substrate being altered. Following its spraying, the gel dries, fractures, and produces dry residues, called "flakes", adhering to the substrate and which are subsequently removed by brushing or aspiration to be directly conditioned. The decontamination processes that use these suction gels are therefore dry decontamination processes, generating no liquid effluent and few dry solid residues. Indeed, these dry solid residues represent on average only a quarter of the initially sprayed gel mass. Moreover, these methods limit the exposure time of the operators to the radioactive contamination, because of their easy implementation by spraying and then suctioning dry residues, and because the presence of the operator is not required during the drying of the gel. The gels described in documents [8] and [9], however, are specifically intended for the radioactive decontamination of surfaces, particularly in the context of the dismantling of nuclear installations, and are in no way adapted to the removal of surface graffiti. or even able to be adapted to solve the extremely specific problem of removing graffiti from surfaces. Documents FR-A1-2962046 and WO-A1-2012 / 001046 [10] relate to an "aspirable" biological decontamination gel and a process for the biological decontamination of surfaces using this gel.
[0013] This gel consists of a colloidal solution comprising at least one inorganic viscosifying agent, at least one biological decontamination agent, at least one superabsorbent polymer, at least one surfactant, and the remainder of solvent. Documents FR-A1-3003763 and WO-A1-2014 / 154818 [11] relate to an oxidizing alkaline gel for "aspirable" biological decontamination and a process for the biological decontamination of surfaces using this gel. This gel consists of a colloidal solution comprising at least one inorganic viscosifying agent, an active biological decontamination agent consisting of the combination of a specific mineral base, such as sodium hydroxide, and a stable oxidizing agent in a specific basic medium, such as sodium hypochlorite, optionally a surfactant, and the remainder of solvent. In addition, this gel does not contain superabsorbent polymer. The gels of the documents [10] and [11] are, however, specifically intended for the biological decontamination of surfaces, in particular for so-called post-event decontamination of surfaces. There is no mention or suggestion in the documents [10] and [11] that the freezes of these documents could solve the extremely specific problem of the removal of surface graffiti, which is a totally different problem. problem of biological decontamination - especially post event - because of the very particular nature of graffiti. Thus, in view of the foregoing, there is a need for a composition and method for removing graffiti from the surface of substrates which, while having a high efficiency, and at least as high as that of the compositions and methods for removing graffiti discussed above, do not have the disadvantages, defects, limitations and disadvantages of these compositions and methods and that solve the problems of the compositions and methods of the prior art to eliminate graffiti. This composition and this process must in particular have a high efficiency to eliminate graffiti whatever the composition of these graffiti and the material of the surface to which they have been affixed.
[0014] This composition must be easy to apply and eliminate and produce a limited amount of waste including liquid waste. This composition must have a very low or no toxicity. In particular, there is a need for a composition and a method for eliminating graffiti from the surface of substrates which limits the number of operators necessary for their implementation, as well as mechanical actions that are painful, tedious, or requiring increased training of the operators. . The object of the present invention is to meet, among others, these needs and requirements.
[0015] SUMMARY OF THE INVENTION This and other objects are achieved, in accordance with the invention, by a gel for removing a graffiti on a surface of a solid substrate, consisting of a colloidal solution comprising, preferably consisting of : 0.1% to 30% by weight, preferably 0.1% to 25% by weight, more preferably 5% to 25% by weight, more preferably 8% to 20% by weight, for example 10% by weight with respect to the total mass of the gel, at least one inorganic viscosifying agent; - 70% to 99.9% by weight, preferably 75% to 99.9% by weight, more preferably 75% to 95% by weight, for example 90% by weight, of one or more solvent (s) chosen from alkyl acetates (linear or branched alkyl group of 1 to 10C) such as ethyl acetate, and compounds of formula (I): (I) in which R and R ', identical or each independently represents a linear or branched alkyl group of 1 to 10 C such as a methyl, ethyl, propyl, or isopropyl group, or a linear or branched alkoxy group of 1 to 10 C such as a methoxy group, ethoxy, propoxy, or isopropoxy, and n is 1, 2 or 3; optionally 0.1% to 2% by weight, based on the total mass of the gel, of at least one surfactant. and optionally from 0.01% to 10% by weight, based on the mass of the gel, of at least one dye and / or pigment; The gel according to the invention has never been described in the prior art. The gel according to the invention is basically characterized in that it contains one or more specific solvent (s) chosen from ethyl acetate and the organic compounds of formula (I) described above. These (s) solvents constitute the active principle of the gel according to the invention and can be defined as stripping active agents. This (s) solvent (s) of the gel according to the invention, is (are) little (or not) toxic (s), harmful (s).
[0016] In other words, according to the invention, care has been taken that the gel solvents are specifically chosen from the least toxic solvents, and the least harmful, or non-toxic, and non-harmful, so as to protect the operators who implement the gel according to the invention. This is a characteristic that fundamentally differentiates the gel according to the invention of gels nti-graffiti of the prior art in which solvents, for example gasolines, toxic or harmful are implemented. This solvent (s) of the gel according to the invention are (are) in addition solvents which gives off an odor which is not or slightly nauseating, or unpleasant. In other words, great care has been taken that the solvents of the gel according to the invention are chosen from solvents whose odor is the least nauseating, the least unpleasant, or not at all nauseating or unpleasant. In other words, the solvents of the gel according to the invention are chosen from solvents which have a "stench" limited or even zero. The solvent or mixture of solvent (s) of the gel according to the invention also has a generally compatible volatility with a good gel drying time, that is to say a volatility which guarantees a not too high drying rate and therefore a sufficient drying time to ensure effective removal of graffiti, for example a drying time equal to or greater than 1 hour, especially close to one hour. Most of the solvents mentioned above have a low volatility, are not very volatile and therefore allow, when used alone in the gel according to the invention to obtain a sufficient drying time, for example an equal or greater drying time at 1 o'clock, especially close to an hour. However, some of the solvents mentioned above have a high volatility, give gels that dry too quickly, and do not allow when they are used alone in the gel according to the invention to obtain a sufficient drying time; is for example the case of ethyl acetate. These solvents which have a high volatility are therefore generally used in combination, mixed with another solvent which has a low volatility in order to obtain a sufficient drying time.
[0017] It is precisely the combination of such a high volatility solvent with another solvent of lower volatility that can "slow down" the drying of the gel and wait for a good drying time, a sufficient drying time. In the same way, the volatility of the solvent or of the solvent mixture is generally such that the gel does not dry too slowly and that its drying time is not too long and does not exceed, for example, 4 hours. . Those skilled in the art can easily identify, among the solvents of the gel according to the invention mentioned above the solvents having a low volatility, and the solvents having a high volatility. Surprisingly, and although the solvents of the gel according to the invention are selected from the solvents little (or even nontoxic), harmful (s), these solvents alone or in mixture however have a high efficiency to eliminate graffiti whatever the substance that constitutes them, for example painting or ink. In particular, these solvents have a high efficiency for eliminating graffiti, tags in spray paint.
[0018] Advantageously, the solvent (s) is (are) chosen from among ethyl acetate, ethyl levulinate, acetyl acetone, methyl levulinate, methyl acetoacetate and acetoacetate. ethyl, dimethyl succinate, diethyl malonate, and mixtures thereof.
[0019] Advantageously, the gel may comprise a mixture of ethyl acetate and of diethyl malonate or of methyl acetoacetate, preferably in proportions by weight of 20% to 99%, preferably 50% to 99% by weight. 80% ethyl acetate, and 1% to 80%, preferably 1% to 50%, for example 20% diethyl malonate or methyl acetoacetate.
[0020] When the gel comprises such a mixture of solvents, this mixture generally represents from 60% to 99% by weight, for example 90% by weight of the mass of the gel, and the viscosing agent is preferably alumina at the rate of 0.1% to 30% by weight, for example 10% by weight of the mass of the gel. It has been found (see Example 1) that the mixture of ethyl acetate and diethyl malonate surprisingly makes it possible to obtain a gel which has a reasonable drying time, namely for example from 1 to 4 hours, and that is also very effective. The gel according to the invention is a suction gel which has all the advantageous properties - mentioned above - inherent to the gels known as suction gels such as the gels of documents [8], [9], [10], and [11], with the fundamental difference, however, that with the gel according to the invention, it does not move contaminants to dry gel flakes, but eliminates a graffiti, an undesirable tag - usually in paint - a support, and that the composition of the gel is therefore adapted accordingly. As indicated above, the gels of these documents are aqueous gels specifically designed for the radioactive or biological decontamination of surfaces and whose solvents and active decontamination agent are totally different from those of the gel according to the invention. . There is no indication in the documents [8], [9], [10], and [11], which could lead the person skilled in the art to modify in such a substantial manner the freezes of these documents in order to use them to eliminate graffiti.
[0021] The gel according to the invention is a colloidal gel whose active principle allows the removal of tags and graffiti, and whose rheology is suitable for application, preferably by spraying on tagged surfaces. This is one of the advantages of the gel according to the invention that can be applied very easily, by spraying. The gel according to the invention dries progressively, prolonging the contact time between the stripping agent and the paint, and forms flakes which are easily detached from the surface by brushing / suctioning - hence the name of the suction gel - thus taking away paint or unwanted ink and this without altering the substrate material, and even the original painting of this material. The cleaning operator can thus let the gel act on the graffiti paint while going to treat other surfaces, without having to be physically present during the drying or painstakingly rubbing the paint with a solvent. In summary, the gels according to the invention therefore meet all the needs mentioned above, they do not have the disadvantages, defects, limitations and disadvantages of the anti-graffiti compositions of the prior art, such as those described in the documents mentioned above and have all the advantageous properties known gels called "aspirable" gels. The gel according to the invention, although it contains a viscosity agent generally exclusively mineral inorganic, without mineral inorganic viscosifying agent, can be called organic gel. Indeed, the organic matter content of the gel according to the invention is high, at least equal to 70% by weight, for example equal to 90% by weight, since it contains at least 70% by weight, for example 90% by weight. mass of organic solvents.
[0022] The gel according to the invention is a colloidal solution, which means that the gel according to the invention contains inorganic solid particles, mineral, viscosity agent whose elementary particles, primary, have a size generally of 2 to 200 nm. These solid, inorganic, inorganic particles act as a viscosity agent to allow the solution to gel and thus adhere to the surface to be treated, regardless of its geometry, shape, size and wherever graffiti is found. to eliminate.
[0023] Advantageously, the inorganic viscosifying agent may be chosen from metal oxides such as aluminas, metalloid oxides such as silicas, metal hydroxides, metalloid hydroxides, metal oxyhydroxides, metalloid oxyhydroxides, aluminosilicates, clays such as smectite, and mixtures thereof. In particular, the inorganic viscosifying agent may be chosen from aluminas (Al 2 O 3) and silicas (SiO 2). The inorganic viscosifying agent may comprise only one silica or alumina or a mixture thereof, namely a mixture of two or more different silicas (SiO 2 / SiO 2 mixture), a mixture of two or more different aluminas (mixture A1203 / A1203), or a mixture of one or more silicas with one or more aluminas (mixture SiO 2 / Al 2 O 3). Advantageously, the inorganic viscosifying agent may be chosen from pyrogenic silicas, precipitated silicas, hydrophilic silicas, hydrophobic silicas, acidic silicas, basic silicas, such as Tixosil® 73 silica, marketed by Rhodia, and mixtures thereof. . Among the acidic silicas, mention may especially be made of fumed or fumed silicas of "Cab-O-Sil" ® M5, H5 or EH5 silica, marketed by CABOT, and fumed silicas marketed by the company EVONIK INDUSTRIES under the name AEROSIL®. Among these fumed silicas, AEROSIL® 380 silica with a specific surface area of 380 m 2 / g, which offers the maximum viscosity properties for a minimum mineral filler, will be preferred. The silica used may also be a so-called precipitated silica obtained for example by the wet route by mixing a solution of sodium silicate and an acid. The preferred precipitated silicas are sold by the company Evonik Industries under the name Sipernat® 22 LS and FK 310 or by the company RHODIA under the name Tixosil® 331, the latter is a precipitated silica whose average specific surface area is between 170 and 200 m2 / g.
[0024] Advantageously, the inorganic viscosifying agent consists of a mixture of a precipitated silica and a fumed silica. The alumina may be chosen from calcined aluminas, crushed calcined aluminas, and mixtures thereof.
[0025] By way of example, mention may be made of the product sold by EVONIK INDUSTRIES under the commercial designation "Aeroxide Alumine C" which is fine-pyrogenic alumina. Advantageously, according to the invention, the viscosing agent is constituted by one or more alumina (s) generally representing from 5% to 30% by weight relative to the mass of the gel. In this case, the alumina is preferably at a concentration of 7% to 15% by weight relative to the total mass of the gel to ensure drying of the gel at a temperature of between 20 ° C. and 50 ° C. and at a humidity of relative between 20% and 60% on average in 30 minutes to 5 hours.
[0026] The nature of the mineral viscosifying agent, especially when it consists of one or more alumina (s), unexpectedly influences the drying of the gel according to the invention and the particle size of the residue obtained. Indeed, the dry gel is in the form of particles of controlled size, more precisely millimetric solid flakes, the size of which generally ranges from 1 to 10 mm, preferably from 2 to 5 mm, in particular by the above-mentioned compositions of the present invention. invention, especially when the viscosing agent is constituted by one or more alumina (s). Note that the size of the particles generally corresponds to their largest dimension.
[0027] In other words, the inorganic solid particles of the gel according to the invention, for example of the silica or alumina type, in addition to their role of viscosity, also play a fundamental role during the drying of the gel because they ensure the fracturing of the gel to achieve to a dry waste in the form of flakes. The gel may optionally also contain a surfactant or a mixture of surfactants, preferably chosen from the family of nonionic surfactants such as block copolymers, which are block copolymers, such as block copolymers of ethylene and propylene oxide, and ethoxylated fatty acids; and their mixtures. For this type of gel, the surface-active agents are preferably block copolymers sold by the company BASF under the name PLURONIC®. Pluronics® are block copolymers of ethylene oxide and propylene oxide. These surfactants influence the rheological properties of the gel, in particular the thixotropic character of the product and its recovery time and avoid the appearance of sagging. The surfactants also make it possible to control the adhesion of the dry waste, and to control the size of the flakes of dry residue to ensure the non-dustiness of the waste. Advantageously, the gel according to the invention may further comprise at least one mineral pigment. When present, the mineral pigment is from 0.01% to 10%, preferably from 0.1% to 5% by weight of the total mass of the gel. The invention furthermore relates to a method for removing a graffiti on a surface of a solid substrate, wherein at least one cycle is carried out comprising the following successive steps: a) the gel according to the invention is applied, such as it has been described above, on said surface; b) the gel is maintained on the surface for at least sufficient time for the gel to remove graffiti, and for the gel to dry and form a dry, solid, non-powdery residue containing compounds resulting from the removal of graffiti; c) removing the dry and solid residue containing the compounds resulting from the removal of graffiti. The solid substrate may be a porous substrate, preferably a porous mineral substrate.
[0028] The effectiveness of the gel and the process according to the invention is just as good in the presence of a non-porous and / or non-mineral surface as in the presence of a porous and / or mineral surface. Advantageously, the substrate is in at least one material selected from metals and alloys such as stainless steel, galvanized steel, or zinc; painted steels; organic polymers such as plastics or rubbers such as polyvinyl chloride or PVC, polypropylenes or PPs, polyethylenes or PEs, in particular high density polyethylenes or HDPEs, poly (methyl methacrylates) or PMMA, polyvinylidene fluoride or PVDF, polycarbonates or PCs; the glasses ; cementitious materials such as pastes, cements, mortars and concretes; plasters; the bricks ; tiles ; raw or cooked earth; natural or artificial stones; coatings; fiberglass, fiber cement; asphalt; tar ; slate; cellulose-based materials such as wood; and ceramics. Generally, the graffiti includes a paint including an aerosol spray paint, an ink, or a mixture thereof. Advantageously, the gel is applied to the surface on which the graffiti is located at a rate of 100 g to 2000 g of gel per surface area, preferably from 500 to 1500 g of gel per surface area, more preferably from 600 to 1000 g of gel per surface rri2, which generally corresponds to a thickness of gel deposited on the surface of between 0.1 mm or 0.5 mm and 2 mm. Advantageously, the gel is applied to the solid surface by spraying, with a brush or with a trowel. Advantageously (during step b)), the drying is carried out at a temperature of 1 ° C. to 50 ° C., preferably of 15 ° C. to 25 ° C., and at a relative humidity of 20% to 80%. preferably from 20% to 70%. Advantageously, the gel is maintained on the surface for a period of from 30 minutes to 72 hours, preferably from 1 to 48 hours, more preferably from 1 to 24 hours, better still from 1 to 5 hours, for example from 1 to 4 hours. . Advantageously, the dry and solid residue is in the form of particles, for example flakes, of a size of 1 to 10 mm, preferably 2 to 5 mm.
[0029] Advantageously, the dry and solid residue is removed from the solid surface by brushing and / or suctioning. Advantageously, the cycle described above can be repeated for example from 1 to 10 times using the same gel during all the cycles or by using different gels during one or more cycle (s). Advantageously, during step b), the gel, before total drying, is rewetted with a solvent, preferably with the solvent of the gel applied during step a), which then generally avoids repeating the application of the gel on the surface and causes a reagent economy and a limited amount of waste. This rewetting operation can be repeated for example from 1 to 10 times. The method according to the invention has all the advantageous properties inherent in the decontamination gel that it uses and which have already been widely discussed above. The method according to the invention allows the effective curative management of tags, unwanted graffiti while being much less painful and much less expensive than conventional methods of cleaning these tags, namely: the methods using high pressure means, which are expensive and "technical" (complex), - processes using wipes soaked in harmful solvents whose use is long and laborious, - processes using protective films that are costly in time and men. Thus, the gel according to the invention can be sprayed with a simple commercially available paint gun while blasting apparatus, for example, require adjustments and special training. These sanding devices are complex and their maintenance is expensive. In addition, the method according to the invention is a dry process which avoids solvent or solvent stripping while optimizing the working time of the cleaning operator. Indeed, it is able to treat several areas at a time quickly, because of the gel drying time and its implementation advantageously by spraying. In summary, the method and the gel according to the invention have, among other things, besides the advantageous properties specifically due to the specific solvent contained in the gel, the following other advantageous properties: the application of the gel preferably by spraying, which It is not possible with most anti-graffiti gels of the prior art described above. Spraying makes it possible to quickly and easily treat large areas and requires fewer operators, - adhesion to the walls, - obtaining the maximum efficiency of removal of graffiti at the end of the drying phase of the gel , including penetrating graffiti especially in the case of porous surfaces. In general, it is ensured that the drying time is greater than or equal to the time necessary to eliminate the graffiti. In the case of deep graffiti, rewetting is generally used. the treatment of a very wide range of materials (see Example 2), the absence of mechanical or physical alteration of the materials at the end of the treatment, the implementation of the process under variable climatic conditions (cf. examples), - reduction of the volume of waste, - ease of recovery of dry waste.
[0030] The examples provided below show that the gel according to the invention because of its specific formulation and its simple, reliable and easy to use, is effective for the elimination of a wide variety of undesirable graffiti on a wide variety of materials.
[0031] Other features and advantages of the invention will appear better on reading the detailed description which follows, this description being given for illustrative and non-limiting, in conjunction with the accompanying drawings.
[0032] BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a photograph of the surface of the tagged painted steel plate tested at the end of the test of Example 1, in which the effectiveness of a gel according to FIG. invention in which the active agent is a mixture of ethyl acetate and diethyl malonate to remove a graffiti, "tag" deposited on this painted steel plate.
[0033] The surface of this plate, comprises, from left to right, a virgin first part where neither tag nor gel has been deposited, a second part where the "tag" has been applied, but has not been treated with the gel , a third part where the gel was applied to the tag and then the dry gel flakes. FIG. 2 is a graph which shows the gray level profile, along the line A shown in the photograph of FIG. 1, obtained from an image analysis of this photograph, carried out using the Imaget software On the abscissa the distance (in pixels) is plotted and the gray values are plotted on the ordinate. FIG. 3 is a graph which shows the roughness profile measured by a STIL optical profilometer of the painted steel plate tagged at the end of the test of example 1. In abscissa the stroke (in mm) is plotted, and on the ordinate is the altitude (in pirn). FIGS. 4 (A, B) to 8 (A, B) are graphs which show the gray level profiles (FIGS. 4B to 8B), along a line drawn in the same manner as in the photograph of FIG. obtained from an image analysis carried out using the ImageJ software of photographs (FIGS. 4A to 8A) of the surface of the plates in various tagged materials tested at the end of the tests of Example 2.
[0034] These materials are stainless steel (Figure 4), painted steel (see example 1), glass (Figure 5), ceramic (Figure 6), concrete (Figure 7), and plastic: PVC (Figure 8). During these tests, it is evaluated the effectiveness of a gel according to the invention which is the gel according to Example 1, to eliminate a graffiti, "tag" deposited on the various materials. In FIGS. 4B to 8B: on the abscissa the distance (in pixels) is plotted and the gray values are plotted on the ordinate. FIGS. 9 (A, B) to 16 (A, B) are graphs which show the gray level profile (FIGS. 9B to 16B), along a line drawn in the same manner as in the photograph of FIG. 1 , obtained from an image analysis carried out using the ImageJ software of a photograph (Figures 9A to 16A) of the surface of the tagged painted steel plate tested at the end of each of the tests of the EXAMPLE 4 In these tests, the effectiveness of a gel according to the invention whose active agent is respectively ethyl acetate (FIG. 9) and ethyl levulinate (FIG. 10) is evaluated. Acetyl acetone (Figure 11), methyl levulinate (Figure 12), methyl acetoacetate (Figure 13), ethyl acetoacetate (Figure 14), dimethyl succinate (Figure 15), Diethyl malonate (Figure 16), to eliminate a graffiti, "tag" deposited on this painted steel plate. In FIGS. 9B to 16B: on the abscissa the distance (in pixels) is plotted and the gray values are plotted on the ordinate. Figure 17 (A, B) is a graph that shows the gray level profile (Figure 17B), along a line drawn in the same manner as in the photograph of Figure 1, obtained from an analysis of image made using the ImageJ software of a photograph (Figure 17A) of the surface of the tagged painted steel plate tested at the end of the test of Example 5. During this test, it is evaluated the effectiveness of a gel according to the invention wherein the active agent is a mixture of ethyl acetate and methyl acetoacetate to remove a graffiti, "tag" deposited on this painted steel plate. In Figure 17B: in abscissa is the distance (in pixels) and in ordinate are carried the values of gray. - Figure 18 shows photographs of a lacquered steel electrical transformer stained with graffiti before (Figure 18A), and after (Figure 18B) treatment of these graffiti by application of a gel according to the invention composed of 89% by mass of acetylacetone and 11% by weight of alumina (Example 6).
[0035] Figure 19 shows photographs of a concrete bridge pile stained with graffiti before (Figure 19A), and after (Figure 19B) treatment of these graffiti by application of a gel according to the invention composed of 89% by weight acetylacetone and 11% by weight of alumina (Example 6). FIG. 20 shows photographs of a painted metal door stained with graffiti before (FIG. 20B), and after (FIG. 20A) treatment of these graffiti by application of the reference gel according to the invention described in example 1. EXHIBIT DETAILED OF PARTICULAR EMBODIMENTS The gel according to the invention can be easily prepared at room temperature.
[0036] For example, the gel according to the invention can be prepared by preferably adding progressively, the inorganic viscosity agent (s), for example the alumina (s) and / or the silica (s). (s), to the solvent (s), or to the mixture of the solvent (s) and any adjuvant (s). Possible adjuvants are generally the surfactant (s), or the mineral pigment (s).
[0037] This mixture of the solvent (s) and any adjuvant (s) may be made by mechanical stirring, for example by means of a mechanical stirrer equipped with a three blade propeller. The rotational speed is for example 200 rpm, and the duration of the stirring is for example 3 to 5 minutes. The addition of the inorganic viscosity agent (s) to the solvent (s) or solvent (s) and any adjuvant (s) may be be carried out by simply pouring the viscosity agent (s) into said one or more solvents or said mixture. When adding the inorganic viscosity agent (s), to the solvent (s), or to the mixture of the solvent (s) and any adjuvant (s) (s) ), this or these solvent (s) or this mixture are generally maintained with mechanical stirring.
[0038] This agitation can be, for example, carried out by means of a mechanical stirrer equipped with a three blade propeller. The stirring speed is generally increased gradually as the viscosity of the solution increases, finally reaching a stirring speed of, for example, between 400 and 600 rpm, without there being projections. After the end of the addition of the mineral viscosity (s) (s), the stirring is continued, for example for 2 to 5 minutes, so as to obtain a perfectly homogeneous gel. It is obvious that other gel preparation protocols used according to the invention can be implemented with an addition of the gel components in a different order from that mentioned above. Generally, the gel used according to the invention must have a viscosity of less than 200 mPa.s under a shear of 1000 to allow spraying on the surface to be decontaminated remotely (for example at a distance of 1 to 5 m ) or in proximity (for example at a distance less than 1 m, preferably from 50 to 80 cm). The recovery time of the viscosity should generally be less than one second and the viscosity under low shear greater than 10 Pa s to not flow on a wall. It should be noted that the optional surfactant of the gel according to the invention has a favorable and noticeable influence on the rheological properties of the gel used according to the invention.
[0039] This surfactant makes it possible in particular for the gel used according to the invention to be used by spraying and to avoid the risks of spreading or sagging during the treatment of vertical surfaces and ceilings. This surfactant also makes it possible to limit the phenomenon of bleeding observed during the conservation of the gel. The gel thus prepared is then applied to the solid surface to be cleaned of a substrate made of a solid material. By surface to be cleaned is meant a solid surface on which there is a graffiti, "tag" that it is desired to eliminate. There is virtually no limitation as to the material which constitutes the surface to be cleaned, in fact the gel according to the invention makes it possible to treat, without any damage, all kinds of even fragile materials.
[0040] The gel according to the invention does not generate any alteration, erosion, attack, chemical, mechanical or physical of the treated material. The gel according to the invention is therefore in no way detrimental to the integrity of the treated materials and even allows their reuse. Thus, the monuments, buildings, works of art such as sculptures, treated by the gel according to the invention are absolutely not degraded and see their visual and structural integrity preserved. This material of the substrate can therefore be chosen from the materials already enumerated above, for example from metals or alloys such as stainless steel, polymers such as plastics or rubbers, among which mention may be made of PVC, PP, PE in particular HDPE, PMMA, PVDF, PC, glasses, cements, mortars and concretes, plaster, bricks, natural or artificial stone, plaster, ceramics. The treated surface can be painted or unpainted. In any case (see Example 2, and Figures 4 to 8 and 1 to 3), whatever the material, for example stainless steel, painted steel, lacquered, glass, ceramic, concrete, PVC, the cleaning efficiency according to the invention is total. There is also no limitation as to the shape, the geometry and the size of the surface to be cleaned, the gel according to the invention makes it possible to treat large surfaces of complex geometries, for example having depressions, angles, recesses. The gel according to the invention provides effective treatment not only of horizontal surfaces, but also of vertical surfaces such as walls, facades, bridge piles, doors, or inclined or overhanging surfaces such as ceilings. The gel according to the invention also guarantees a complete and efficient removal of graffiti whatever the paint, ink or other that constitutes these graffiti, whatever the color of these graffiti and whatever colorant or pigment they contain ( see Example 3). The gel according to the invention allows the effective removal of graffiti, tags, aerosol spray paint. The effectiveness of the gel according to the invention has been demonstrated on real graffiti on various substrates (Example 6, Figures 18 to 20). Compared to existing techniques which use liquids such as solutions, the invention uses a gel, which is particularly advantageous for the treatment of large surface materials, non-transportable and implanted outside. Indeed, the method according to the invention because of the implementation of a gel, allows cleaning in situ by avoiding the spread of chemical solutions in the environment and the dispersion of contaminating species.
[0041] The gel according to the invention can be applied to the surface to be treated by all the application methods known to those skilled in the art. Conventional methods are spraying, for example by spraying, or applying by means of a brush, or a trowel. For the spray application of the gel on the surface to be treated, the colloidal solution may for example be conveyed via a low pressure pump, for example a pump which uses a pressure of less than or equal to 7 bar, about 7,105 Pascals. The burst of the gel jet on the surface can be obtained for example by means of a jet nozzle or round jet.
[0042] The distance between the pump and the nozzle may be arbitrary, for example it may be from 1 to 50 m, in particular from 1 to 25 m. The sufficiently short viscosity recovery time of the gels used according to the invention allows the spray gels to adhere to all surfaces, for example to walls.
[0043] The amount of gel deposited on the surface to be treated is generally from 100 to 2000 g / m 2, preferably from 500 to 1500 g / m 2, more preferably from 600 to 1000 g / m 2. The amount of gel deposited per unit area and, consequently, the thickness of the deposited gel influences the rate of drying. Thus, when spraying a film, a layer of gel with a thickness of 0.5 mm to 2 mm on the surface to be treated, the drying time, which is then generally the effective contact time, is sufficient for a good surface treatment leading to graffiti removal. The effective contact time is the period during which the active principle contained in the gel which is other than the solvent (s) will interact with the graffiti.
[0044] The drying time is not only related to the thickness of the applied gel layer, but also to the climatic conditions, namely relative humidity and temperature. Those skilled in the art can easily determine, depending on the climatic conditions, and in the thickness range of 0.5 mm to 2 mm mentioned above, the thickness of the gel layer to be applied to the graffiti so that the gel is effective and graffiti is eliminated. So if one is at 20% relative humidity RH, and at 40 ° C, it is possible that the drying of a layer of gel of a thickness of 0.5 mm applied on a graffiti is too fast to allow effective removal of this graffiti. On the contrary, if one is at 15 ° C, and at 50% RH. Drying a layer of the same thickness of the same gel allows effective removal of this same graffiti. In addition, it has been surprisingly shown that the amount of gel deposited when it is in the ranges mentioned above and in particular when it is greater than 500 g / m2 and in particular in the range of 500 to 1500 g. / m2, which corresponds to a minimum thickness of deposited gel for example greater than 500 um for a deposited gel amount greater than 500 g / m2, allowed after drying of the gel to obtain fracturing of the gel in the form of millimetric flakes , for example of a size of 1 to 10 mm, preferably 2 to 5 mm aspirable.
[0045] The amount of gel deposited and therefore the deposited gel thickness, preferably greater than 500 g / m2 or 500 μm, is the fundamental parameter which influences the size of the dry residues formed after drying of the gel and which thus ensures that dry residues millimetric size and not powder residues are formed, such residues being easily removed by a mechanical process and preferably by suction.
[0046] However, it should also be noted that when the gel contains a low concentration surfactant, the drying of the gel is improved and leads to a homogeneous fracturing phenomenon with a size of the mono-dispersed dry residues and an increased ability of the residues dry to detach from the support. The gel is then held on the surface to be treated for the duration necessary for drying. During this drying step, which can be considered as constituting the active phase of the process according to the invention, the solvent (s) contained in the gel evaporates (s) up to obtaining a dry and solid residue. The drying time depends on the composition of the gel in the concentration ranges of its constituents given above, but also, as already mentioned, on the amount of gel deposited per unit area, that is to say the deposited gel thickness. The drying time also depends on the climatic conditions, namely the temperature, the ventilation and the relative humidity of the atmosphere in which the solid surface is located.
[0047] The process according to the invention can be carried out under extremely wide climatic conditions, namely at a temperature T of 1 ° C. to 50 ° C. and at a relative humidity RH of 20% to 80%. The drying time of the gel according to the invention is therefore generally from 15 minutes to 24 hours, preferably from 1 hour to 24 hours at a temperature T of 1 ° C. to 50 ° C. and at a relative humidity RH of 20% at 80%. It should be noted that the formulation of the gel used according to the invention, especially when it contains surfactants such as "Pluronics®", generally ensures (that is to say, in general, generally under reasonable climatic conditions, such as indicated above) a drying time which is substantially equivalent to the time of contact between the gel and the graffiti that is necessary, required to destroy, remove the graffiti polluting the material. In other words, the formulation of the gel ensures a drying time which is none other than the time necessary to eliminate, destroy the graffiti and which is compatible with the kinetics of destruction of graffiti and in particular with the kinetics of destruction of the graffiti. painting, ink or other that constitutes graffiti. After the drying of the gel, the gel fractures homogeneously to give millimetric solid dry residues, for example of a size of 1 to 10 mm, preferably 2 to 5 mm non-pulverulent, generally in the form of solid glitter. Dry and solid residues contain compounds resulting from the destruction of graffiti.
[0048] Dry residues, such as flakes, obtained after drying have a poor adhesion to the surface of the cleaned material. As a result, the dry residues obtained after drying of the gel can be easily recovered by simple brushing and / or aspiration. However, the dry residues can also be evacuated by gas jet, for example by compressed air jet. No rinsing is generally necessary and the process according to the invention does not generate any secondary effluent. However, a light rinse for example with water, treated surfaces, without mechanical action such as brushing may exceptionally be necessary to eventually remove residual traces of paint and low gel residues. According to the invention, thus first of all an important economy of chemical reagents is achieved with respect to a decontamination method by washing with a solution. Then, since a waste in the form of a directly aspirable dry residue is obtained, a rinsing operation with water or with a liquid is generally avoided. This obviously results in a decrease in the amount of effluents produced but also a significant simplification in terms of treatment and outlet channel. In particular, according to the invention, the waste obtained at the end of the treatment is not entrained in the rainwater drainage networks in violation of the regulations.
[0049] Because of the composition of the gel used according to the invention, the waste produced, once dry, represent only a small volume and are essentially mineral. They can therefore be stored or sent to an evacuation route without prior treatment. By way of example, in the current case where 1000 grams of gel are applied per m2 of treated surface, the mass of dry waste produced is less than 300 grams per square centimeter. The invention will now be described with reference to the following examples, given by way of illustration and not limitation. Examples.
[0050] The gels used in the following examples are gels composed of alumina and one or more organic solvents. This or these organic solvents constitute the active agent for pickling these gels. Alumina is Aeroxide® Alu C alumina marketed by EVONIK INDUSTRIES with a specific surface area of 100 m 2 / g (BET). The organic solvent (s) are chosen from the family of ketones and the family of esters and correspond to the formula (I) given above. Solvents of the gel formulations of the following examples are listed in Table I below.
[0051] Table I: Solvents used in the examples. Solvent CAS No. Chemical Formula 0 Ethyl Acetate 141-78-6 H3C 0 CH3 Ethyl Levulinate 539-88-8 H3C 0 0 0 H3 Acetyl Acetone 123-54-6 II 0 H3 Methyl Levulinate 624-45- 3 H3 C 0 0 OCH3 Methyl acetoacetate 105-45-3 OOCH3 Ethyl acetoacetate 141-97-9, OH ,, Dimethyl succinate 106-65-0 H3C0 0 OCH3 Diethyl malonate 105-53-3 0 ..-----. The gels according to the invention used in the examples which follow are prepared in the following manner: the solvent or solvents are mixed using a mechanical stirrer equipped with a three-blade stirrer; at a speed of 200 rotations / min, for 3 to 5 minutes. The alumina, in a proportion of 7% to 11% by weight according to the gels, is then gradually added to the reaction mixture, gradually increasing the stirring speed as the viscosity increases, to reach about 400. at 600 rpm without projections. The gel is then stirred for 5 minutes. The gels thus prepared are then tested on different types of graffiti, "tags", found on different materials, by applying them with a spatula or using a sprayer. The applied gel thickness is 0.5 to 2 mm depending on the means of application used. In all cases, the tested gel dries, fractures by absorbing paint from graffiti, and thus forms flakes that can then be brushed.
[0052] The drying time of the gels varies depending on the solvent or solvent mixture used. This drying time can range from 15 minutes for ethyl acetate to 48 hours for ethyl levulinate. A slight wet brushing is necessary in some cases to remove paint residue from graffiti that is not trapped in dry gel flakes.
[0053] EXAMPLE 1 In this example, the effectiveness of a gel according to the invention whose active agent is a mixture of ethyl acetate and diethyl malonate is evaluated to eliminate a graffiti, "tag" deposited on a support in a simple material, namely lacquered painted steel.
[0054] The gel used in this example is a mixture of alumina (10% by weight) and an active agent which is a mixture of solvents (80:20 by weight of ethyl acetate: diethyl malonate) (90% by mass). This gel is manufactured according to the protocol described above. This gel is the reference gel and will be used in the following in many other examples.
[0055] The effectiveness of the gel in the removal of graffiti is shown using photographs but also by establishing a profile of the support using an optical profilometer. The test intended to show the effectiveness of the gel is carried out according to the following protocol: A coupon, plate, lacquered painted steel is covered - about two thirds of its surface, located on the right - of a graffiti, "tag In black paint from a tag bomb from a major graffiti paint manufacturer, MOLOTOW® Ultra-Cover Black CoversAll2TM Outline Black. Once well covered with paint, the plate is left under fume hood for drying for 24h. The gel is then applied to the spatula on the third of the surface of the rightmost plate with a thickness of 0.5-2 mm. Following the complete drying of the gel, the dry gel flakes are brushed and the plate is briefly rinsed in order to be able to perform an image analysis (gray level) using a software (ImageJ), as well as a measurement to the profilometer. It is a profilometer manufactured by the company STIL (Industrial Sciences and Techniques of Light) which is used to draw roughness profiles and measure the average roughness on different parts. The surface of the tagged painted steel plate is divided into three parts, namely from left to right: a virgin first part where neither tag nor gel has been deposited, a second part where the "tag" has been applied, but was not treated with the gel, a third part where the gel was applied to the tag then the dry gel flakes brushed.
[0056] The results are shown in FIGS. 1, 2 and 3. It appears in the final photograph (FIG. 1) as well as on the gray level profile obtained from this photograph along the light line A in FIG. that the black paint of the tag was successfully removed on the right side of the gel-treated plate.
[0057] We can thus find the same level of gray on the part "detagée" by the frost on the right, than on the left untouched part on the left (Figure 2). To confirm this result, a roughness profile drawn from left to right of the plate (Figure 3) shows an increase in thickness and an increase in roughness of the passage from the virgin zone to the painted zone, then a loss of thickness and roughness when passing over the "unconged" area, proving the elimination of the paint thickness of the tag. Example 2
[0058] In this example, the effectiveness of the reference gel of Example 1 according to the invention is evaluated to eliminate graffiti on different types of materials, namely stainless steel, painted steel (see Example 1, Figures 1 to 3), glass, ceramics, concrete, and a plastic material: PVC. As in Example 1, plates in each of these materials are provided with a graffiti, "tag" in a black paint from a tag bomb of a major manufacturer of graffiti paints, namely the MOLOTOW paint ® Ultra-Black Cover CoversAll2TM Outline Black. The tests are carried out according to the same test protocol as that used in Example 1.
[0059] The results for stainless steel plates, glass, ceramic, concrete, and a plastic material: PVC are shown respectively in Figures 4 to 8. The results for the painted steel plate are shown in Example 1 and Figures 1 to 3. It appears that on all simple materials, non-porous, the gel effectively eliminates the tag where it is applied, that is to say on the right half of the support. For porous surfaces such as concrete, the elimination is slightly less clear but can be improved by the application of a second layer of gel or by a greater thickness. That is, after removal of flakes from the first gel layer, a second gel layer is applied. In other words, a second pass is made.
[0060] Example 3. In this example, the effectiveness of the reference gel of Example 1 according to the invention is shown to eliminate graffiti in three different commercially available paints, made on lacquered painted steel coupons. These three paints are: the ultra-covering black Molotow® paint described in Example 1; a paint from a spray of pink paint Molotow® Premium Mad C psycho pink, a paint from a neon red Luxens® paint spray. The tests are carried out according to the same test protocol as that used in Example 1. Photographs are taken at the various stages of the process and show the tagged support, the application of the gel, the totally dry gel, the elimination straws by brushing, and finally the state of the support after a light rinse of all the support. It appears that whatever the paint used for the "tag", the part treated by the gel is returned to its original appearance after the light rinse. It should be noted that the rinsing has no effect on the untreated gel paint and is ultimately only necessary to eliminate the paint of the black tag which is more persistent than the other two pink and fluorescent red paints. Example 4: In this example, the effectiveness of eight gels according to the invention, which each contain a different solvent, active agent, to eliminate a graffiti, "tag" deposited on lacquered painted steel coupons. The graffiti, "tag" is a black paint from a tag bomb, namely the MOLOTOW® ultra-black CoversAll2TM Outline Black paint (see example 1). The gels used in this example are mixtures of alumina (10% by weight) and one of the solvents, active agents appearing in Table I above (90% by mass).
[0061] These gels are manufactured according to the protocol described above. The tests are carried out according to the same test protocol as that used in Example 1. The results are shown in Figures 9 to 16.
[0062] It should be noted that the drying times observed can vary greatly depending on the conditions of use of the gel (temperature, thickness of the gel, ventilation ...). The drying times indicated here have all been observed under the same conditions and thus make it possible to compare the gels with each other. Photographs have been taken which show the condition of the coupon whose right side was treated by the gel in question after the removal of the gel flakes without rinsing. From these photographs, the corresponding gray level profiles have been established (Figures 9 to 16). It appears that these solvents are relatively effective on this type of paint, some drying more or less quickly and the gels are more or less effective.
[0063] More specifically: - the gel containing ethyl acetate dries very quickly (15-20 min) but still retains excellent pickling efficiency (very few paint residues which more eliminate by simple rinsing). the gel containing ethyl levulinate dries very slowly (2 to 3 days), but this prolonged contact time does not confer a greater pickling efficiency on this gel. - The gel containing acetyl acetone dries over a periodically optimal for the aspirable gesl, or 2 to 3 hours, and has a relatively good stripping power. the gel containing methyl levulinate has a classic drying time (2-3h) and its cleaning power is particularly good, this gel leaves little paint residue which is eliminated by rinsing with water. In addition, this solvent does not emit too strong odor and does not present health risks since it is used in the food industry. On the other hand, its price per liter remains unattractive. - The gel containing methyl acetoacetate is very inefficient because its stripping power is very low despite a contact time (drying) extended from 2 to 3 days. the gel containing ethyl acetoacetate has a drying time of 2- 3 days and is relatively effective under the experimental conditions used for these tests. the gel containing dimethyl succinate has a conventional drying time, ie 2 to 3 hours, and its pickling power is relatively good, despite the residues of paint appearing between the flakes of dry gel. the gel containing diethyl malonate has a drying time of about 24 hours and its pickling power is relatively good, despite paint residues appearing between the flakes of dry gel. Example 5
[0064] In this example, it evaluates the effectiveness of a gel according to the invention, containing as active agent another solvent mixture than that of the gel of Example 1, to remove graffiti. Indeed, it may be wise to use, in the gels according to the invention, mixtures of solvents as an active pickling agent to lengthen the gel drying time and thus increase its pickling efficiency, to limit the solvent attack on plastics or to reduce the overall toxicity of the gel. Thus, the reference gel of Example 1 was formulated with a mixture of ethyl acetate and diethyl malonate, in fact: an ethyl acetate gel alone is very effective in removing the paint but it dries much too fast (drying time about 15 to 30 minutes, see Example 4), without other solvents, especially on the porous materials, and it is therefore ultimately less effective, a diethyl malonate gel alone dries very slowly ( in about 24 hours, see Example 4) but it is less effective than the gelled ethyl acetate.
[0065] The mixture of these two solvents thus makes it possible to obtain a gel with a reasonable drying time, namely from 1 to 4 hours, and effective. A gel containing another solvent mixture was therefore prepared to evaluate its effectiveness for removing graffiti.
[0066] This gel is a mixture of alumina (10% by weight) and an active agent which is a mixture of solvents (80:20 by weight of ethyl acetate: methyl acetoacetate) (90% by mass). This gel was manufactured according to the protocol described above. This gel is used to remove a graffiti, "tag" deposited on lacquered painted steel coupons. The graffiti, "tag" is a black paint from a tag bomb, namely the MOLOTOW® ultra-black CoversAll2TM Outline Black paint (see example 1). The tests are carried out according to the same test protocol as that used in Example 1. The results concerning the gel which is a mixture of alumina (10% by weight) and an active agent which is a mixture of solvents ( 80:20 mass ethyl acetate: methyl acetoacetate) (90 wt%) are shown in Figure 17. The results for the reference gel of Example 1 are shown in Figures 1 to 3. It is clear that the active mixture tested in Example 1 (FIGS. 3) is better than that tested in this example since the tag is removed more efficiently with the solvent combination of the gel of Example 1 than with that of this example 5. Example 6. In this example, the anti-graffiti gels according to the invention are used under real conditions, that is to say that the effectiveness of gels according to the invention is evaluated. to eliminate real, unmasked graffiti actually present on buildings, in stallations or structures. Two tests in real conditions were thus carried out. The first test was performed on graffiti, "tags", present on a lacquered steel electrical transformer and on a concrete bridge stack.
[0067] The gel tested for the removal of these graffiti is a gel whose solvent, active agent is acetylacetone (89% by weight) in which was incorporated alumina (11% by mass). This gel was manufactured according to the protocol described above.
[0068] The gel was applied with a spatula on different tags of different colors and different textures of paint. The results of this first field trial are shown in Figures 18A and 18B (transformer) and Figures 19A and 19B (bridge stack). It appears that the gel has a relatively effective action on these graffiti, "tags", either on the lacquered steel of the transformer (Figures 18A and 18B) or on the concrete of the bridge stack. However, the gel having been tested on very small surfaces with a lot of wind (90km / h), and the solvent being moreover very volatile, the duration of action of the gel was relatively reduced (15 to 30 minutes maximum) and its effectiveness less blatant than in the second test carried out.
[0069] The second test was carried out with the reference gel described in Example 1 which has a longer drying time and is therefore more suitable for real outdoor trials. The gel was sprayed on buildings tagged with a Wagner® paint sprayer (W670 electric gun). The targets were graffiti on a painted steel door (unglazed). After removing the dry gel flakes with an industrial vacuum cleaner, a light rinsing of the treated surfaces without brushing was carried out to remove the residual traces of paint. The results of this second test are shown in Figures 20A and 20B.

权利要求:
Claims (21)
[0001]
REVENDICATIONS1. Gel for removing a graffiti on a surface of a solid substrate, constituted by a colloidal solution comprising, preferably consisting of: - 0.1% to 30% by weight, preferably 0.1% to 25% by weight, of more preferably 5% to 25% by weight, more preferably 8% to 20% by weight, for example 10% by weight, based on the total weight of the gel, of at least one inorganic viscosifying agent; 70% to 99.9% by weight, preferably 75% to 99.9% by weight, more preferably 75% to 95% by weight, for example 90% by weight, of one or more solvent (s) chosen (s) from alkyl acetates (linear or branched alkyl group of 1 to 10C) such as ethyl acetate, and compounds of formula (I): (I) wherein R and R ', identical or each independently represents a linear or branched alkyl group of 1 to 10 C such as a methyl, ethyl, propyl, or isopropyl group, or a linear or branched alkoxy group of 1 to 10 C such as a group, methoxy, ethoxy , propoxy, or isopropoxy, and n is 1, 2, or 3; optionally, 0.1% to 2% by weight, based on the total weight of the gel, of at least one surfactant; and optionally, from 0.01% to 10% by weight, relative to the mass of the gel, of at least one dye and / or pigment.
[0002]
2. The gel of claim 1, wherein the (s) solvent (s) is (are) chosen from ethyl acetate, ethyl levulinate, acetyl acetone, methyl levulinate, acetoacetate. methyl, ethyl acetoacetate, dimethyl succinate, diethyl malonate, and mixtures thereof.
[0003]
3. Gel according to claim 2, in which the gel comprises a mixture of ethyl acetate and of diethyl malonate or of methyl acetoacetate, preferably in proportions by weight of 20% to 99%, preferably 50% to 99%, for example 80% ethyl acetate, and 1% to 80%, preferably 1% to 50%, for example 20% diethyl malonate or methyl acetoacetate.
[0004]
4. Gel according to any one of the preceding claims, wherein the inorganic viscosifying agent is chosen from metal oxides such as aluminas, metalloid oxides such as silicas, metal hydroxides, metalloid hydroxides, metal oxyhydroxides, metalloid oxyhydroxides, aluminosilicates, clays such as smectite, and mixtures thereof.
[0005]
5. Gel according to claim 4, wherein the inorganic viscosifying agent is selected from pyrogenic silicas, precipitated silicas, hydrophilic silicas, hydrophobic silicas, acidic silicas, basic silicas, and mixtures thereof.
[0006]
6. Gel according to claim 4, wherein the inorganic viscosifying agent consists of one or more alumina (s).
[0007]
7. Gel according to claim 6, wherein the alumina (s) represent 5% to 30% by weight, preferably 7% to 15% by weight relative to the total mass of the gel.
[0008]
8. Gel according to any one of the preceding claims, wherein the surfactant is selected from nonionic surfactants such as block copolymers, such as block copolymers of ethylene oxide and propylene oxide, and ethoxylated fatty acids; and their mixtures.
[0009]
9. Gel according to any one of the preceding claims, which comprises at least one inorganic pigment, preferably said mineral pigment is present in a proportion of 0.01% by weight to 10%, preferably 0.1% by weight to 5% by weight of the total mass of the gel.
[0010]
10. A method for removing a graffiti on a surface of a solid substrate, wherein at least one cycle is carried out comprising the following successive steps: a) the gel according to any one of claims 1 to 9 is applied to said surface; ; b) the gel is maintained on the surface for at least sufficient time for the gel to remove graffiti, and for the gel to dry and form a dry, solid, non-powdery residue containing compounds resulting from the removal of graffiti; c) removing the dry and solid residue containing the compounds resulting from the removal of graffiti.
[0011]
The method of claim 10, wherein the substrate is a porous substrate, preferably a porous mineral substrate.
[0012]
The method of any of claims 10 and 11, wherein the substrate is at least one material selected from metals and alloys such as stainless steel, galvanized steel, or zinc; painted steels; organic polymers such as plastics or rubbers such as polyvinyl chloride or PVC, polypropylenes or PPs, polyethylenes or PEs, in particular high density polyethylenes or HDPEs, poly (methyl methacrylates) or PMMA, polyvinylidene fluoride or PVDF, polycarbonates or PCs; the glasses ; cementitious materials such as pastes, cements, mortars and concretes; plasters; the bricks ; tiles ; raw or cooked earth; natural or artificial stones; coatings; fiberglass, fiber cement; asphalt; tar ; slate; cellulose-based materials such as wood; and ceramics.30
[0013]
13. A method according to any one of claims 10 to 12, wherein the graffiti comprises a paint including an aerosol spray paint, an ink, or a mixture thereof.
[0014]
14. A process according to any one of claims 10 to 13, wherein the gel is applied to the surface at a rate of 100 g to 2000 g of gel per m2 of surface, preferably from 500 g to 1500 g of gel per m2de surface, more preferably from 600 g to 1000 g of gel per m 2 of surface.
[0015]
The method of any one of claims 10 to 14, wherein the gel is applied to the surface of the solid substrate by spraying, brushing, or with a trowel.
[0016]
16. A method according to any one of claims 10 to 15, wherein in step b), the drying is carried out at a temperature of 1 ° C to 50 ° C, preferably 15 ° C to 25 ° C and at a relative humidity of 20% to 80%, preferably 20% to 70%.
[0017]
The method of any one of claims 10 to 16, wherein the gel is held on the surface for a period of 30 minutes to 72 hours, preferably 1 to 48 hours, more preferably 1 to 24 hours, better from 1 to 5 hours, for example from 1 to 4 hours.
[0018]
18. Process according to any one of claims 10 to 17, in which the dry and solid residue is in the form of particles, for example flakes, of a size of 1 to 10 mm, preferably of 2 to 5 mm. mm.
[0019]
The method of any one of claims 10 to 18, wherein the dry and solid residue is removed from the solid surface by brushing and / or aspirating.
[0020]
The method of any one of claims 10 to 19, wherein the cycle is repeated from 1 to 10 times using the same gel in all cycles or using different gels in one or more cycles ( s).
[0021]
21. Process according to any one of claims 10 to 20, wherein during step b), the gel, before total drying, is rewetted with a solvent, preferably with the solvent of the gel applied during the step at).

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同族专利:

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公开号 | 公开日

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US10376931B2|2019-08-13|

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WO2016059125A1|2016-04-21|

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FR3027310B1|2017-12-15|

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US20170239694A1|2017-08-24|

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EP3206780B1|2020-10-07|

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ES2842113T3|2021-07-12|

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EP3206780A1|2017-08-23|

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FR3027310B1|2014-10-15|2017-12-15|Commissariat Energie Atomique|GEL FOR REMOVING GRAFFITI AND METHOD FOR REMOVING GRAFFITIS USING THE GEL.|FR3027310B1|2014-10-15|2017-12-15|Commissariat Energie Atomique|GEL FOR REMOVING GRAFFITI AND METHOD FOR REMOVING GRAFFITIS USING THE GEL.|

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法律状态:
2015-11-02| PLFP| Fee payment|Year of fee payment: 2 |

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2016-04-22| PLSC| Publication of the preliminary search report|Effective date: 20160422 |

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2016-10-28| PLFP| Fee payment|Year of fee payment: 3 |

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2017-10-31| PLFP| Fee payment|Year of fee payment: 4 |

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2018-10-30| PLFP| Fee payment|Year of fee payment: 5 |

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2019-10-31| PLFP| Fee payment|Year of fee payment: 6 |

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2020-10-30| PLFP| Fee payment|Year of fee payment: 7 |

优先权:

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申请号 | 申请日 | 专利标题

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FR1459884A|FR3027310B1|2014-10-15|2014-10-15|GEL FOR REMOVING GRAFFITI AND METHOD FOR REMOVING GRAFFITIS USING THE GEL.|FR1459884A| FR3027310B1|2014-10-15|2014-10-15|GEL FOR REMOVING GRAFFITI AND METHOD FOR REMOVING GRAFFITIS USING THE GEL.|

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PCT/EP2015/073807| WO2016059125A1|2014-10-15|2015-10-14|Gel for removing graffiti and method for removing graffiti using said gel|

---

EP15790850.0A| EP3206780B1|2014-10-15|2015-10-14|Gel to eliminate graffitis and process to eliminate graffitis using this gel|

---

US15/518,891| US10376931B2|2014-10-15|2015-10-14|Gel for removing graffiti and method for removing graffiti using said gel|

---

ES15790850T| ES2842113T3|2014-10-15|2015-10-14|Gel to remove graffiti and procedure to remove graffiti using this gel|