Patent Application
20070254106
1. Field of Invention
This invention relates to a process for producing a decorative surfacing material by selective orientation of decorative fillers by magnetic and impact means.
2. Description of the Related Art
The preferred use for the process of this invention is the production of a decorative solid surface material. As employed herein, a solid surface material is understood in its normal meaning and represents a uniform, non-gel coated, non-porous, three dimensional solid material containing polymer resin and particulate filler, such material being particularly useful in the building trades for kitchen countertops, sinks, wall coverings, and furniture surfacing wherein both functionality and an attractive appearance are necessary. A well-known example of a solid surface material is Corian® produced by E. I. DuPont de Nemours and Company. A number of design aesthetics are heretofore known in solid surface materials, such as granite and marble, but they have a mostly two-dimensional appearance.
Most solid surface materials are manufactured by thermoset processes, such as sheet casting, cell casting, injection molding, or bulk molding. The decorative qualities of such products are greatly enhanced by incorporating pigments and colored particles such that the composite resembles natural stone. The range of patterns commercially available are constrained by the intermediates and processes currently used in the manufacturing of such materials.
Solid surface materials in their various applications serve both functional and decorative purposes. The incorporation of various attractive and/or unique decorative patterns into solid surface materials enhances its utility. Such patterns constitute intrinsically useful properties, which differentiate one product from another. The same principle applies to naturally occurring materials such as wood, marble, and granite whose utility, for example in furniture construction, is enhanced by certain naturally occurring patterns, e.g., grain, color variations, veins, strata, inclusions, and others. Commercially manufactured solid surface materials often incorporate decorative patterns intended to imitate or resemble naturally occurring patterns in granite or marble. However, due to limitations of feasibility and/or practicality, certain decorative patterns and/or categories of decorative patterns have not previously been incorporated in solid surface materials.
Decorative patterns that have been previously achieved in traditional solid surface manufacturing typically employ one of three methods:
Using these traditional methods, it is required to mix materials of different colors or appearances to form decorative patterns. They do not produce certain categories of decorative patterns not dependent on combinations of different colors.
A new class of aesthetic for solid surface materials is disclosed in U.S. Pat. No. 6,702,967 to Overholt et al which discloses a process for making a decorative surfacing material having a pattern by preparing a curable composition with orientable anisotropic particles, forming numerous fragments of the composition, and reforming the fragments into a cohesive mass with at least some of the fragments having the oriented particles in different orientations.
The invention is a process for forming a decorative pattern in a surface of a solid surface material containing magnetic anisotropic particles comprising the steps of orienting at least a majority of the magnetic anisotropic particle in a flowable solid surface material, inducing a magnetic field in a portion of surface areas of the flowable solid surface material to change the orientation of magnetic particles in the magnetic field, indenting a plurality of surface areas in the flowable solid surface material to disrupt the orientation of the anisotropic particle at indented surface areas, smoothing the surface of the flowable solid surface material having indented surface areas, and solidifying the flowable solid surface material.
In another embodiment of the process of the invention, a decorative pattern in a surface of a solid surface material containing magnetic anisotropic particles is formed by the steps of orienting at least a majority of the magnetic anisotropic particle in a flowable solid surface material, indenting a plurality of surface areas in the flowable solid surface material to disrupt the orientation of the anisotropic particle at indented surface areas, inducing a magnetic field in a portion of surface areas of the flowable solid surface material to change the orientation of magnetic particles in the magnetic field, smoothing the surface of the flowable solid surface material having indented surface areas, and solidifying the flowable solid surface material.
These and other features, aspects and advantages of the present invention will become better understood with reference to the following description, append claims, and accompanying drawings where
The present invention is a process for forming a decorative pattern in solid surface materials with anisotropic particles by orienting the anisotropic particulate filler. The anisotropic particulate filler in an uncured solid surface composition may be oriented by various means wherein at least some of the orientable particles are in a common orientation and subsequently reorienting, by magnetic and impact means, at least some of the oriented anisotropic particles (i.e., flakes) in specific regions to form a decorative pattern in solid surface materials. Another embodiment of the invention comprises a generally unoriented filler in the uncured solid surface composition and subsequently orienting, by various means, at least some of the oriented anisotropic particles (i.e., flakes) in specific regions to form a decorative pattern. The pattern is created by differences in anisotropic particle orientation between adjacent regions within the solid surface material. The process will create an aesthetic three-dimensional appearance in the solid surface material by the way ambient light differentially interacts with the adjacent regions due to particle orientation.
Solid surface compositions useful in the present invention are not specifically limited as long as they are flowable under process conditions and can be formed into a solid surface material. The polymerizable composition may be a casting sirup as disclosed in U.S. Pat. No. 3,474,081 to Bosworth, and cast on a moving belt as disclosed in U.S. Pat. No. 3,528,131 to Duggins. In another embodiment of the invention, the polymerizable compositions may be made by a process in which compression molding thermosettable formulations are made and processed as described in Weberg et al, in U.S. Pat. No. 6,203,911 and the compression molding compound is put through an extrusion process step. Solid surface formulations could also include various thermoplastic resins capable of compression molding. In a further embodiment of the invention, the polymerizable composition may be made and extruded according to the disclosure of Beauchemin et al in U.S. Pat. No. 6,476,111. In all embodiments, orientable anisotropic aesthetic-enhancement particles are included in the polymerizable compositions, as described hereinafter. Anisotropic pigments, reflective particles, fibers, films, and finely divided solids (or dyes) may be used as the aesthetic-enhancement particles to highlight orientation effects. By controlling the amount of enhancement particles, and the shape and size of the reoriented regions, the translucency of the resulting solid surface material can be manipulated to give a desired aesthetic. Different colors, reflectivity, and translucency can be achieved by combining different amounts of enhancement particles, fillers, and colorants, and the degree to which the anisotropic filler particles are reoriented.
Anisotropic particulate fillers useful in the present invention are not specifically limited as long as they have an aspect ratio that is sufficiently high to promote particle orientation during material processing and have an appearance that changes relative to the orientation to the material and the observer. Preferred anisotropic particulate fillers include materials that have an aspect ratio that is sufficiently high to promote particle orientation during material processing and have an appearance that changes relative to the orientation to the material and the observer. The aspect ratios of suitable enhancement particles cover a broad range, e.g. metallic flakes (20-100), mica (10-70), milled glass fiber (3-25), aramid fiber (100-500), chopped carbon fiber (800), chopped glass fiber (250-800) and milled coated carbon fiber (200-1600). These visual effects may be due to angle dependent reflectivity, angle dependent color absorption/reflection, or visible shape. These particles may be plate-like, fibers, or ribbons. The aspect ratio is the ratio of the greatest length of a particle to its thickness. Generally the aspect ratio will be at least 3, and more generally at least 20. Plate-like materials have two dimensions significantly larger than the third dimension. Examples of plate-like materials include, but are not limited to: mica, synthetic mica, glass flakes, metal flakes, alumina, and silica substrates, polymer film flakes, as well as synthetic materials such as ultra-thin, multi-layer interference flakes (e.g., Chromaflair® from Flex Products), and helical superstructure, cigar-shaped liquid crystal molecules (e.g., Helicone® HC from Wacker). In many cases, the surfaces of the platy substrate are coated with various metal oxides or pigments to control color and light interference effects. Some materials appear to be different colors at different angles. To enable the magnetic reorientation, at least a portion of the anisotropic particles must possess magnetic properties. Metal flakes with magnetic properties are found to be especially useful. Exemplary metal flakes for magnetic reorientation include steel, stainless steel, nickel, and combinations thereof.
Fibers have one dimension that is significantly larger than the other two dimensions. Examples of fibers include, metal, polymer, carbon, glass, ceramic, and various natural fibers. Ribbons have one dimension that is significantly larger than the other two, but the second dimension is noticeably larger than the third. Examples of ribbons would include metals and polymer films.
Optionally, the polymeric compositions may include particulate or fibrous fillers that are either not isotropic or not aesthetic. In general, fillers increase the hardness, stiffness, or strength of the final article relative to the pure polymer or combination of pure polymers. It will be understood, that in addition, the filler can provide other attributes to the final article. For example, it can provide other functional properties, such as flame retardation, or it may serve a decorative purpose and modify the aesthetic. Some representative fillers include alumina, alumina trihydrate (ATH), alumina monohydrate, aluminum hydroxide, aluminum oxide, aluminum sulfate, aluminum phosphate, aluminum silicate, Bayer hydrate, borosilicates, calcium sulfate, calcium silicate, calcium phosphate, calcium carbonate, calcium hydroxide, calcium oxide, apatite, glass bubbles, glass microspheres, glass fibers, glass beads, glass flakes, glass powder, glass spheres, barium carbonate, barium hydroxide, barium oxide, barium sulfate, barium phosphate, barium silicate, magnesium sulfate, magnesium silicate, magnesium phosphate, magnesium hydroxide, magnesium oxide, kaolin, montmorillonite, bentonite, pyrophyllite, mica, gypsum, silica (including sand), ceramic microspheres, ceramic particles, ceramic whiskers, powder talc, titanium dioxide, diatomaceous earth, wood flour, borax, or combinations thereof.
Furthermore, the fillers can be optionally coated with sizing agents, for example, silane (meth)acrylate which is commercially available from OSI Specialties (Friendly, W. Va.) as Silane 8 Methacrylate A-174. The filler is present in the form of small particles, with an average particle size in the range of from about 5-500 microns, and can be present in amounts of up to 65% by weight of the polymerizable composition.
The nature of the filler particles, in particular, the refractive index, has a pronounced effect on the aesthetics of the final article. When the refractive index of the filler is closely matched to that of the polymerizable component, the resulting final article has a translucent appearance. As the refractive index deviates from that of the polymerizable component, the resulting appearance is more opaque. ATH is often a preferred filler for poly(methylmethacrylate) (PMMA) systems because the index of refraction of ATH is close to that of PMMA. Of particular interest are fillers with particle size between 10 microns and 100 microns. Alumina (Al2O3) improves resistance to marring. Fibers (e.g., glass, nylon, aramid and carbon fibers) improve mechanical properties. Examples of some functional fillers are antioxidants (such as ternary or aromatic amines, Irganox® (Octadecyl 3,5-Di-(tert)-butyl-4-hydroxyhydrocinnamate) supplied by Ciba Specialty Chemicals Corp., and sodium hypophosphites, flame retardants (such as halogenated hydrocarbons, mineral carbonates, hydrated minerals, and antimony oxide), UV stabilizers (such as Tinuvin® supplied by Ciba Geigy), stain-resistant agents such as Teflon®, stearic acid, and zinc stearate, or combinations thereof.
In carrying out the process of this invention, the orientation of the anisotropic particulate fillers may be done by taking advantage of the tendency of the particles to align themselves during laminar flow of the polymerizable matrix, as shown schematically in
An aesthetic is created in the uncured solid surface composition by selective reorientation of the anisotropic particles. The reoriented particles do not have the same orientation as the bulk of the material after selective reorientation, which results in the region of the reorientation (400) appearing visually different as shown in
Reorienting the anisotropic particles employing physical deformation will form indentations (300) in the surface of the polymerizable composition as shown in
The strength of the magnetic field is not critical provided the strength is sufficient to disrupt or change filler orientation in a localized volume of the surface. For purposes of illustration, a magnetic field of 35 gauss or less is suitable when applied over an extended time during the casting cure. A magnetic field of 250 gauss or more is typically used for short exposure times, including exposures of less than one second. Pattern orientation through the full thickness of a ½-inch thick casting using approximate one-second exposure is produced with larger magnetic fields with mid thickness field strengths of approximately 250 gauss.
After any surface flattening or texturing, the uncured composition is cured. Curing of the polymerizable composition after the reorientation of the anisotropic particles is done according to what polymer system is used. Most solid surface materials manufactured by thermoset processes, such as sheet casting, cell casting, injection molding, or bulk molding will use cure agents that when thermally activated will generate free radicals which then initiate the desired polymerization reactions. Either a chemically-activated thermal initiation or a purely temperature-driven thermal initiation to cure the acrylic polymerizable fraction may be employed herein. Both cure systems are well known in the art. Curing of thermoplastic embodiments of the invention, such as extruded thermoplastics, is accomplished by allowing the composition to cool below the glass transition temperature.
The following examples are included as representative of the embodiments of the present invention. The percentages are by weight, and the temperatures are in centigrade, unless otherwise noted.
The following ingredients were weighed out and mixed:
at a temperature of 28 degrees C. After mixing for 1 minute, 0.91 grams of distilled water was added to the mixture. The mixture was then evacuated under vacuum (24-25 in Hg) using a pump and a suitable condensing vapor trap. After mixing and evacuating for approximately 3 minutes, 2.58 grams of calcium hydroxide slurry (34% in sirup) and 1.33 grams of ethylene glycol dimercaptoacetate were added using syringes. After 45 seconds of additional mixing and evacuation, the mixture was poured into a container of square design to form a layer of approximately 0.5-inch thickness. The container had a 0.040-inch thick metal bottom made of AISI 301 stainless steel that had been demagnetized prior to the pour. It took approximately 20 seconds to transfer the mixed material from the mixer and pour it into the container.
Immediately after the pour of the casting material, the casting was deformed by dragging an 11/16-inch wide blade through the casting in a series of linear paths. The casting material flowed back into a level surface following the deformation. Following the deformation, the casting was then traversed with a magnetic field, creating a linear pattern. The magnetic field was created with two electromagnets with 0.5-inch diameter by 1.27-inch length inner cores made of 1215 steel. The electromagnet coils consisted of 4,000 turns, a coil winding density of approximately 3200 turns/inch, and a coil resistance of 150 ohms. The coil outer diameter was approximately 1 and 5/16-inches. The centerlines of the cylindrical electromagnets were aligned and the ends of the cores were spaced 0.060-inches from the bottom of the casting container and from the top of the poured casting. The electromagnet coils were wired with opposite polarity and powered with 0.5 amperes of direct current. The electromagnets were positioned around the casting, the power was turned on, and the electromagnets were traversed across the casting at a speed of approximately 4.6 inches per second. The power was turned on approximately 120 seconds after the calcium hydroxide slurry and ethylene glycol dimercaptoacetate were injected. The electromagnet motion was stopped and the current was turned off at the end of the linear traverse. The electromagnets were then moved away from the container, insulation was placed on top of the casting and underneath the casting container, and the casting was allowed to cure.
The sequence of deformation followed by electromagnet traverse created a reorientation pattern in the casting similar to the pattern described in Example 3 with additional darkened lines of approximate 0.025-inch width, intersecting the electromagnet induced pattern and following the blade-deformation paths.
A casting mixture was prepared according to the process of Example 1. Immediately after pouring the mixture into the stainless steel container the casting was then traversed with a magnetic field, creating a linear pattern. The magnetic field was created with two electromagnets with 0.5-inch diameter by 1.27-inch length inner cores made of 1215 steel. The electromagnet coils consisted of 4,000 turns, a coil winding density of approximately 3200 turns/inch, and a coil resistance of 150 ohms. The coil outer diameter was approximately 1 and 5/16-inches. The centerlines of the cylindrical electromagnets were aligned and the ends of the cores were spaced 0.060-inches from the bottom of the casting container and from the top of the poured casting. The electromagnet coils were wired with opposite polarity and powered with 0.5 amperes of direct current. The electromagnets were positioned around the casting, the power was turned on, and the electromagnets were traversed across the casting at a speed of approximately 4.6 inches per second. The power was turned on approximately 120 seconds after the calcium hydroxide slurry and ethylene glycol dimercaptoacetate were injected. The electromagnet motion was stopped and the current was turned off at the end of the linear traverse. The electromagnets were then moved away from the container. The casting was then deformed by dragging an 11/16-inch wide blade through the casting in a series of linear paths perpendicular to the electromagnet traverse. The casting material flowed back into a level surface following the deformation. Insulation was then placed on top of the casting and underneath the casting container, and the casting was allowed to cure.
The sequence of electromagnet traverse followed by deformation created a reorientation pattern in the casting similar to the pattern described in Example with additional darkened lines of approximate 0.025-inch width, intersecting the electromagnet induced pattern and following the blade-deformation paths. The deformation process also caused some disruption of the straightness of the electromagnet-induced pattern.
