The invention relates generally to apparatus and compositions useful for caulking and grouting tiles and other building materials having interstices therebetween.
The placement of various flat or curved pieces of ceramic, stone, concrete, or other material, collectively referred to as “tile”, onto floors, walls, counter tops, or other surfaces in a building is an ancient tradition. Tile is installed by adhering multiple tiles to the area to be covered and thereafter filling the spaces between the tiles with a grout.
In laying the tile on a floor, for example, the craftsman applies an adhesive (e.g., thin set mortar) to the floor. Then, tiles are positioned on the adhesive while inserting spacers between the tile for proper spacing, and the adhesive is allowed to set (e.g., overnight). Once set, the tile spacers are removed and a grout is applied to fill the spaces around the tile that have been preserved by the tile spacers. Grout often consists of a cementitious mixture of fine aggregates mixed into a cementing agent with a solvent (e.g., water), but made so thin as to flow almost like cream. The cementing agent may comprise a polymeric adhesive material (e.g., a resin-based grout, such as an epoxy) or simply Portland cement. The aggregates are typically sand and/or crushed stone. The addition of dyes and pigments to the cementitious materials has also enjoyed wide application in all of the above mentioned materials. Such grouts enjoy broad application in construction materials, tile setting, wall and pool plasters, stucco, self-leveling compounds, roofing tiles, and patches.
Application of grout to a tile surface such as a tile floor or wall has traditionally and conventionally been done almost entirely by hand in that the workman uses a hand trowel working on hands and knees or squatting in small areas by pouring the grout between the tiles and by hand troweling the excess grout to form the grouting joints while removing the excess to leave a smooth grouting joint between adjacent tiles. Applied grout can be allowed to at least partially dry, and the excess overlying the face of the tile thereafter removed by washing with water.
Cementitious grouts are in common use. Polymeric resin-based grouts are also known. By way of example, U.S. Pat. No. 4,833,178 describes an epoxy resin-based grout composition that requires addition of a hardener thereto and mixing prior to use. U.S. Pat. Nos. 3,854,267; 3,859,233; and 4,472,540 describe non-epoxy polymer resin-based grout compositions that either contain sand or have a smooth-textured finish that is undesirable in many applications.
Microspheres are generally spherical particles of organic or inorganic material, and are a well known in the art. Microspheres are available in two forms: hollow microbubbles and solid microbeads. Examples include particles described in U.S. Pat. Nos. 5,849,055; 4,767,726; 5,176,732; 6,531,222; 5,534,348; and 5,077,241. Inorganic microspheres may include glass or ceramic microspheres.
The present invention overcomes and eliminates the necessity for applying grout with hand trowels while greatly increasing the speed of application without reducing the workmanship or structural integrity of the grouting joints and which quickly and expeditiously allows for the application and easy clean-up of the grout.
The invention relates to a grout composition comprising a first mineral filler, a second mineral filler, microspheres, and an air-dryable polymeric resin. The first mineral filler has an average particle size greater than 160 micrometers and a Mohs hardness less than about 6.5. The second mineral filler has an average particle size less than 600 micrometers. The composition comprises the air-dryable polymeric resin in an amount sufficient to bind the first and second mineral fillers and the microspheres upon drying of the composition. In some grout compositions, the microspheres can be used in place of the second filler.
One example of this grout composition comprises 20% to 40%, by weight, of first mineral filler particles having an average particle size in the range from 160 to 700 micrometers and a Mohs hardness less than about 6.5; 20% to 40%, by weight, of second mineral filler particles having an average particle size in the range from 90 to 120 micrometers; 0.5% to 5% by weight of microspheres; and 20% to 35%, by weight, of an air-dryable polymeric resin.
The microspheres can be made of inorganic or organic material. In one embodiment, the microspheres are inorganic microbubbles and comprise no more than 5% by weight of the composition. In another embodiment, the microspheres can be inorganic microbeads and comprise up to no more than 10% of the composition. The microspheres have an average particle size less than 600 micrometers. In one embodiment, the average particle size of the microspheres is less than 150 microns.
The first and second mineral fillers can be the same mineral (e.g., calcium carbonate) or different minerals. The overall mineral filler content of the grout composition (i.e., the sum of the first and second mineral fillers and any other mineral fillers incorporated into the composition, including the microspheres) should be in the range from 30% to 80% by weight, and is preferably 55% to 65% by weight. The proportions of first and second mineral fillers can vary. The first mineral filler can be present in an amount from 5% to 70% by weight, but is preferably present in an amount from 20% to 40% by weight. The second mineral filler can be present in an amount from 5% to 60% by weight, but is preferably present in an amount from 20% to 40% by weight.
The grout composition described herein can be packaged in pressurized containers from which the composition can be dispensed. Preferably, compositions packaged in pressurized containers do not comprise a particulate having an average particle size greater than 100 micrometers and a Mohs hardness greater than about 6.5. More preferably, they do not comprise a particulate having an average particle size greater than 20 micrometers and a Mohs hardness greater than about 6.5.
Because the first mineral filler particles are generally larger than the second mineral filler particles, the hardness of the first mineral particles is more critical than the hardness of the second mineral filler particles. Suitable first mineral filler particles have sizes in the range from 160 to 700 micrometers, more preferably from 185 to 245 micrometers. The Mohs hardness of the first mineral filler should not be greater than about 6, and is preferably from 2 to 4. Suitable second mineral filler particles have sizes in the range from 50 to 600 micrometers, more preferably from 90 to 120 micrometers.
The polymeric resin in the grout composition can comprise a single polymer or a plurality of polymers, such as one or more acrylic latex polymers. Examples of suitable acrylic latex polymers include homopolymers of acrylate, homopolymers of alpha-methyl acrylate, and copolymers of acrylate and alpha-methyl acrylate. In addition to any solvent in the polymeric resin, the grout composition can further comprise one or more additional solvents. Solvents can be added in an amount sufficient to improve the workability of the composition. For example, the viscosity of the grout composition can be adjusted such that it is not less than about 240 centipoise (and preferably not more than about 880 centipoise) or such that it is from 2400-8800 Poise.
The grout composition can comprise other ingredients as well, such as a dye, a colorant (e.g., titanium dioxide), an antifoam, a wetting agent, a coupling agent, a biocide, a thickening agent, a drying rate modulator, a water-repelling polymer, and mixtures of these.
The invention also relates to a sealed container containing the grout composition described herein. The container has a nozzle for dispensing the composition from the container under pressure. The container can have a valve in fluid communication with the nozzle. The composition is dispensed through the nozzle upon actuation of the valve. The container can also have a piston having a face that urges the composition through the nozzle upon application of force or pressure to the piston (e.g., pressure exerted upon the piston by a pressurized reservoir). The shape of the container can be adapted to fit a caulking gun or other conventional device for applying caulks or sealants.
The invention includes a pressurized container containing the grout composition described herein. In one embodiment, the container has a valved outlet in fluid communication with the interior of the container for dispensing the composition from the container under pressure upon actuation of the valve and a nozzle in fluid communication with the outlet of the valve, for directing the dispensed composition. The nozzle can have a dispensing end adapted to fit between ceramic tiles (e.g., between tiles spaced not less than 0.5, 0.25, 0r 0.125 inch apart). The nozzle can also (or instead) have a shaping edge (e.g., a rounded portion of the nozzle) adjacent the dispensing end, such that the surface of the dispensed composition can be shaped by sliding the shaping edge along the surface. The nozzle can also (or instead) have a stabilizing member for sliding against a tiled surface while dispensing the composition. Each of these aspects can be unitary with the nozzle, fixed thereto, or attachable and detachable therefrom.
The interior of the grout-filled container can have a piston interposed between a pressurized portion of the container and a second portion of the container. The second portion fluidly communicates with the valve and can contain the composition. For example, the container can have a substantially circular cross-section and a first portion adjacent the outlet that contains the grout composition. A second, pressurized portion of the container (e.g., a pressurized bladder or a space containing a pressurized gas) is disposed on the opposite side of the grout composition than the outlet. A slidable disk- or cup-shaped piston can be disposed between the first and second portions. When the outlet is opened, the pressurized portion urges the piston axially along the substantially cross-section of the container against the first portion, forcing the grout composition out of the outlet.
The invention further relates to a method of waterproofing a surface having tiles adhered thereto. The method comprises filling interstices between the tiles with a grout composition described herein.
In another aspect, the invention relates to methods of making a grout composition described herein.
These and other features and advantages of the present invention will be more fully disclosed in, or rendered obvious by, the following detailed description of the preferred embodiment of the invention, which is to be considered together with the accompanying drawings wherein like numbers refer to like parts and further wherein:
The invention relates to grout compositions that exhibit the appearance of traditional cementitious grouts and other sand-containing (“sanded”) grouts without exhibiting the extremely abrasive properties of such grouts. In almost all applications, the degree of hardness and the abrasiveness exhibited by traditional grouts are greater than the hardness and abrasiveness that are necessary for the particular application. The extreme hardness and abrasiveness of traditional grouts are largely vestiges of traditional methods of making grouts. Because the grout compositions described herein are less abrasive than prior art grouts, they can be used in ways (e.g., application using pressurized containers) that prior art grouts cannot. In addition to their flexibility with regard to use, the grout compositions described herein retain the pleasing textured appearance and feel of sanded and cementitious grouts. Furthermore, it has been discovered that addition of microspheres to the grout compositions described herein can improve the clean-up properties of the compositions.
Definitions
As used herein, each of the following terms has the meaning associated with it in this section.
The “average particle size” of a collection of particles means the weight-averaged particle size (as opposed to the number-averaged particle size). Half of the weight of the particles in the collection have a size larger than the average particle size, while 50% by weight have a smaller size.
A “piston” is a solid, generally non-deformable body that has at least one face and that is movable within a container, cavity, tube, or other enclosure. Pressure or force applied to the body to move the piston is transmitted to the face, which can transmit the force to a material (e.g., a grout composition) that contacts the face within the enclosure.
A “polymeric resin” is a fluid form of a polymer or a fluid precursor of a polymer that is polymerized to form the polymer.
“Grout workability” refers to the consistency of grout compositions typically employed in tile grouting applications. The consistency of grout can differ based on the particular application. For example, grout applied to vertical surfaces (e.g., tiled walls) must be sufficiently viscous that it will not run or fall out from the vertical interstices between tiles, but must retain sufficient deformability that it can be packed or shaped as desired in order to obtain an aesthetically pleasing surface. Grout used in supported horizontal applications (tile floors, for example) can be less viscous.
“Microspheres” refers to generally spherical shaped particles of inorganic or organic material. Microspheres are available in two forms: microbubbles and microbeads. Microbeads are essentially void free, solid spherical particles. Microbubbles are spherical shaped particles having a hollow cavity defined by surface walls.
This description of preferred embodiments is intended to be read in connection with the accompanying drawings, which are to be considered part of the entire written description of this invention. The drawing figures are not necessarily to scale and certain features of the invention may be shown exaggerated in scale or in somewhat schematic form in the interest of clarity and conciseness. In the description, relative terms such as “horizontal,” “vertical,” “up,” “down,” “top” and “bottom” as well as derivatives thereof (e.g., “horizontally,” “downwardly,” “upwardly,” etc.) should be construed to refer to the orientation as then described or as shown in the drawing figure under discussion. These relative terms are for convenience of description and normally are not intended to require a particular orientation during practice of the invention. Terms including “inwardly” versus “outwardly,” “longitudinal” versus “lateral” and the like are to be interpreted relative to one another or relative to an axis of elongation, or an axis or center of rotation, as appropriate. Terms concerning attachments, coupling, and the like, such as “connected” and “interconnected,” refer to a relationship wherein structures are secured or attached to one another either directly or indirectly through intervening structures, as well as both movable or rigid attachments or relationships, unless expressly described otherwise. The term “operatively connected” is such an attachment, coupling or connection that allows the pertinent structures to operate as intended by virtue of that relationship. In the claims, means-plus-function clauses are intended to cover the structures described, suggested, or rendered obvious by the written description or drawings for performing the recited function, including not only structural equivalents but also equivalent structures.
The invention relates to grout compositions that exhibit the appearance of traditional cementitious grouts and other sanded grouts without exhibiting the extremely abrasive properties of such grouts. Because the grout compositions described herein are less abrasive than prior art grouts, they can be used in ways (e.g., pressurized application) that prior art grouts cannot. In addition to their flexibility with regard to use, the grout compositions described herein retain the pleasing textured appearance and feel of sanded and cementitious grouts. Furthermore, grout compositions including microspheres exhibit significantly improved clean-up properties.
The grout composition comprises at least the following components, a polymeric resin, microspheres, a first mineral filler, and a second mineral filler. In one embodiment, the microspheres are microbubbles and comprise no more than 5% of the composition. In another embodiment, the microspheres are microbeads and comprise no more than 10% of the composition. In some compositions, the first mineral filler has an average particle size greater than 100 micrometers and the mineral particles of the first mineral filler exhibit a Mohs hardness less than about 6.5. In some compositions, the second mineral filler has an average particle size less than 100 micrometers. The polymeric resin is air-dryable and is present in an amount sufficient to bind the microspheres, and first and second mineral fillers upon drying of the composition. The first mineral filler gives the dried grout composition the appearance, texture, and feel of a traditional sanded cementitious grout. In some compositions, the microspheres can be used in place of the second mineral filler. These compositions comprise the polymeric resin, the microspheres, and the first mineral filler.
In another embodiment, the grout composition comprises 20% to 40%, by weight, of first mineral filler particles having an average particle size in the range from 160 to 700 micrometers and a Mohs hardness less than about 6.5; 20% to 40%, by weight, of second mineral filler particles having an average particle size in the range from 90 to 120 micrometers; 0.5% to 5%, by weight, of microspheres having an average particle size not greater than 120 micrometers; and 20% to 35%, by weight, of an air-dryable polymeric resin.
The grout composition can also include one or more of a variety of other constituents. A variety of additives (e.g., wetting agents, solvents, antifoams, thickening agents, and agents that modulate the rate at which the grout dries) are known in the art to be useful components of grout compositions, and substantially any of those additives can be included in the grout composition described herein. The grout composition can also include components that confer beneficial properties to the dried grout. By way of example, the grout composition can include a dye or colorant to impart a desired color to the dried grout composition. A biocidal agent can also be incorporated into the grout composition, to inhibit growth of organisms in or on the finished grout. Incorporation of one or more water-repelling agents (e.g., a water-repellant polymer) into the grout composition can enhance the water resistance (and useful lifespan) of the grout composition.
An important advantage of the grout composition described herein is that it is suitable for application to a tile surface in a variety of different ways. The grout composition disclosed herein can be manually applied using a trowel and float, as with traditional grouts. It can be packaged and sold in cartridges adapted to fit standard caulking guns and other applicators to facilitate application with caulking guns or other applicators. It can be packaged, sold, and applied in a manually-squeezable tube, such as the type of tube in which various adhesives, caulks, and sealants are presently sold.
Unlike most or all previous grout compositions, the grout composition described herein is suitable for packaging into a pressurized container, such that the grout composition can be applied to the interstices of a tiled surface by actuating a valve that seals the container. Prior art grouts are not suitably packaged in this manner, since the sand, cement, or other components of the grouts are highly abrasive and cause serious damage to machinery used to package pressurized containers. Application of a grout composition in the form of a pressurized can-type container is a highly desirable application method, particularly in situations in which the person applying the grout is not an experienced mason, in which only a relatively small amount of grouting needs to be done, or in which the person applying the grout wishes to perform the work intermittently. The grout composition described herein is useful in each of these situations (in addition to traditional grouting applications).
Another advantage of the grout compositions described herein is that they can be formulated to resist shrinking (relative to freshly-applied grout) and cracking of the dried grout. As the size of the crack or hole to be filled using the grout increases, the importance of the anti-shrinking and anti-cracking properties of the grout composition increases.
Another advantage of grout compositions including microspheres is that they are significantly easier to clean up after application and drying. For example, these grout compositions require significantly less water, scrubbing, and time to clean off of the face of ceramic tile after application and drying. The reason why these compositions are more easily cleaned is not fully understood. Without being bound by any particular theory of operation, it is believed that the interaction of solvent(s) in the grout with the spherical surface of the microspheres can reduce the tendancy of those solvents to interact with (i.e., adhere to) ceramic tile surfaces.
The invention includes grout compositions, methods of using them, and apparatus for applying them. Further details of the components of the grout composition, certain apparatus useful for containing and applying the grout compositions, and methods of using the grout composition are described below.
The Polymeric Resin
The grout composition described herein includes at least one polymeric resin. The resin comprises at least one polymer and at least one solvent. The resin can contain multiple polymers, multiple solvents, or both multiple polymers and multiple solvents. The polymer(s) and solvent(s) should be miscible with one another. Suitable polymers and solvents are known in the art, and include those used as binders in previously-known grouts, cements, and concretes. Polymers traditionally used in caulks and other sealants can also be incorporated into the grout composition described herein. However caulk/sealant polymers often have a glossy finish that is not normally associated with grouts, and incorporation of such polymers in the grout compositions described herein should be limited so as to avoid a glossy or high-sheen finish. Grout compositions having a matte, dull, sandy or other textured finish are preferred.
A preferred type polymer is the class of polymers known as acrylic latexes. A wide variety of acrylic latex resins, colloids, and suspensions are commercially available, each with its own characteristics. The particular acrylic latex and the corresponding resin that should be selected for a grout composition can be determined based on the intended end use of the grout composition. For example, in applications in which the appearance of the finished grouted surface is more important than the durability or impact resistance of the grout, the polymeric resin can be selected primarily on the basis of its color, workability, and non-shrinking character. As another example, in applications in which the water-resistance of the finished grouted surface is a primary consideration, the polymeric resin can be selected primarily on the basis of the water-repelling characteristics of the polymer, the ability of the polymeric resin to cure in the presence of water, the drying (curing) time of the resin, and the crack resistance of the cured resin. Further by way of example, in applications in which the durability and impact resistance of the finished grout are the paramount concerns, the polymeric resin can be selected to yield high durability and impact resistance.
An example of a suitable acrylic latex polymer that can be incorporated into a general purpose grout composition is the acrylic copolymer sold commercially as RHOPLEX (Registered Trademark, “RTM”) brand colloid (Rohm & Haas Company, Philadelphia, Pa.). Other suitable acrylic latexes include homopolymers of acrylate, homopolymers of alpha-methyl acrylate, and copolymers of acrylate and alpha-methyl acrylate. Examples of suitable polymer resins include butyl acrylate/styrene copolymers, such sold as those sold in the form of dispersions under the trade name ACRONAL(RTM) NX 4787 (BASF, Mount Olive, N.J.), and acrylic/vinyl acetate copolymers, such as those sold in the form of dispersions under the trade name ACRONAL(RTM) V275 (BASF, Mount Olive, N.J.).
Other suitable polymers that can be incorporated into the grout composition in place of, or in addition to, acrylic latexes include polymeric silanes and polysilazanes. Polymers in which silane coupling agents (e.g., vinylbenzyl chloride products available from Dow Chemical Company, Midland, Mich.) are incorporated are also suitable, the coupling agents being able to link organic polymer systems with inorganic substrates, such as the first and/or second mineral fillers. An example of a suitable coupling agent is the product designated AP-SILANE 33 (Trademark, “TM”), obtained from Advanced Polymer, Inc. (Carlstadt, N.J.). Other polymers can be used as well or instead, such as polymers used in known caulks and sealant products.
The polymeric resin must be air-dryable, meaning that if the grout composition is dispensed into a crack and the surface of the grout is thereafter maintained in contact with ambient air, then substantially all of the solvent(s) in the grout composition will disappear (e.g., by evaporation) within days, weeks, or months following the application. Under normal, atmospheric conditions, it is preferable that the finished grout composition be substantially free of solvents (i.e., >90% of solvents have disappeared) within 48 to 72 hours after application. Grout compositions from which a substantial fraction (e.g., >75%) of solvent evaporates or otherwise disappears within 24 hours after application are also preferable. The polymeric resin can include more than one solvent, wherein the volatility of at least one solvent is significantly greater than another solvent in the resin at the anticipated application or drying temperature. Such a resin can be used to cause the grout composition to set relatively quickly while completely drying more slowly (e.g., to facilitate enhanced polymer cross-linking or entanglement).
Because grouting is often performed in enclosed areas (e.g., in interior rooms of houses, such as bathrooms and kitchens), non-toxic and non-irritating solvents are preferred, particularly in situations in which the grout composition is to be used or sold for use in occupied buildings. Many acceptable solvents are known. Water is a preferred solvent and exhibits no known toxicity or irritation. Regardless of the solvent used, it is recommended that any area enclosing the grouted surface be ventilated during and after application of the grouting composition described herein.
The grout composition must contain enough of the polymeric resin that the polymer contained in the resin is present in an amount sufficient to bind the first and second mineral fillers into a common mass once the solvent(s) in the resin are no longer present. The necessary amount of the polymer (and the corresponding resin) depends on the properties of the particular polymer(s) and fillers used, the presence of wetting agents, surface-modifying or coupling agents, the degree and energy of mixing, and other factors that are within the ken of the skilled artisan. This information can also be readily derived empirically simply by preparing a plurality of test compositions. Suitable grout compositions can include from 15% to 70%, by weight, polymeric resin; however, grout compositions having very high (e.g., >50%) polymeric resin content can fail to resemble sanded grouts and may more closely resemble caulks. Preferred polymeric resin content values are 20% to 35% by weight (more preferably, 25% to 30%).
The First Mineral Filler
The first mineral filler is a particulate that acts as a filler and imparts a highly textured appearance to the finished grout. The particles of the first mineral filler have an average particle size that is greater than at least 160 micrometers. Depending on the texture, feel, and appearance desired, particulate compositions having a larger average particle size (e.g., 200, 300, 500, 700, 1000, 1500, or 2000 micrometers) can be used as the first mineral filler.
Sand used in traditional grout composition generally has grains that range in size from 160 to 700 micrometers. Fine-grained sands (e.g., particle sizes 185-245 micrometers) are desirable in many applications in which appearance, and tactile texture are important. Sand size distributions vary depending on the source of the sand and how it is sifted, cleaned, or otherwise processed. Substantially any sand particle size and size distribution can be replicated using first mineral filler particle sizes and size distributions. For example, desirable first mineral particle sizes include particles that range is size from 160 to 700 micrometers. First mineral fillers containing predominantly particles in the range 185-245 micrometers in size yield a grout composition having a fine-grained appearance. In one preferred composition, at least 80%, by weight, of first mineral filler particles in a grout composition described herein have a size in the range from 160 to 700 micrometers, and more preferably at least 80%, by weight, of those particles have a size in the range from 185 to 245 micrometers.
The uniformity of sizes of the particles in the first mineral filler is not critical, and selection of a first mineral filler on the basis, for example, of a particle size uniformity coefficient (e.g., the mesh opening size through which 60% of particles pass divided by the mesh opening size through which 10% of particles pass) can be made to accommodate aesthetic considerations such as the effect of the filler on the texture or other appearance of the finished grout.
An important characteristic of the particles of the first mineral filler is that the particles must not exhibit a greater hardness than the hardness of the materials that the grout composition contacts during preparation, processing, or both, of the composition. Sand, cement, and other relatively hard mineral components of prior art grouts have made packaging those prior art grouts into pressurized containers impractical, owing to the abrasive properties of those hard minerals. It has been discovered that relatively large particles of less hard minerals can replicate the appearance of sanded and other textured cementitious grouts without exerting the abrasive effect on processing and packaging machinery that was observed with prior art grouts.
Steel is a common component of chemical processing and packaging equipment. The hardness of a steel depends on a number of factors, including its composition and how it was treated during formation and subsequent fabrication. Generally, however, steels exhibit a hardness value of at least about 6.5 on the Mohs hardness scale. It has been discovered that if the relatively large mineral filler particles in a grout composition exhibit a hardness less than 6.5, then abrasion of processing and packaging materials can be reduced significantly. Preferably, the Mohs hardness of the particles of the first mineral filler of the grout composition disclosed herein is not greater than 6, 5, 4, or 3. A preferable mineral filler is particulate calcium carbonate (also known as calcite), which exhibits a Mohs hardness of approximately 2.5. Without wishing to be bound by any particular theory of operation, it is believed that if the Mohs hardness of the particles of the first mineral filler is lower (at least one Mohs scale units lower, and preferably at least two Mohs scale units lower) than the Mohs hardness of the materials from which the grout-contacting portions of a grout packaging machine are made, then the grout composition described herein will not exert excessive wear on the machine, thereby making packaging of the grout into pressurized containers practical.
Although the relatively large particles of a grout appear to be the primary cause of the abrasive effects exerted by grouts on packaging machinery, smaller particles can also abrade and wear such machinery. In the grout composition described herein, it is preferable that no particulate component of the composition (in its fluid form) exhibit a Mohs hardness greater than that of a machine used to package it into a pressurized container. For example, the grout composition can be formulated so that no particulate component exhibits a Mohs hardness greater than 6.5, 6, 5, 4, or 3. By way of example, if the hardest mineral particulate contained in the grout composition is calcite (i.e., calcium carbonate), then the composition does not comprise a particulate component exhibiting a Mohs hardness greater than about 2.5.
The first mineral filler should be selected so that the mineral particles thereof do not dissolve or degrade significantly over time in the grout composition. The first mineral filler is also desirably relatively inexpensive and easily obtained. Calcium carbonate is commercially available in a variety of forms, including in fractions separated by particle size, whiteness, surface treatment, and the like.
Selection of an appropriate first mineral filler can also be influenced by the anticipated end use of the grout. For grouts that will not be exposed to significant wear or abrasion after installation, appearance, availability, and cost concerns can outweigh wear resistance in selecting a first mineral filler. In such applications, first mineral fillers having relatively low hardness (e.g., Mohs hardness<4, <3, or <2.5) can be suitably used. If significant wear or abrasion of installed grout is anticipated, a harder filler (e.g., 5<Mohs hardness<6.5) can be used so that the grout retains its “sanded” appearance and texture in spite of the wear or abrasion.
The appearance of the grout composition can be significantly affected by the color and the shape of the mineral particles in the first mineral filler. In some embodiments, white mineral particles are preferred. Generally cubical mineral particles will closely mimic the appearance of sand. Mineral particles having substantially any crystal shape can be used, although particles having an aspect ratio (i.e., longest characteristic dimension divided by smallest characteristic dimension) less than about 5 or 10 are preferred. Generally cubic (e.g., longest characteristic dimension divided by smallest characteristic dimension<1.5) are preferred in applications in which the first mineral filler is intended to have the appearance of a sanded grout.
The Second Mineral Filler
The second mineral filler is a particulate that has an average particle size less than 600 micrometers. Preferably, the average particle size of the second mineral filler is significantly less than 600 micrometers (e.g., <300 micrometers, <120 micrometers, or <85 micrometers). The average particle size of the second mineral filler is preferably not less than 50 micrometers and more preferably not less than 90 micrometers. Use of second mineral filler particles smaller than 50 micrometers is possible. However, the effect of such particles on viscosity of the resulting grout composition can be undesirable unless other viscosity-lowering ingredients are included. In one embodiment, at least about 80%, by weight, of second mineral filler particles are in the size range 50-600 micrometers. In a preferred embodiment, at least about 80%, by weight, of the second mineral filler particles are in the size range 90-120 micrometers. The second mineral filler acts primarily as a simple filler, as such fillers are typically used in plastics.
The hardness of mineral particles in the second mineral filler is not critical. Preferably, the particles of the second mineral filler exhibit a Mohs hardness not greater than that of the parts of packaging machinery that contact the grout composition. For example, the hardness of particles in the second mineral filler should be not greater than 6.5 (6, 5, 4, or 3). Suitable materials that can be used as the second mineral filler include sands, calcium carbonate, ashes (e.g., coal furnace fly ash), and glass beads. Particles of minerals having a Mohs hardness from 2 to 4 are preferred. Because the color of the second mineral filler can significantly affect the color of the grout composition and the finished grout, the second mineral filler should be selected to conform with the desired grout color. For example, a gray particulate can be used as the second mineral filler for gray grout compositions. White minerals are compatible with most, if not all, colors of grout, and white particulate minerals such as calcium carbonate are suitable in many applications.
The mineral content of the first and second mineral fillers can be composed of the same or different minerals. By way of example, the first and second mineral fillers can both be calcium carbonate particulates. In some embodiments, a single mineral filler having a relatively broad or biphasic particle distribution can be used as both the first and second mineral fillers. It is immaterial whether separate mineral fillers having the properties recited herein for the first and second mineral fillers are combined or, alternatively, a single mineral filler comprising particles having sizes described for the first and second mineral fillers is used.
The absolute and relative amounts of the first and second mineral fillers used in the grout described herein depends on the desired texture, feel, or appearance of the finished grout. A higher content of first mineral filler increases the ‘sandiness’ or coarse texture of the grout. A higher overall (i.e., first+second+any other) mineral filler content decreases the degree of shrinkage of the grout composition upon drying. Increasing the amount of the second mineral filler increases the viscosity of the grout composition.
Suitable overall mineral filler content values for grout compositions described herein include 30% to 80%, more preferably 50% to 70%, and more preferably 55% to 65% (all percentages are percent, by weight, of the wet {i.e., non-dried} grout composition). The grout composition can include approximately equal (by weight) amounts of the first and second mineral fillers. Alternatively, the grout composition can include up to a two-, three-, or four-fold excess of one of the first and second fillers, relative to the other. On a percentage (of wet grout composition weight) basis, the amount of first mineral filler in the grout composition can range from 5% to 70%, although amounts in the range from 20% to 40% will more nearly resemble traditional sanded grouts. The grout composition can include the second mineral filler in amounts from 5% to 60%, and preferably contains the second mineral filler in an amount from 20% to 40%. One preferred grout composition comprises about 25% (by wet weight) polymers, about 28.5% first mineral filler, and about 32.5% second mineral filler. Colorants, solvents, and various additives described herein make up the remainder of that composition.
The Microspheres
The microspheres are generally spherical particles. Microspheres typically have an essentially normal distribution of particle size (Gaussian distribution). In some embodiments, it is preferable that not more than 5% by weight of the microspheres have a particle size less than one fourth the average particles size. In other embodiments, at least 85% of the microspheres have a particle size not more than twice the average particle size. The microspheres can have an average particle size less than 600 micrometers, for example. Preferably, the average particle size of the microspheres is significantly less than 600 micrometers (e.g., <300 micrometers, <120 micrometers, or <85 micrometers). In some compositions, blends of microspheres having different average particle sizes may be used.
Microspheres can be made from organic or inorganic materials. In one preferred embodiment, the microspheres are inorganic particles, such as glass or ceramic particles. The microspheres fill and adhere with other components of the grout composition. However, due to their substantially rounded shape, addition of the microspheres to the composition does not lead to significant increase in viscosity of the composition. If microspheres are incorporated into a grout composition packaged in a pressurized container, then smaller microspheres (e.g., not greater than 150 micrometers diameter or not greater than 120 micrometers diameter) can improve the flow properties of the grout when it is dispensed. Microspheres should be substantially non-porous, so that solvent from the grout composition is not sequestered within the microspheres. Inclusion of additional solvent can at least partially overcome such sequestration.
Microspheres are available in hollow and solid forms. An example of suitable microbeads is SPHERIGLASS™ solid glass spheres (PQ Corporation, Valley Forge, Pa.). In one embodiment, microbeads can be included in an amount of not more than 10% by weight of the composition. Examples of suitable hollow microspheres (i.e., microbubbles) include glass microbubbles such as SCOTCHLITE™ glass bubbles (3M Corporation, Minneapolis, Minn.), and Q-CEL™ and SPHERICEL™ hollow spheres (PQ Corporation, Valley Forge, Pa.). One suitable microbubble, K1 SCOTCHLITE™ glass bubbles (3M Corporation, Minneapolis, Minn.), has an average particle size of 65 micrometers with a maximum particle size not greater than 120 micrometers. Glass microbubbles can have a density ranging between 0.10 grams per cubic centimeter to over 1.0 grams per cubic centimeter. One preferred density range of glass microbubbles is 0.10-0.5 grams per cubic centimeter.
The density of the microspheres incorporated into grout compositions can be selected by a skilled artisan based on the desired density of the final composition. Because microbubbles having thicker walls can exhibit greater resistance to breakage, the thickness of microbubble walls can be selected based on the expected use of the grout.
Glass microbubbles can be included in substantially any amount, but the amount is preferably not more than 5% by weight of the composition. In a preferred embodiment, the amount of glass microbubbles is not more than 3% by weight of the composition. In another preferred embodiment, the amount of glass microbubbles is between 0.5% by weight and 2% by weight of the composition.
Microbubbles may also be made from any ceramic composition including silica-alumina compositions. Examples of ceramic microbubbles include Z-LIGHT SPHERES™ ceramic microspheres (3M Corporation, Minneapolis, Minn.).
The grout compositions comprising microspheres have several advantages. The spherical shape and particle size of the microspheres do not adversely affect the viscosity and flow characteristics of the composition. Additionally, the compositions exhibit improved clean-up properties, relative to similar compositions that do not include the microspheres. For example, the composition of Example 5 containing K-1 SCOTCHLITE™ glass bubbles requires significantly less water and time to clean off of the face of ceramic flooring tile after application and drying. Depending upon the composition, water may be all that is required for clean-up. In some cases, polar organic solvents such as isopropyl alcohol maybe employed to remove excess or misplaced compositions. U.S. Pat. No. 5,360,489 describes one method of removing compositions from a substrate. Commonly known or practiced methods can be used as well.
Other properties that microspheres can impart to polymer/grout compositions include lower weight, reduced shrinkage, and improved thermal insulation. Additionally, microspheres can reduce viscosity and lower surface gloss of the polymer/grout compositions.
Furthermore, grout compositions comprising microspheres can be applied from the pressurized container of the present invention.
Other Ingredients
In addition to the polymeric resin, the microspheres, and the first and second mineral fillers, the grout composition can include a variety of other ingredients. Such ingredients include ingredients that are known by skilled artisans to be useful additives for grouts, cements, concretes, and filled plastics. Examples of suitable ingredients include polymer-soluble dyes, colorants, solvents, antifoams, wetting agents, biocides, sealants, thickening agents, drying rate modulators, coupling agents, stabilizers, plasticizers, flow modifiers, lubricants, and additional fillers. Selection of such additives and suitable amounts thereof is within the ken of the skilled artisan in this field, and can be made depending on the composition and properties of a particular grout and its desired use.
One or more colorants can be incorporated into the grout composition in order to impart a desired color to the grout composition, to the finished grout, or both. The colorant can be a particulate (e.g., one of the first and second mineral fillers, or the microspheres) or a compound that is soluble in one or more of the solvents in the grout composition. The colorant should be substantially uniformly dispersed or dissolved throughout the grout composition, in order to avoid color variations in the finished grout. Particulate colorants (i.e., pigment particles) and polymer-soluble dyes can be used interchangeably or in combination, depending on the desired effect. For example, particulate, polymer-insoluble colorants should be used when a finished grout having non-colored matrix containing colored particles is desired. Examples of suitable colorants include titanium dioxide (a white mineral particulate), carbon black (a black mineral particulate), and anthraquinone and azo dyes (polymer-soluble colorants).
In addition to the solvent(s) of the polymeric resin, the grout composition can include one or more other solvents. The additional solvent(s) should be miscible with the solvent(s) of the polymeric resin, in order to avoid phase separation during processing, packaging, storage, or use. The additional solvents can be more or less volatile than the solvent(s) of the polymeric resin, and can therefore affect the drying/curing rate of the grout composition. For example, the additional solvents can include both relatively volatile solvents (e.g., mineral spirits) and less volatile solvents (e.g., water). In addition to their effects on the grout composition, additional solvents can aid in preparation of the composition, for example, by suspending or dissolving a component of the composition prior to its mixing with the other components of the grout composition. The ability of the solvent to wet the surface of the microspheres may also affect the clean-up properties of the applied and dried grout.
The grout composition can include one or more antifoaming agents in order to inhibit formation of foam during preparation of the composition. Inhibiting foam formation can decrease the amount of air suspended in the composition during mixing and ensure that ingredients added to the composition are mixed therewith. An example of a suitable antifoaming agent is the FOAMASTER (RTM) III product available from Congis Corporation (Cincinnati, Ohio).
One or more wetting agents can be included in the composition in order to enhance contact of particulates (e.g., the first and second mineral fillers) with the polymers and other ingredients of the grout composition. Binding of the polymers with the particulates and/or envelopment/encapsulation/coating of the particulates by the polymers enhances the uniformity of the grout composition and the unity of the dried/cured grout. This also inhibits shedding of particulates from the dried/cured grout, preserving the physical properties, texture, feel, and appearance of the grout. Examples of suitable wetting agents include detergents such as the TRITON (RTM) X-405 product available from Union Carbide Corporation (Danbury, Conn.) and dispersants such as the TAMOL (RTM) 850 product available from Rohm & Haas Company (Philadelphia, Pa.).
One or more biocides can be added to the grout composition in order to inhibit growth of microorganisms, fungi, mold, and plants in the composition and in the finished grout. Numerous biocides are known in the art and available commercially. The selection of an appropriate biocide can depend on the geographical location and intended use of the grout composition. An example of a suitable biocide is the ACTICIDE (RTM) CT product available from Acti-Chem Specialties Products (Trumbull, Conn.).
When the environment in which the grout composition is to be used includes water or other chemicals that can penetrate and harm the grout, for example, one or more sealants can be incorporated into the grout composition. Numerous sealants are known in the art and available commercially. The selection of an appropriate sealant can depend on the intended use and anticipated environment of the grout composition, as well as on the nature of the chemicals expected in such use and environment. An example of a suitable sealant is an ester of wood rosin, such as the HERCOLYN (RTM) D hydrogenated methyl ester of wood rosin product available from Loos & Dilworth, Inc. (Bristol, Pa.).
The grout composition can include one or more thickening agents to improve the consistency and/or workability of the grout composition. Numerous thickening agents are known in the art and available commercially. An example of a suitable thickening agent is the ACRYSOL (RTM) 186B product available from Rohm & Haas Company (Philadelphia, Pa.). Another suitable thickening agent is the product designated ALCOGUM (TM) L-18 acrylic emulsion copolymer, which is available from Alco Chemical (Chattanooga, Tenn.).
Drying rate modulators such as polyhydric alcohols can be added to the grout composition in order to slow the rate of drying. Such modulators can be beneficial when the environment in which the grout is to be used exhibits a low humidity or high air flow. An example of a suitable drying rate modulator is polypropylene glycol.
The grout composition can include one or more coupling agents for improving the binding or encapsulation of filler particles by the polymer(s) of the composition. Suitable coupling agents can effect covalent, ionic, or other non-covalent binding of the polymer and the particles. Many coupling agents are known in the art, and selection of an appropriate coupling agent depends on the chemical identity and form of the polymer(s) and particulate(s) present in the composition. Nonetheless, selection and addition of suitable coupling agents are within the ken of the skilled artisan in this field. Examples of suitable coupling agents include polymeric silanes and polysilazanes.
In some grout compositions comprising microspheres, it may be preferable not to include a coupling agent. For example, if the coupling agent more firmly bonds the polymer resin to the surface of the microspheres, clean up of the grout composition may be more difficult. If coupling agents are included, care should be taken in selecting the coupling agent to ensure that the composition's clean-up properties are not adversely affected. By way of example, the slower a coupling agent acts to form cross-links, the less likely it is to adversely affect clean-up. An example of an appropriate coupling agent is AP-SILANE 33™ (Advanced Polymer, Inc., Carlstadt, N.J.).
In applications in which it is desirable that the finished grout exhibit plastic properties (e.g., deformability, resilience, and/or flexibility) rather than cementitious properties alone, stabilizers, plasticizers, and/or lubricants can be included in the grout composition in order to impart their characteristic properties to the finished grout. A wide variety of plastic additives are known, and selection and incorporation of such additives depends on the chemical identity of the polymer(s) used in the grout composition and desired properties of the finished grout. Nonetheless, selection and incorporation of suitable stabilizers, plasticizers, and/or lubricants are within the ken of the skilled artisan in this field.
The grout composition can also include a water-repelling polymer. The water-repelling polymer can be substantially any polymer that is compatible with the other ingredients of the composition and that imparts hydrophobicity to the grout composition or to the finished grout. Such polymers can be used when the grout is anticipated to be installed in a wet environment or when water resistance of the finished grout is considered important.
A wide variety of suitable water-repelling polymers are known, including fluorochemical polymers, styrene maleic anhydride copolymers, and polyalkylsiloxanes such as polydimethylsiloxane. Water-repelling polymers include those sold under the SCOTCHGARD (RTM) trademark (3M Company, St. Paul, Minn.) such as product number 18961, those sold as the perfluoroalkylsulfonamide-modified urethane polymer product designated L-18961 Developmental Material (3M Company), those sold as the product designated SLR 2B (SLR, Inc., Scottsdale, Ariz.), those sold as the proprietary fluoropolymer product designated SLR-TP™ water base active (SLR, Inc.), those described in U.S. Pat. No. 6,037,429, those described in U.S. Pat. No. 4,648,904, those described in U.S. Pat. No. 4,517,375, those described in U.S. Pat. No. 5,274,159, those described in U.S. Pat. No. 5,011,713, those described in U.S. Pat. No. 6,271,289, those described in U.S. Pat. No. 6,251,984, and those described in U.S. patent application publication No. 2003/0129419 A1.
Grout Dispensers
The grout compositions described herein can be packaged in substantially any way currently known for packaging grout. The grout compositions, including those comprising microspheres, described herein exhibit significantly lower abrasiveness than prior art grouts. This property permits packaging of the grout composition described herein in ways that cannot be practically done using prior grouts.
The grout composition described herein can packaged and sold in the form of a dry powder to be mixed with a solvent (e.g., water) by the user immediately prior to use. However, because the grout composition does not begin to set immediately upon water addition, as with cementitious and epoxy-based grouts, the grout composition described herein can be stored in a fully prepared (i.e., wet) form for long periods, so long as the composition is stored in a sealed container or in a very humid atmosphere. Thus, the grout composition described herein can be packaged and sold in a ‘ready-to-use’ form. This form is particularly desirable for homeowners and non-professional masons who wish to install, repair, or replace grout in a tiled surface.
In a powdered form, the grout composition described herein can be sold in any traditional form (e.g., paper or plastic bags, plastic or metal tubs or cans, or in bulk). In a wet (i.e., fully prepared) form, the grout composition described herein can be packaged and sold in any sealed container or apparatus. For example, the wet grout composition can be sold in bulk tubs, cans, buckets, or bags suitable for traditional manual grout installation (e.g., using a trowel and float).
In a preferred embodiment, the wet grout composition is packaged and sold in a container that can be used as an applicator or as a replaceable part (e.g., a cartridge or reservoir) of an applicator. By way of example, the wet grout composition can be packaged and sold in manually squeezable tubes having a nozzle that can be inserted between tiles or urged against a tiled surface. As another example, the wet grout composition can be packaged and sold in cartridges adapted to fit a standard caulking gun or another standard cartridge-fed applicator. Many prior art grouts can also be packaged and sold in these forms.
Unlike prior art grouts, the grout composition described herein is suitable for packaging and sale in pressurized and pressurizable containers.
For example, the grout composition can be packaged and sold in a container having a sealed outlet and a compressible portion. When the outlet is unsealed and the compressible portion is compressed, the grout composition is dispensed from the outlet. Examples of such containers include the squeezable tube and cartridge embodiments described above. Other examples include a container in which a bladder or pouch which communicates with the outlet contains the grout composition. Application of pressure to the exterior of the bladder or pouch (e.g., by pressurization of the container or by the action of a pressurized second bladder on the grout-containing bladder) forces the grout composition to be dispensed from the outlet. The outlet can be sealed with a valve in order to regulate dispensing of the grout.
In a preferred embodiment, the grout composition is contained within a pressurized container having a valved outlet in communication with the interior thereof. When the valve is actuated, the grout composition is dispensed from the container by way of the outlet. The outlet can fluidly communicate with a nozzle to facilitate controlled or directed release of the grout composition.
Because the grout composition described herein is substantially incompressible (or, at most, not very compressible), the pressurized container must include a pressure source. Substantially any pressure source suitable for use with a sealed container can be used. Examples of suitable pressure sources include compressed springs, compressed gas, and gas-generating chemical reactions. Compressed gas is a preferred pressure source.
Compressed gas can directly contact the grout composition, in which instance the container should generally be used in an inverted position, so that gravity draws the grout composition to the bottom of the container, covering the outlet. However, this configuration requires careful manipulation of the container and can limit the containers use to only certain geometric orientations, decreasing ease of use. Furthermore, compressed gas can generate a path through the grout composition to the outlet, leaving a substantial portion of the grout in the container undeliverable. For this reason, it is preferred that compressed gas in the container either be retained behind a solid structure (e.g., a slidable piston) or contained within a closed compartment (e.g., a sealed, flexible bladder) within the container. Pressure imparted by the compressed gas upon the solid structure or compartment can be transmitted to the grout composition if the structure or compartment also contacts the grout composition. In one embodiment, the solid structure is a piston that separates a compressed gas from the grout composition. The piston can, for example, be a substantially planar disk or cup-shaped. An expandable bladder can be used in combination with a piston or other solid structure, if desired.
A suitable nozzle has a portion adapted to fit the outlet of the container and a dispensing end for directing flow of the grout composition. The dispensing end can have a shape adapted to fit between ceramic tiles (i.e., partially or entirely within the gap between tiles). Alternatively, the dispensing end can be shaped simply to direct a stream or spray of the grout composition in a selected direction.
The nozzle can have a shaping edge disposed thereon (e.g., adjacent the orifice), wherein the shaping edge has a shape designed to impart a particular shape (e.g., a concave rounded shape) to the surface of dispensed grout by sliding the shaping edge along the surface.
The nozzle can also have a stabilizing member formed or applied thereon. The stabilizing member is designed to contact the tiled surface in a manner such that when the stabilizing member is pressed or slid against the surface, the dispensing end of the nozzle directs dispensed grout into a crack between tiles. The shape of the stabilizing member is not critical. It will generally include a planar face for sliding against the tiled surface and can also (or instead) have a raised portion for insertion within an inter-tile crack, to direct sliding of the nozzle along the crack. In one embodiment, the stabilizing member has the appearance of a short “ski” with a raised bump on the planar “bottom” of the ski. In this embodiment, the bump is inserted into an inter-tile crack, and the nozzle is drawn along the length of the crack. The planar portion of the ski maintains the dispensing end of the nozzle in a position in which grout dispensed therefrom is directed into the crack. The stabilizing member can be a unitary part of the nozzle or, for example, a removable piece which can be clipped onto the nozzle to accommodate both left-handed and right-handed users.
Grout Preparation
The grout composition described herein can be made by combining the components thereof and mixing them, preferably very thoroughly. So long as the mixed composition is not permitted to dry, it can be stored indefinitely prior to application. Preferably, the grout composition is packaged into a sealed container, such as one of those described herein.
The order of addition of the ingredients of the composition is not critical. However, the final wet composition can be significantly more viscous than its ingredients. As a matter of convenience and processibility, it can be preferable to first mix some or all liquid ingredients prior to addition of the particulate ingredients, such as the mineral fillers. By way of example, the polymeric resin can first be combined with the ingredients to be incorporated at relatively low levels (e.g., antifoam, wetting agents, biocides, etc.) and other solvents as an initial step. Addition of any dye or colorant can be made to the liquid components of the composition while the liquids are at their least viscous stage, so that thorough mixing can occur and the color of the final grout composition can be as uniform as possible. Alternatively, any dye or colorant can be mixed at an early stage with the polymeric resin (and with any other ingredient with which mixing of the dye or colorant can be most difficult), and addition of other components can be suspended until satisfactory mixing is achieved. Multiple particulate or powdered ingredients can be pre-mixed prior to combining them with liquid ingredients.
Compositions containing microspheres have no special mixing requirements, and can be handled as described above. However, compositions including microbubbles (especially those having thin walls), it is preferred to add the microbubbles to the liquid portions of the formula prior to adding the mineral filler components. The thin walls of low density inorganic microbubbles can be brittle and therefore, care should be taken not to “crush” the microbubbles during the mixing process—high sheer mixing should be avoided. Low density microbubbles can become easily airborne during handling and generation of static charges. Care should be taken to prevent air born dusting from occurring while adding the low density microbubbles. A static eliminator is recommended to prevent static charge build-up. Once the microbubbles are incorporated, the mineral filler components are added while the composition is mixed. Alternatively, depending upon the composition, the microbubbles may also be pre-mixed with the other dry ingredients prior to combining them with liquid ingredients.
The invention is now described with reference to the following Examples. These Examples are provided for the purpose of illustration only, and the invention is not limited to these Examples, but rather encompasses all variations which are evident as a result of the teaching provided herein.
Grout Composition
A grout composition suitable for packaging in a pressurized container was made as follows. 557.49 Pounds of RHOPLEX (RTM) 2200 acrylic latex suspension was mixed with 168.23 pounds of RHOPLEX (RTM) A-920 acrylic latex suspension. As mixing continued, 0.98 pound of FOAMASTER (RTM) III antifoam, 6 pounds of TRITON (RTM) X-405 detergent, 1.56 pounds of ACTICIDE (RTM) CT bactericide/fungicide, and 8.06 pounds of TAMOL (RTM) 850 dispersant were added to the mixture. 14.18 Pounds of HERCOLYN (RTM) D hydrogenated methyl ester of wood rosin was combined with 14.67 pounds of mineral spirits, and that combination was added to the mixture. Thereafter, 28.36 pounds of titanium dioxide R706 (DuPont, Wilmington, Del.) and 800 pounds of calcium carbonate having an average particle size smaller than 100 micrometers (calcium carbonate product G260, J.M. Huber Corp., Marble Hill, Ga.) were added to the batch, with mixing. Next, 112.48 pounds of water, 25.43 pounds of propylene glycol (99.8% pure; Interstate Chemical Corp., Hermitage, Pa.) and 21.64 pounds of ACRYSOL (RTM) 186B thickener were added to the mixture. Finally, 700 pounds of calcium carbonate having an average particle size greater than 100 micrometers (calcium carbonate product 40-200, Imerys Actives Group, Roswell, Ga.) were added, and the mixture was thoroughly mixed.
Flexible Grout Composition
A second grout composition suitable for packaging in a pressurized container was made as follows. 795.00 Pounds of RHOPLEX (RTM) A-920 acrylic latex suspension was mixed with 15.187 pounds of TRITON (RTM) X-405 detergent, 2.0 pounds of ACTICIDE (RTM) CT bactericide/fungicide, 18.917 pounds of propylene glycol (99.8% pure; Interstate Chemical Corp., Hermitage, Pa.), 4.0 pounds of TAMOL (RTM) 850 dispersant, 2.043 pounds of tripotassium phosphate, 15.542 pounds of mineral spirits, 1.776 pounds of AP-SILANE 33™ (Advanced Polymer, Inc., Carlstadt N.J.), 9.50 pounds of ACRYSOL (RTM) TT615 thickener, 87.22 pounds of water, 20.547 pounds of titanium dioxide R706 (DuPont, Wilmington, Del.), 1100 pounds of calcium carbonate having an average particle size smaller than 100 micrometers (calcium carbonate product G260, J.M. Huber Corp., Marble Hill, Ga.), and 630 pounds of calcium carbonate having an average particle size greater than 100 micrometers (calcium carbonate product 40-200, Imerys Actives Group, Roswell, Ga.) were added, and the mixture was thoroughly mixed. Thereafter, the pH was adjusted to 7.4-8.8 by addition of 4.0 pounds of ammonium hydroxide and further thorough mixing under vacuum.
When applied and dried, this grout composition exhibits greater flexibility than does the grout composition of Example 1. This grout composition is useful in traditional grout applications and in applications in which grout flexibility is important. By way of example, this grout is useful in ‘floating floor’ applications, in which discrete panels (e.g., panels having laminated wood or ceramic tiles thereon) are laid atop (but not adhered to) a solid substrate so that the panels interlock with one another. This grout composition can be used to fill interstices between the panels or tiles thereon. The flexibility of the grout composition accommodates minor movement, shifting, and settling that occurs in floating floor panels, without significantly splitting, cracking, or peeling away from the panels or tiles.
Grout Composition Having Improved Clean-Up Properties
A grout composition having improved clean-up properties is made as follows. 557.49 Pounds of RHOPLEX (RTM) 2200 acrylic latex suspension is mixed with 168.23 pounds of RHOPLEX (RTM) A-920 acrylic latex suspension. As mixing continues, 0.98 pound of FOAMASTER (RTM) III antifoam, 6 pounds of TRITON (RTM) X-405 detergent, 1.56 pounds of ACTICIDE (RTM) CT bactericide/fungicide, and 8.06 pounds of TAMOL (RTM) 850 dispersant are added to the mixture. 14.18 Pounds of HERCOLYN (RTM) D hydrogenated methyl ester of wood rosin is combined with 14.67 pounds of mineral spirits, and that combination is added to the mixture. Thereafter, 49 pounds of K-1 SCOTCHLITE™ glass bubbles (3M Corporation, Minneapolis, Minn.) is carefully added with mixing, followed by 28.36 pounds of titanium dioxide R706 (DuPont, Wilmington, Del.) and 800 pounds of calcium carbonate having an average particle size smaller than 100 micrometers (calcium carbonate product G260, J.M. Huber Corp., Marble Hill, Ga.). Next, 112.48 pounds of water, 25.43 pounds of propylene glycol (99.8% pure; Interstate Chemical Corp., Hermitage, Pa.) and 21.64 pounds of ACRYSOL (RTM) 186B thickener are added to the mixture. Finally, 700 pounds of calcium carbonate having an average particle size greater than 100 micrometers (calcium carbonate product 40-200, Imerys Actives Group, Roswell, Ga.) is added, and the mixture is thoroughly mixed.
Flexible Grout Composition Having Improved Clean-Up Properties
A second grout composition having improved clean-up properties is made as follows. 795.00 Pounds of RHOPLEX (RTM) A-920 acrylic latex suspension is mixed with 15.187 pounds of TRITON (RTM) X-405 detergent, 2.0 pounds of ACTICIDE (RTM) CT bactericide/fungicide, 18.917 pounds of propylene glycol (99.8% pure; Interstate Chemical Corp., Hermitage, Pa.), 4.0 pounds of TAMOL (RTM) 850 dispersant, 2.043 pounds of tripotassium phosphate, 15.542 pounds of mineral spirits, 1.776 pounds of AP-SILANE 33™ (Advanced Polymer, Inc., Carlstadt N.J.), 9.50 pounds of ACRYSOL (RTM) TT615 thickener, and 87.22 pounds of water. 55 Pounds of K-1 SCOTCHLITE™ glass bubbles (3M Corporation, Minneapolis, Minn.) is carefully added with mixing, followed by 20.547 pounds of titanium dioxide R706 (DuPont, Wilmington, Del.). Thereafter, 1100 pounds of calcium carbonate having an average particle size smaller than 100 micrometers (calcium carbonate product G260, J.M. Huber Corp., Marble Hill, Ga.), and 630 pounds of calcium carbonate having an average particle size greater than 100 micrometers (calcium carbonate product 40-200, Imerys Actives Group, Roswell, Ga.) are added, and the mixture is thoroughly mixed. Thereafter, the pH is adjusted to 7.4-8.8 by addition of 4.0 pounds of ammonium hydroxide and mixing is continued under vacuum.
Sanded Grout Composition Having Improved Clean-Up Properties
Another grout composition having improved clean-up properties was made as follows. 615.49 Pounds of BASF ACORONAL(RTM) NX4787X butylacrylate/styrene copolymer dispersion was mixed with 111.23 pounds of BASF ACRONAL(RTM) V275 acrylic/vinyl acetate copolymer dispersion, 3.125 of SLR-TP water based active polymer dispersion (SLR Inc., Scottsdale, Ariz.), and 25 pounds of water repellant polymer dispersion L-18961 (3-M Corporation, Minneapolis, Minn.). As mixing continued, 0.98 pound of FOAMASTER (RTM) III antifoam, 6 pounds of TRITON (RTM) X-405 detergent, 1.56 pounds of ACTICIDE (RTM) CT bactericide/fungicide, 8.06 pounds of TAMOL (RTM) 850dispersant, and 14.67 Pounds of mineral spirits were added to the mixture. Thereafter, 35 pounds of K-1 SCOTCHLITE™ glass bubbles (3M Corporation, Minneapolis, Minn.) was carefully added and then mixed, followed by 28.36 pounds of titanium dioxide R706 (DuPont, Wilmington, Del.) and 800 pounds of calcium carbonate having an average particle size smaller than 100 micrometers (calcium carbonate product G260, J.M. Huber Corp., Marble Hill, Ga.). Next, 112.48 pounds of water, 25.43 pounds of propylene glycol (99.8% pure; Interstate Chemical Corp., Hermitage, Pa.) and 70 pounds of ALCOGUM (RTM) L-18 thickener were added to the mixture. Finally, 50 pounds of fine silica sand F-95 having an average particle size of about 150 micrometers (U.S. Silica Company, Ottawa, Ill.) was added, and the mixture thoroughly mixed.
This grout composition was then used to grout ceramic floor tile. After the grout had adequately dried, the composition was easy to clean and required less water and time to clean off the face of the ceramic floor tile than the composition not containing the microspheres.
The disclosure of every patent, patent application, and publication cited herein is hereby incorporated herein by reference in its entirety.
While this invention has been disclosed with reference to specific embodiments, it is apparent that other embodiments and variations of this invention can be devised by others skilled in the art without departing from the true spirit and scope of the invention. The appended claims include all such embodiments and equivalent variations.
This application is a continuation-in-part of U.S. patent application Ser. No. 10/669,991, filed Sep. 24, 2003, which is incorporated herein in its entirety.
Number | Date | Country | |
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Parent | 10669991 | Sep 2003 | US |
Child | 10951061 | Sep 2004 | US |