FR2949794A1 - Removable horizontal marking product, preferably road marking, useful to make special markings e.g. arrows, comprises bilayer to apply on surface area to be marked preferably of the road coating and a second upper layer of marking product - Google Patents

Abstract

Removable horizontal marking product (I), preferably road marking, comprises a bilayer for applying on the surface area to be marked preferably of the road coating, where the bilayer is formed by a first base layer containing an organic binder, a reactive filler having volume expansion triggered by high temperatures and a ferromagnetic filler adapted to be heated by exposure to electromagnetic radiation, and a second upper layer of marking product. An independent claim is included for process for implementing road marking product, comprising applying, on the ground, the first base layer, then after drying the latter the second upper layer of marking material, while eliminating that product, heating without contacting by electromagnetic induction of the product and producing the destruction of the internal cohesion of the base layer followed by separating two layers of marking by the product.

Description

Customizable marking product, in particular road marking, and its method of implementation

The present invention generally relates to a marking product, in particular horizontal marking of all types of floors and more particularly road marking, which is removable on command. According to the general concept of the present invention, the marking product is applied in two layers, a base layer whose controlled degradation is activatable by a specific action without contact, in particular a heating action, and an upper layer of product of marking, in particular certified road marking. In the field of road marking, the elimination of existing signage is a problem well identified by dealers and road network managers. The difficulty of eliminating marking in place concerns both temporary signage and permanent signage. Two methods of disposal are known and used by those skilled in the art. Elimination by mechanical action type high-pressure pickling, hydrodécapage, micro-planing. Specific mechanical machines have been developed as described in patent application JP 4315602. It involves physically removing the marking product layer by spraying water under pressure, shot or by micro-abrasion. The degradation of the labeling product can also be achieved by burning. The application of a bright flame causes the pyrolysis of the marking product. The calcined residues are then swept. This method, in addition to being very expensive in energy, leads to releases of uncontrolled fumes into the atmosphere. These two methods have the major disadvantage of degrading the surface of the roadway on which road marking is applied. Indeed, after treatment, there is a very visible alteration of the surface of the coating.

Another technique is to hide the marking in place by applying black paint. During the course of time and under the effect of road traffic, this masking paint deteriorates allowing the underlying marking to reappear. The result is a set of lines, confusing to interpret for the user. To compensate for the superficial degradation of the roadway, specific road marking products with the ability to be peeled off after use have been developed. By way of example, mention may be made of: Glued preformed signal strips (US Pat. No. 5,437,907, European Patent EP 0 037 211, EP 0 162 229). These systems have the disadvantage of their fixed geometrical shape which makes them unsuitable for the marking of discontinuous lines or specific marks type of drawdown arrows or dots of great width. They are reserved for temporary marking with continuous lines. Patent No. NL 1004432 which proposes a multilayer system incorporating a reinforced weft with surface loops. The marking is withdrawn by pulling the loops on the surface which causes the separation of the weft. This method using a fabric weft is poorly suited to the realization of discontinuous marking. Non-voluntary detachments are also likely to occur when a vehicle is hooking a surface loop.

Patent EP 0 905 322 relating to a removable ground signaling device for vehicle taxiways. It is a mechanical device only adapted to the delimitation of continuous lane. This material creates a physical barrier that prevents crossing or crossing users.35 Patent No. AU 200071927 refers to an erasable marking product. This product is suitable for marking ground or grass marking for sports fields. The elimination of the product is obtained by the application of an alkaline solution diluted on the surface. In general, the surface of road markings is covered with glass beads to ensure regulatory retroreflective levels, which prevents these types of disposal methods from operating.

With respect to all of the above solutions, the present invention has the advantage of adapting to any type of marking, whatever its shape (continuous or discontinuous) and its duration (temporary or permanent), and of which elimination is strictly controlled by a specific action. The invention can be applied to any type of support without restriction. These include bituminous concretes, asphalts, cement concretes, wooden or metal supports, natural or reconstituted stones, resin-type synthetic materials.

Moreover, in the field of structural adhesives and adhesives, several dismountable assembly techniques have been developed in an industrial environment. The proposed solutions consist in integrating thermal expansion charges directly in the glue joint or in the adhesion primer of the pyrotechnic products. Examples which may be mentioned are EP 1 185 594 and US Pat. No. 6,172,141. All of these solutions are suitable for bonding substrates at least one of which is metallic in stationary industrial installations. The heat input is either direct by a radiating source, or indirectly by electromagnetic heating of a bonded substrates. The metal substrate absorbs the heat transferred by the electromagnetic field and diffuses this supply of thermal energy at the glue joint, causing its degradation.

These methods of direct and indirect heating are not adapted to the problem of road markings. Indeed, the direct heating is prevented by the presence of glass beads on the surface of the marking. These balls create a heat shield blocking the flow of heat necessary for the degradation of the bonding. Indirect heating through one of the substrates does not work, the roadway substrate supporting the road marking being insensitive to electromagnetic radiation. It does not allow the diffusion of heat towards the marking product. The present invention solves this problem by coupling in the base layer the degradation function by incorporating a reactive charge and the contactless heating function by the incorporation of a specific charge sensitive to electromagnetic radiation. The present invention relates to a horizontal marking product, in particular to road marking, which can be dismantled, consisting of a bilayer to be applied to the surface surface of the road surface layer, this bilayer consisting of a first base layer containing an organic binder, a reactive charge with volumetric expansion triggered by temperature rise and a ferromagnetic charge able to be heated by exposure to electromagnetic radiation, and by a second upper layer of marking product. According to an additional characteristic of the invention, the second upper layer of marking product comprises at least one organic binder, fillers, pigments and / or glass beads or other retro-reflective particles. According to an advantageous characteristic of the invention, the organic binder of the first and / or second layer is a polymeric binder chosen from the families of synthetic resins such as acrylic resins, acrylic styrene, latex, polyurethane, epoxy and alkyd resins. among resins of plant or animal origin such as rosin derivatives, starch derivatives. Preferably, the binder present in the first layer will be of the same nature as that of the second layer to give more consistency to the entire bilayer product marking.

According to another characteristic of the invention, the volume-expansion reactive filler consists of microspheres containing a fluid, in particular isobutane, isopentane or a mixture of these two gases. According to another characteristic of the invention, the microspheres consist of thermoplastic spherical capsules having a mean particle size at rest of the order of 15 μm. According to an advantageous characteristic of the invention, the spherical thermoplastic capsules are made of PVDC, acrylonitrile resin or methacrylonitrile. According to another characteristic of the invention, the ferromagnetic charge is constituted by metal particles, ceramics or nanoscale silicas capable of causing Joule heating in their conductive mass.

According to an advantageous characteristic of the invention, said particles are ferrites in particular of formula MO, Fe 2 O 3 where M represents a divalent metal such as nickel, magnesium, manganese and zinc. According to another characteristic of the invention, the first base layer has a thickness of between 50 μm and 1000 μm. According to another characteristic of the invention, the second upper layer has a thickness of between 0.3 mm and 3 mm. According to a particular embodiment of the invention, the first base layer has the following weight composition: Binder 10 - 40% Expanding filler 10 - 50% Ferrite 5% - 30% Mineral filler 15 - 40% Other additives 0% - 5% 0 Black pigment 0% - 10% water 1% - 10% According to another characteristic of the invention, the first base layer has the following composition by weight: Binder 20 - 25% Expanding load 20 - 40% Ferrite 10 - 20% Mineral filler 20 - 40% Other additives 2% - 5% 2% 0 Black pigment 2,5 - 10% water 2,5 - 10% The present invention also relates to a process for the introduction of a customizable road marking product according to the invention, according to which a first base layer is successively applied to the ground, and after drying of the latter a second upper layer of marking product, and when it is desired to eliminate said marking product is heated without act by electromagnetic induction of said product, leading to the destruction of the internal cohesion of the base layer followed by detachment of the two product marking layers. According to another characteristic of the process according to the invention, after detachment of the two layers of the marking product, the said marking product 20 is removed by brushing, sweeping and / or suctioning. According to another characteristic of the process according to the invention, the invention, the application of the first base layer and the second upper layer of the marking product is carried out by brush, by spraying under air pressure or by "airless" type spraying. According to another characteristic of the method according to the invention, the non-contact heating by electromagnetic induction of the marking product to be eliminated is carried out by means of an induction heating device having a power of between 10 kW and 100 kW and a frequency between 50 kHz and 500 kHz, said device being embedded on a mobile platform with adjustable forward speed. According to another characteristic of the invention, the induction heating device comprises an inductor disposed at the free end of an arm articulated on said mobile platform so as to be positioned at an adjustable height of between 1 mm and 10 mm at the above the surface of the marking product to be eliminated.

The first layer of the system combines a polymeric binder selected from the families of synthetic resins including acrylic compounds, styrene acrylic, latex, polyurethane, epoxy, alkyd, a reactive charge that generates an increase in volume under the effect of an increase temperature and a load sensitive to heating by electromagnetic radiation type induction. The formulation of this base layer comprises at least these three elements dispersed in an organic solvent or an aqueous phase. The dry extract of this base layer will be between 10% and 90%. The thickness of this layer will be between 50 microns and 1000 microns. The application is carried out according to conventional means known to those skilled in the art, these including in particular the brush application, the air pressure spraying and the airless type spray.

In the formulation of this base layer, the percentage of polymer binder will be between 10% and 50% of the dry extract of the formulation. The choice of its chemical nature will be adapted according to the marking product applied in the second layer to ensure a high performance bonding. The polymeric binder will be selected from acrylic binders, styrene acrylic, latex, polyurethane, epoxy, alkyd. The reactive load is selected from the family of products undergoing a substantial increase in volume under the effect of a rise in temperature. By way of example, mention may be made of thermal expansion microballoons. These microballoons consist of a polymer wall containing a volatile liquid. A rise in temperature above the boiling point of the liquid leads to its vaporization. The volume of these microballoons then increases considerably. The boiling temperature causing the increase in volume is generally between 80 ° C and 180 ° C. The mass percentage of this reactive filler will be between 5% and 50% of the dry extract of the formulation of the base layer.

The charge sensitive to induction heating is chosen from metal materials, for example ferrite type, inorganic compounds sensitive to electromagnetic radiation, for example ceramic type, silica of nanometric size. This charge is intended to convert the electromagnetic radiation into heat and diffuse this heat to ensure the temperature rise of the base layer under the effect of the passage of the induction heating system. The size of the load is chosen to be sensitive to electromagnetic fields of frequency within a frequency range of 50 kHz to 500 kHz. The percentage of this filler is between 2% and 50% of the dry extract of the formulation of the base layer. In addition to these three elements, the base layer may also contain filler materials chosen from mineral fillers known to those skilled in the art, such as calcium carbonate, barium sulfate, talc, silica, and the like. as pigments and additives necessary for the formulation of this type of product among which at least one dispersant, a wetting agent, a thickener or a coalescent.

The second upper layer according to the invention is in particular a traditional road marking product, applied according to the rules of the art to meet the various contractual specifications. The second upper layer of this horizontal marking product in particular, urban road or highway marking, is carried out in a manner known per se. Of course, this type of marking can be applied more generally to all types of industrial floors, indoor or outdoor and it can be as well surfaces for the road traffic of vehicles or cycles, as pedestrian surfaces intended more particularly to urban applications. The product of the second top layer may consist of a conventional road paint, generally consisting of an organic binder as well as various fillers, pigments and other additives such as glass beads. Of course, such a paint frequently contains appropriate solvents. Among the most frequently encountered resins, mention will be made of epoxy resins, alkyd resins and acrylic resins. This second upper layer may also be made in the form of a cold coating that does not involve a solvent, but consists of a pair involving a base, usually a methacrylic resin and a hardener, of the peroxide type. This second upper layer of marking product may also be constituted by a thermoplastic coating of the traditional road marking product type which is applied under heat. Such a top layer of marking product may also contain, in a conventional manner, non-slip granules in suspension. in said product or deposited by dusting. It is the same for any glass microbeads or other reflective particles incorporated in such a type of traditional road marking, to make them more visible at night. It will be noted simply that in visible night markings in rainy weather (VNTP), the glass particles present in said marking generally have a larger particle size. Finally, the marking product may be a preformed product in the form of a sheet of ready-to-use material. This type of marking is generally used, whether permanent or temporary, to make special markings (zebras, arrows, or the like). It may especially be materials cut into symbol shapes or parts of symbols that are deposited and assembled on the road to obtain the desired shape. Similarly, the marking product may also be in the form of sound strips which correspond to a product emitting a noise perceptible by the user when he rolls on said marking. This type of product is conventionally used, for example, in areas where the emergency stop strips are narrow or non-existent, or in the case of dangerous shoulders so as to indicate to the user that he is leaving his rolling corridor. In order to ensure good cohesion of the marking product according to the invention, those skilled in the art will choose components of each of the base and marking layers that are compatible with each other. Preferably, this compatibility will be sought at the level of the organic binder present both in the first base layer and in the second upper layer of marking product. According to a preferred embodiment of the marking product according to the invention, these two organic binders will be identical in nature so as to ensure, as a result of a migration at the interface of the two layers, a true reinforced bond ensuring a perfect cohesion of the two layers. The heating system is of the induction heating type with a power between 10 kW and 100 kW and a frequency between 50 kHz and 500 kHz. The power / frequency torque is tuned to obtain the fastest rise in temperature at the base layer. The heating system is installed on a mobile platform whose forward speed is between 0 km / h and 10 km / h.

The heating system is self-sufficient in energy thanks to the presence of a generator built into the platform and whose power is adapted to the consumption of the inductive heating system. The power of the group is between 10 kVA and 200 kVA. The inductor, held by an articulated arm, is positioned at a height between 1 mm and 10 mm from the surface of the marking product to be eliminated. After use, the elimination of the marking product is obtained in two steps: The first step consists in heating without contact the base layer by switching to controlled speed of the induction heating system. The increase in temperature is instantaneous and localized only at the level of the base layer. Once the temperature exceeds the microballoon expansion threshold temperature, the reactive charge undergoes an irreversible volume increase which destroys the internal cohesion of the base layer. This loss of cohesion causes the separation of the two layers. The second step proceeds from a physical removal of the entire marking product by a mechanical action of cleaning type brushing, sweeping, suction. After brushing, all the marking product is removed without any alteration of the surface layer of the roadway. EXAMPLE By way of example, the formulation of the base layer is established as follows: Acrylic phase aqueous binder, Fastrack E2706, Rohm and Haas: 22% by weight Reactive microballoon type charge, Expancell 551WU80, Expancell: 28% by weight Inductive heating load, ferrite size 500 microns: 15% by weight Feedstock, CaCO3, Durcal 40, Omya: 23% by weight Additives: 2% by weight Black pigment, Aquiss Black 070: 5% by weight Water: 5% by weight This base layer is applied by pneumatic spraying on a bituminous concrete type substrate at a dosage of 150 g / m 2. The second layer consists of a certified marking product, in the aqueous phase of the acrylic paint type. This product is composed of an acrylic binder, fillers, pigments and formulation additives. A layer of 400g / m2 was applied and then surface-blasted, as recommended in the rules of art. After drying, the traffic resistance of the assembly was verified by a traffic simulator test at a temperature of 30 ° C. The axle load was set at 13 tonnes. After 50,000 wheel arches, no degradation or departure of materials was observed. After the traffic simulator test, the support covered with the marking products was passed through an induction heating system. The frequency of the generator is set at 145 kHz, the power at 45 kW. The distance between the inductor and the marking is fixed at 3 mm. As the inductor passes, the base layer degrades instantly, which results in swelling and loss of cohesion of this layer.

After passing the heating system, the marking is completely eliminated by manual brushing. No residual traces are visible. The surface of the asphalt concrete substrate has not undergone any visible degradation.

Claims (18)

REVENDICATIONS1. Horizontal marking product, in particular road marking, which can be dismantled, consisting of a bilayer to be applied to the surface surface to be marked, in particular of the road surface layer, this bilayer consisting of a first base layer containing an organic binder, a filler reactive volume expansion triggered by temperature rise and a ferromagnetic charge capable of being heated by exposure to electromagnetic radiation, and by a second upper layer of marking product. Marking product according to claim 1, characterized in that the second upper layer of marking product comprises at least one organic binder, fillers, pigments and / or glass beads or other retro-reflective particles. 3. Marking product according to one of claims 1 and 2, characterized in that the organic binder of the first and / or second layer is a polymeric binder chosen from the families of synthetic resins such as acrylic resins, styrene acrylic, latex, polyurethane, epoxy and alkyd or among resins of plant or animal origin such as derivatives of rosin, starch derivatives. 4. Marking product according to one of the preceding claims, characterized in that the reactive charge volume expansion is constituted by microspheres containing a fluid. 5. Marking product according to claim 4, characterized in that the microspheres are constituted by spherical thermoplastic capsules having a mean particle size at rest of the order of 15 pm. 6. Marking product according to one of claims 4 and 5, characterized in that the spherical thermoplastic capsules are made of PVDC, acrylonitrile resin or methacrylonitrile. 7. Marking product according to claim 4, characterized in that the fluid contained in said capsules is isobutane, isopentane or a mixture of these two gases. 8. Marking product according to one of the preceding claims, characterized in that the ferromagnetic charge is constituted by metal particles, ceramics or nanoscale silicas capable of causing a joule effect heating in their conductive mass. 9. Marking product according to claim 8, characterized in that said particles are ferrites in particular of formula MO, Fe203 where M represents a divalent metal such as nickel, magnesium, manganese and zinc. 10. Marking product according to one of the preceding claims, characterized in that the first base layer has a thickness between 50 pm and 1000 pm. 11. Marking product according to one of the preceding claims, characterized in that the second upper layer has a thickness of between 0.3 mm and 3 mm. 12. Marking product according to one of the preceding claims, characterized in that the first base layer has the following composition by weight: Binder Expanding load Ferrite Mineral filler Other additives Pigment black water 10 - 40% 10 - 50% 5% - 30% 15 - 40% 0% - 5% 0 0% - 10% 1% - 10% 13. Marking product according to one of the preceding claims, characterized in that the first base layer has the following composition by weight: Binder 20 - 25% Expanding load 20 - 40% Ferrite 10 - 20% Mineral filler 20 - 40 % Other additives 2% - 5% 2% 0 Black pigment 2,5 - 10% water 2,5 - 10% 14. A method of implementing a road marking product eliminable to order according to one of claims 1 to 13, characterized in that one applies successively on the ground a first base layer, and after drying of this last a second upper layer of marking product, and when it is desired to eliminate said marking product is carried out contactless heating by electromagnetic induction of said product, leading to the destruction of the internal cohesion of the base layer followed by separation of the two layers of product marking. 15. The method of claim 14, characterized in that after detachment of the two layers of the marking product is carried out the removal of said marking product by brushing, sweeping and / or aspiration. 16. Method according to one of claims 14 and 15, characterized in that the application of the first base layer and the second upper layer of the marking product is carried out by brush, by spraying under air pressure or by "airless" type spray. 17. Method according to one of claims 14 to 16, characterized in that the contactless heating by electromagnetic induction of the marking product to be eliminated is performed using an induction heating device having a power of between 10 kW and 100 kW and a frequency between 50 kHz and 500 kHz, said device being embedded on a mobile platform with adjustable forward speed. 18. The method of claim 17, characterized in that the induction heating device comprises an inductor disposed at the free end of an arm articulated on said movable platform so as to be positioned at an adjustable height of between 1 mm and 10 mm above the surface of the marking product to be removed.