Patent Application
20140295173
The present invention relates to a pigmented paper coating with improved brightness.
Titanium dioxide (TiO2) is used as a pigment in paperboard coatings on darker substrates such as recycled board and unbleached Kraft board to improve the optical properties such as brightness, opacity, and appearance. In addition, TiO2 is used in lightweight coated paper to improve opacity, or in premium coated paper grades to improve the brightness and appearance. Motivated by the high cost of TiO2, papermakers are looking for ways to either reduce its usage or improve its efficiency or both.
In the absence of modifiers such as dispersants, TiO2 particles will crowd, leading to inefficient hiding. However, even with well dispersed TiO2 there can be crowding of TiO2 particles as the level of TiO2 is increased. Furthermore, it is known, for example, (2001 TAPPI Coating Conference Paper by Imerys on “Optimum Dispersion In Blade Coating Operations;” also, Chapter 3 on “Inorganic Salt Dispersants” in Practical Dispersion: A Guide to Understanding and Formulating Slurries by R. F. Conley, Wiley Press) that over-dispersing of a coating will cause pigment particles to flocculate, which can lead to an improvement in coating brightness on the order of 0.5 to 1.5 points. This improvement in brightness, however, is attributed to an increase in the porosity of the coating, which increases the amount of light scattering from air voids, and not to the increased efficiency of TiO2 dispersion in the coating. Furthermore, the brightness advantage realized from using high levels of dispersants is greatly reduced after calendaring to less than 1 point because the voids created upon the addition of the dispersant are removed during the calendaring process.
U.S. Pat. No. 8,043,476 discloses a paper or paperboard coating formulation with improved viscosity stability comprising a phosphate or phosphonate functionalized acrylic polymer binder, TiO2, and a polyphosphate dispersant. Although the phosphate or phosphonate functionality is known to enhance adsorptivity of the binder to the TiO2, thereby improving the efficiency of its usage, the presence of phosphates or phosphonates often adversely affect viscosity stability of the binder and water sensitivity of the coating. Moreover, latexes prepared with the commonly used phosphate monomer, phosphoethyl methacrylate (PEM), invariably contain impurities that are of concern to governmental regulatory agencies (e.g., the FDA) that regulate products that may come in contact with food. Accordingly, it would be an advance in the art of paper and paperboard coating formulations to design a coating with enhanced brightness that does not require the presence of phosphate and phosphonate functionalized binders.
The present invention addresses a need in the art by providing a laminate comprising coated or uncoated paperboard; and a 5- to 35-μm thick layer of a film adhered to the coated or uncoated paper or paperboard; wherein the film comprises a) from 3 to 25 weight percent of a polymeric binder; b) from 5 to 35 weight percent TiO2; and c) from 0.05 to 2 weight percent tetrapotassium pyrophosphate; wherein the polymeric binder comprises vinyl acetate, vinyl-acrylic, styrene-acrylic, or styrene-butadiene polymer, and blends thereof; and wherein the weight percentages are all based on the weight of the film.
In another aspect, the present invention is a method comprising the step of applying a 5- to 35-μm thick layer of a composition to paper or paperboard, wherein the composition comprises an aqueous dispersion of a) from 3 to 25 weight percent polymeric binder particles; b) from 5 to 35 weight percent TiO2; and c) from 0.05 to 2 weight percent of tetrapotassium pyrophosphate; wherein the polymeric binder particles comprise vinyl acetate, vinyl-acrylic, styrene-acrylic, or styrene-butadiene polymer particles, and blends thereof; and wherein the weight percentages are all based on the weight of total solids of the composition.
The potassium pyrophosphate containing film shows improved brightness with a variety of binders and grades of TiO2 as compared with films containing other ostensibly similar dispersants.
The present invention addresses a need in the art by providing a laminate comprising coated or uncoated paperboard; and a 5- to 35-μm thick layer of a film adhered to the coated or uncoated paper or paperboard; wherein the film comprises a) from 3 to 25 weight percent of a polymeric binder; b) from 5 to 35 weight percent TiO2; and c) from 0.05 to 2 weight percent tetrapotassium pyrophosphate; wherein the polymeric binder comprises vinyl acetate, vinyl-acrylic, styrene-acrylic, or styrene-butadiene polymer, and blends thereof; and wherein the weight percentages are all based on the weight of the film.
Preferably, the weight percent of the binder, based on the weight of total solids of the composition, is from 5 to 25 weight percent. The binder may contain up to 8 weight percent phosphate or phosphonate groups but preferably comprises a substantial absence of these groups. As used herein, the term “substantial absence of phosphate or phosphonate groups” means that the binder particles contain, based on the weight of the binder, less than 0.05 weight percent, preferably less than 0.01 weight percent, more preferably less than 0.001 weight percent, and most preferably 0 weight percent phosphate and phosphonate groups.
The aqueous composition preferably comprises from 5 to 25 weight percent, more preferably to 20 weight percent, and most preferably to 15 weight percent TiO2, based on the weight of total solids of the composition; the TiO2 can be rutile or anatase TiO2 and may be untreated, or treated with inorganic silica or alumina or zirconia or a combination thereof.
The tetrapotassium pyrophosphate is preferably present in the composition at 0.1 to 0.8 weight percent, based on the weight of the composition.
The composition of the present invention advantageously includes other additives including auxiliary pigments, such as clays and calcium carbonate; rheology modifiers; hollow sphere pigments, such as ROPAQUE™ AF-1055 Hollow Sphere Pigment (A Trademark of The Dow Chemical Company or its Affiliates); natural binders, such as proteins and starch; optical brightening agents; lubricants; antifoamers; crosslinkers; and other dispersants, such as polyacrylic acid based dispersant. The particle size of auxiliary pigments useful for the composition of the present invention is preferably finer than 2 μm, more preferably 80% to 100% by weight finer than 2 μm, as measured using Sedigraph. This preferred size range is considerably smaller than what is typically used in paint formulations.
The film thickness is preferably in the range of from 5 μm, more preferably from 10 μm, to 35 μm, more preferably to 20 μm, which is about one-third to one-tenth the film thickness of typical paint coatings.
In a second aspect, the present invention is a method comprising the step of applying a 5- to 35-μm thick layer of a composition to paper or paperboard, wherein the composition comprises an aqueous dispersion of a) from 3 to 25 weight percent polymeric binder particles; b) from 5 to 35 weight percent TiO2; and c) from 0.05 to 2 weight percent of tetrapotassium pyrophosphate; wherein the polymeric binder particles comprise vinyl acetate, vinyl-acrylic, styrene-acrylic, or styrene-butadiene polymer particles, and blends thereof; and wherein the weight percentages are all based on the weight of total solids of the composition. The binder particles preferably have a volume average particle size in the range of from 50 nm, more preferably from 80 nm, to 500 nm, more preferably to 300 nm.
It has surprisingly been discovered that the laminate of the present invention imparts brightness to the paper or paperboard without additional loadings of TiO2, and preferably using binder that contains a substantial absence or complete absence of phosphate and phosphonate groups. Moreover, as the following examples demonstrate, it has surprisingly been discovered that paper or paperboard coated with pigmented films containing TKPP consistently provide superior brightness compared to films containing ostensibly similar dispersants (TSPP or KTPP). This trend of superiority was generally observed across a variety of binders and TiO2 types.
RPS TiO2 (10.5 parts by weight, 70.58% solids) was added to Clay (89.5 parts by weight, 68.24% solids), followed by addition of Vinyl Acrylic Latex (20 parts by weight, 49.8% solids), then TKPP (0.3 parts by weight, 5% solids). Additional DI water was added to adjust percent solids to 45%. The pH was then adjusted to 8-8.5 with NaOH followed by addition of RM-232D (0.6 parts by weight, 28.27% solids).
RPS TiO2 (10.5 parts by weight, 70.58% solids) was added to Clay (89.5 parts by weight, 68.24% solids), followed by addition of Vinyl Acrylic Latex (20 parts by weight, 49.8% solids). Additional DI water was added to adjust percent solids to 45%. The pH was then adjusted to 8-8.5 with NaOH followed by addition RM-232D (0.6 parts by weight, 28.27% solids).
The method of Example 1 was used except that TSPP (0.3 parts by weight, 5% solids) was used as the dispersant instead of TKPP.
The method of Example 1 was used except that KTPP (0.3 parts by weight, 5% solids) was used as the dispersant instead of TKPP.
RPS TiO2 (10.5 parts by weight, 70.58% solids) was added to Clay (89.5 parts by weight, 68.24% solids), followed by the addition of Styrene Acrylic Latex (20 parts by weight, 46.5% solids), then TKPP (0.8 parts by weight, 5% solids). Additional DI water was added to adjust solids to 45%. The pH was then adjusted to 8-8.5 with NaOH followed by addition of RM-232D (0.2 parts by weight, 28.27% solids).
RPS TiO2 (10.5 parts by weight, 70.58% solids) was added to Clay (89.5 parts by weight, 68.24% solids), followed by addition of Styrene Acrylic Latex (20 parts by weight, 46.5% solids). Additional DI water was added to adjust solids to 45%. The pH was then adjusted to 8-8.5 with NaOH followed by addition of 0.2 parts of RM-232D (28.27% solids).
The method of Example 2 was used except that TSPP (0.8 parts by weight, 5% solids) was used as the dispersant instead of TKPP.
The method of Example 2 was used except that KTPP (0.8 parts by weight, 5% solids) was used as the dispersant instead of TKPP.
Example 3 and Comparative Examples 7-9 use the Vinyl Acrylic Latex binder with the 2063 TiO2 which has a lower purity of TiO2 and a higher concentration of inorganic alumina surface treatment compared to the RPS TiO2.
2063 TiO2 (10.5 parts by weight, 77.8% solids) was added to Clay (89.5 parts by weight, 68.24% solids), followed by addition of Vinyl Acrylic Latex (20 parts by weight, 49.8% solids), then TKPP (0.3 parts by weight, 5% solids). Additional DI water was added to adjust percent solids to 45%. The pH was then adjusted to 8-8.5 with NaOH followed by addition of RM-232D (0.6 parts by weight, 28.27% solids).
2063 TiO2 (10.5 parts by weight, 77.8% solids) was added to Clay (89.5 parts by weight, 68.24% solids), followed by addition of Vinyl Acrylic Latex (20 parts by weight, 49.8% solids. Additional DI water was added to adjust percent solids to 45%. The pH was then adjusted to 8-8.5 with NaOH followed by addition of RM-232D (0.6 parts by weight, 28.27% solids).
The method of Example 3 was used except that TSPP (0.3 parts by weight, 5% solids) was used as the dispersant instead of TKPP dispersant.
The method of Example 3 was used except that KTPP (0.3 parts by weight, 5% solids) was used as the dispersant instead of TKPP dispersant.
Example 4 and Comparative Examples 10-12 use the Vinyl Acrylic Latex binder with R-746 TiO2, which is an alumina- and silica-surface treated TiO2 of reduced purity compared to RPS TiO2.
R-746 TiO2 (10.5 parts by weight, 76.81% solids) was added to Clay (89.5 parts by weight, 68.24% solids), followed by addition of Vinyl Acrylic Latex (20 parts by weight, 49.8% solids), then TKPP (0.3 parts by weight, 5% solids). Additional DI water was added to adjust percent solids to 45%. The pH was then adjusted to 8-8.5 with NaOH followed by addition of RM-232D (0.6 parts by weight, 28.27% solids).
R-746 TiO2 (10.5 parts by weight, 76.81% solids) was added to Clay (89.5 parts by weight, 68.24% solids), followed by addition of Vinyl Acrylic Latex (20 parts by weight, 49.8% solids). Additional DI water was added to adjust percent solids to 45%. The pH was then adjusted to 8-8.5 with NaOH followed by addition of RM-232D (0.6 parts by weight, 28.27% solids).
The method of Example 4 was used except that TSPP (0.3 parts by weight, 5% solids) was used as the dispersant instead of TKPP dispersant.
The method of Example 4 was used except that KTPP (0.3 parts by weight, 5% solids) was used as the dispersant instead of TKPP dispersant.
RPS TiO2 (9 parts by weight, 70.58% solids) and AF-1055 (2.16 parts by weight, 26.61% solids) were added to Clay (88.6 parts by weight, 68.24% solids), followed by addition of Vinyl Acrylic Latex (20 parts by weight, 49.8% solids), then TKPP (0.24 parts by weight, 5% solids). Additional DI water was added to adjust percent solids to 45%. The pH was then adjusted to 8-8.5 with NaOH followed by addition of RM-232D (0.6 parts by weight, 28.27% solids).
RPS TiO2 (9 parts by weight, 70.58% solids) and AF-1055 (2.4 parts by weight, 26.61% solids) were added to Clay (88.6 parts by weight, 68.24% solids), followed by addition of Vinyl Acrylic Latex (20 parts by weight, 49.8% solids). Additional DI water was added to adjust percent solids to 45%. The pH was then adjusted to 8-8.5 with NaOH followed by addition of RM-232D (0.6 parts by weight, 28.27% solids).
The coatings were manually applied to a Leneta paint scrub panel substrate using a wire wound rod #12 and then were dried at 83° C. for 3 min. Brightness measurements were performed using Technidyne Micro S-5 Brightmeter. Brightness calibration was done using a standard (84.7 brightness reading) before measurements. Five measurements per sample were recorded and the median values reported in Table 1. The brightness data for Examples 1-2 and Comparative Examples 1-6 (C1-C6) are shown in Table 1:
The results show that the films containing TKPP (Examples 1 and 2) exhibits superior brightness as compared with the films containing TSPP (C2 and C5); the results further show that TKPP is better than KTPP for the styrene acrylate binder. The TKPP coatings (Ex 1 and 2) show about 5-6 point improvement in brightness compared to the coating with no dispersant (C1 and C4) while the TSPP coatings show only about a 3-4 point improvement in brightness.
To compare the effects of a modified TiO2 on the performance of the coating, coated substrates were prepared using two types of surface treated TiO2: an alumina treated TiO2 (2063) and a silica and alumina treated TiO2 (R 746). 2063 TiO2 based coatings were made with a) TKPP (Example 3); b) no dispersant (C7); c) TSPP (C8); and d) KTPP (C9). R-746 TiO2 based coatings were made with a) TKPP (Example 4); b) no dispersant (C10); c) TSPP (C11); and d) KTPP (C12).The results are summarized in Table 2.
The data show that the film containing TKPP dispersant and alumina-treated TiO2 (2063) (Example 3) exhibits brightness superior to the comparative films. The film containing TSPP (C8) exhibits no improvement in brightness compared to the film with no dispersant (C7), while the film containing KTPP (C9) exhibits about a 1 point increase in brightness. By comparison the TKPP film exhibits about a 3 point increase in brightness with this alumina-modified TiO2.
A similar trend is observed in alumina and silica surface treated TiO2 (R-746) where the film containing TKPP shows brightness superior to the comparative films. The film containing TKPP dispersant (Example 4) shows about a 4 point increase in brightness compared to the film with no dispersant (C10). By comparison, the films containing TSPP (C11) and KTPP (C12) show about a 3 point increase in brightness.
To compare the effects of TKPP in films containing TiO2 and hollow spherical pigment, two coatings were prepared: a) a coating containing RPS TiO2, AF-1055 and TKPP (Example 5) and b) a coating containing RPS TiO2 and AF-1055 (C13). The results in Table 3 indicate a superior brightness performance of coatings containing TKPP (Example 3) over the coatings without TKPP (C13). Specifically, the film containing TKPP exhibits a brightness increase of about 4 points over the film without TKPP.
It has surprisingly been discovered that paper or paperboard coated with pigmented films containing TKPP consistently provided superior brightness compared to films containing ostensibly similar dispersants. This trend of marked superiority was generally observed across a variety of binders and TiO2.
| Number | Date | Country | |
|---|---|---|---|
| 61805638 | Mar 2013 | US |
