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LOW VOC UNIVERSAL COLORANT COMPOSITIONS

20230416542 ยท 2023-12-28

    Inventors

    Cpc classification

    International classification

    Abstract

    A universal colorant composition compatible to tint water-borne and solvent-borne base paints and stains. The universal colorant composition includes one or more modified polyether dispersants with one or more pigment affinic groups, which wet, disperse, and stabilize the disperse included pigments. The universal colorant compositions provide for low viscosity drop and excellent compatibility when the colorant composition is used to tint a base paint or stain.

    Claims

    1-35. (canceled)

    36. A universal colorant composition comprising: an aqueous vehicle, one or more pigments or dyes, and a modified polyether dispersant containing one or more pigment affinic groups; wherein the polyether dispersant includes one or more polyoxyalkyl, substituted or unsubstituted polyoxyphenyl, polyetherketone, polyetheretherketone, cyclic ether, or combinations thereof, and wherein the pigment affinic groups are each a saturated or unsaturated aliphatic or aromatic structural unit containing a plurality of carbon atoms; wherein the modified polyether dispersant has a peak weight average molecular weight of at least 1000 g/mol; wherein the universal colorant composition is substantially free of low molecular weight surfactants; wherein the universal colorant composition is compatible with water-borne and solvent-borne base paints and stains and is suitable for use in a point-of-sale tinting machine; and wherein the colorant composition contains less than a film-forming amount of binder.

    37. The universal colorant composition of claim 36, wherein the colorant compositions are substantially free of surfactants.

    38. The universal colorant composition of claim 36, wherein the colorant composition comprises a first modified polyether dispersant containing one or more pigment affinic groups; and a second modified polyether dispersant containing one or more pigment affinic groups; wherein the one or more pigment affinic groups of the first modified polyether dispersant are the same or different from the one of more pigment affinic groups of the second modified polyether dispersant.

    39. The universal colorant composition of claim 36, wherein the polyether dispersant includes oxymethyl, oxyethyl, oxypropyl, or oxybutyl polyalkyl structural groups.

    40. The universal colorant composition of claim 39, wherein the polyether dispersant includes oxyethyl structural groups.

    41. The universal colorant composition of claim 36, wherein the polyether includes tetrahydrofuran or oxirane groups.

    42. The universal colorant composition of claim 36, wherein the one or more modified polyether dispersants are present in a total amount of at least 2 weight percent based on the wet weight of the colorant composition.

    43. The universal colorant composition of claim 36, wherein the one or more modified polyether dispersants are present in a total amount of at most 20 weight percent based on the wet weight of the colorant composition.

    44. The universal colorant composition of claim 36, wherein at least one pigment affinic groups include a linear or branched aliphatic chain having at least 4 carbons.

    45. The universal colorant composition of claim 36, wherein at least one pigment affinic groups include an aromatic group.

    46. The universal colorant composition of claim 36, wherein at least one pigment affinic groups include a branched or unbranched C10 alkyl chain.

    47. The universal colorant composition of claim 36, wherein at least one pigment affinic groups include a saturated or unsaturated fatty acid having at least 14 carbon atoms.

    48. The universal colorant composition of claim 36, wherein at least one pigment affinic groups include a saturated or unsaturated fatty acid having at least 18 carbon atoms.

    49. The universal colorant composition claim 47, wherein at least one pigment affinic groups include an unsaturated oleic or linoleic fatty acid.

    50. The universal colorant composition of claim 36, wherein the dispersant has a mole ratio of pigment affinic groups to polyoxylalkyl groups is at least 1:20.

    51. The universal colorant composition of claim 36, wherein the pigments or dyes are present in an amount of at least 2 weight percent based on the wet weight of the colorant composition.

    52. The universal colorant composition of claim 36, wherein the one or more pigments or dyes are present in an amount of at most about 90 weight percent based on the wet weight of the colorant composition.

    53. The universal colorant composition of claim 36, wherein the composition contains less than 50 g/L VOC.

    54. The universal colorant composition of claim 36, wherein the modified polyether dispersant has a peak weight average molecular weight of at least 1500 g/mol.

    55. The universal colorant composition of claim 36, wherein the universal colorant further comprises a phospho-lipid.

    56. The universal colorant composition of claim 54, wherein the phospho-lipid is a lechitin.

    57. The universal colorant composition of claim 36, wherein the pigment-to-dispersant ratio is at least 1.

    58. The universal colorant composition of claim 36, wherein the pigment-to-dispersant ratio is at most 20.

    Description

    DETAILED DESCRIPTION

    [0052] Disclosed are universal colorant compositions for custom-tinting both water-borne and solvent-based base paints and stains. Universal colorant compositions of the present disclosure include at least one dispersant with pigment affinic groups to wet, disperse, and stabilize the pigment both in the colorant composition and in a base paint or stain following tinting. Colorant compositions including the dispersant with pigment affinic groups in some approaches may be formulated to include little to no VOCs. Colorant compositions of the present disclosure have universal compatibility to tint both water-borne and solvent-based paints and stains. Compositions of the present disclosure preferably are low VOC, and have lower impact on the viscosity of a base paint or stain when used to tint (e.g., viscosity drop) compared to prior colorant compositions.

    Carrier

    [0053] Universal colorant compositions of the present disclosure are water-borne and include an aqueous vehicle or carrier. Water is a preferred vehicle or carrier, and may for example be tap water, deionized water, desalinated (e.g., via reverse-osmosis) water, or distilled water. Cosolvents may assist in dispersing the pigment into the colorant or into a base paint or stain; may speed up, retard or otherwise change the time or emissions associated with drying; may improve wet edge properties or overlap characteristics; may improve freeze-thaw protection, or may provide or improve other features, and generally will not be retained in a film of the dried, cured or otherwise hardened paint or stain. Cosolvents present in the vehicle preferably are selected so the universal colorant composition contains less than 50 g/L VOC, preferably less than 20 g/L VOC, preferably less than 10 g/L VOC, or even more preferably, less than 5 g/L VOC.

    [0054] A chosen cosolvent may be a hazardous air pollutant solvent (HAPS material) but preferably is a non-HAPS material or is substantially free of HAPS materials. Exemplary cosolvents typically have low molecular weights (e.g., up to about 700, up to about 600, up to about 500 or up to about 400 g/mol) and may for example include glycols (e.g., ethylene glycol, diethylene glycol, triethylene glycol, tetraethylene glycol and propylene glycol), glycol ethers (e.g., DOWANOL DPM and Butyl CELLOSOLVE from Dow Chemical Co.), alcohols (e.g., methanol, ethanol, n-propanol, isopropanol, n-butanol, isobutanol, 2-methyl butanol, isoamyl alcohol and other primary amyl alcohol isomers, n-pentanol, 2-ethylhexanol, 4-hydroxy-2,6,8-trimethylnonane and diisobutyl carbinol), esters and ester alcohols (e.g., isopropyl acetate; n-butyl acetate; isobutyl acetate; n-propyl acetate; primary amyl acetate mixed isomers, and UCAR Ester EEP from Dow Chemical Co.), ketones (e.g., diisobutyl ketone and ECOSOFT Solvent IK from Dow Chemical Co.), CARBOWAX 300 and CARBOWAX 600 polyethylene from Dow Chemical Co., mixtures thereof and the like. The colorants may for example contain at least about 8, at least about 10 or at least about 12 wt. % vehicles or carriers, and up to about 70, up to about 60 or up to about 50 wt. % vehicles or carriers.

    Pigments

    [0055] Universal colorant compositions of the present disclosure also include one or more pigments or dyes. A variety of pigments may be employed in the disclosed colorants (as well as in the base paints or stains), and will be familiar to persons having ordinary skill in the art. The pigments desirably form a stable dispersion that does not require agitation prior to use. In some instances a suitable pigment may also or instead be referred to commercially as a dye. Exemplary pigments include treated or untreated inorganic pigments and mixtures thereof, for example metallic oxides including titanium dioxide, iron oxides of various colors (including black) and zinc oxide; and metallic flakes such as aluminum flakes, pearlescent flakes, and the like. Exemplary pigments also or instead include treated or untreated organic pigments and mixtures thereof, for example carbon black, azo pigments, benzimidazolinones, carbazoles such as carbazole violet, diketopyrrolopyrroles, indanthrones, isoindolinones, isoindolons, perylenes, phthalocyanines, quinacridones and thioindigio reds. Suitable pigments are commercially available from a variety of commercial suppliers including BASF Colors & Effects GmbH, LANXESS, Cabot Corp, Ciba Specialty Chemicals, Clamant, Ferro Corporation, Shepherd Color Company, Sun Chemical and Tomatec America, Inc. Other exemplary pigments are described, for example, in U.S. Pat. No. 8,141,599 B2 (Korenkiewicz et al.), U.S. Pat. No. 8,746,291 B2 (Hertz et al.) and U.S. Pat. No. 8,748,550 B2 (Cavallin et al.). Colorants or colorant arrays containing entirely inorganic pigments or pigment mixtures may be preferred where custom-tinted paints or stains having maximum exterior durability are desired. In some embodiments, the colorant array includes non-infrared absorptive pigments for tinting dark exterior paints, and infrared-absorptive pigments for tinting dark interior paints, as described in U.S. Pat. No. 8,752,594 B2 (Gebhard et al.). The colorant compositions disclosed herein may for example contain at least about 2, at least about 3 or at least about 5 wt. % pigment and up to about 90, up to about 80 or up to about 70 wt. % pigment.

    Film-Forming Binder

    [0056] Colorant compositions of the present disclosure contain less than a film-forming amount of binder. That is, when applied to a surface, the colorant compositions do not form a continuous coating film upon drying unless it is first added to a base paint or stain that does contain a film--forming amount of binder. Consequently, if applied to a surface, dried and subsequently washed with water, the colorant composition (prior to addition to a base l-aint or stain) will wash away and not remain adhered to the surface.

    Modified Polyether Dispersent Having Pigment Affinic Groups

    [0057] To disperse, wet, and stabilize colorant composition pigments, universal colorant compositions of the present disclosure also include at least one modified polyether dispersant, the modification being the presence of one or more pigment affinic groups in the polyether dispersent. Universal colorant compositions of the present disclosure include at least 2 weight percent total of the modified polyether dispersants based on the wet weight of the colorant composition. In some approaches, the colorant compositions include at least 5 or at least 7 weight percent of modified polyether dispersants based on the wet weight of the colorant composition. Universal colorant compositions of the present disclosure include at most 20 weight percent of the modified polyether dispersants based on the wet weight of the colorant composition. In some approaches, universal colorant compositions of the present disclosure include at most about 15, or preferably at most about 12 weight percent total of the modified polyether dispersants based on wet weight of the colorant composition. While not wishing to be bound by theory, it is believed that the modified polyether dispersants in colorant compositions of the present disclosure wet, disperse, and stabilize pigments by adsorbing onto the particle and hindering agglomeration of particles by charge repulsion.

    [0058] The polyether dispersant includes structural units joined through one or more ether linkages (COC), which can provide the dispersant with hydrophobicity or hydrophilicity. The ether linkage may include may include one or more linear or branched polyoxyalkylene or polyacetal structural groups, such as an oxymethylene, oxyethylene, oxypropylene, or oxybutylene group. The oxypropylene may be a linear n-propylene oxide or a branched isopropylene oxide group. Similarly, the oxybutylene group may be an n-butylene oxide group or an isobutylene oxide group. If present, the polyoxyalkylenegroup has the following structure:


    (C.sub.mH.sub.2mO)).sub.n

    where m is the number of carbons in the polyoxyalkylene group and n is the number of repeated oxyalkylene groups. The polyether disperent may include one or more of the same or different polyoxyalkylene groups, in combination with other ether linkages disclosed herein.

    [0059] The ether linkage may also include one or more oxyphenylene or polyphenyelene oxide structural groups having the following structure:

    ##STR00001##

    where p is the number of phenyl groups in the oxyphenylene and q is the number of repeated oxyphenylene groups.

    [0060] The ether linkage may also include one or more polyetherketone structural groups having the following structure:

    ##STR00002##

    where r is the number of ketones in the etherketone group and q is the number of repeated etherketone groups.

    [0061] The ether linkage may also include one or more polyetheretherketone structural groups having the following structure:

    ##STR00003##

    where t is the number of ketone groups in the ether ether ketone group and u is the number of repeated ether ether ketone groups.

    [0062] The ether linkage may also include one or more cyclic ethers structural groups, such as oxirane or tetrahydrofuran moieties.

    [0063] The ether linkage may include one or more ether linkages, alone or in combination with other ether linkage groups.

    [0064] As a general matter, ether linkages that contain more short chain groups with a smaller number of carbon atoms (such as oxyethyl groups) provide more hydrophilicity, whereas linkages containing longer chains with more carbon atoms (e.g., oxypropyl, oxybutyl and longer chain) provide comparatively more hydrophilicity.

    [0065] The polyether dispersant is modified in that it includes one or more pigment affinic groups. Pigment affinic groups present in the modified polyether dispersant wet, stabilize, and disperse pigments in both the universal colorant composition and in a tinted base paint or stain after tinting. A pigment affinic group includes a hydrophobic aliphatic or aromatic structural unit, or combinations thereof, having at least 4 carbon atoms. The pigment affinic group may be saturated or partially unsaturated. In addition, pigment affinic groups may be adjacent to, connected to, or terminated by an ester group or carboxylic acid group. A pigment affinic group may be unsubstituted, or in some approaches may be substituted with one or more nitrogen, oxygen, or fluorine atoms replacing a hydrogen atom. In some approaches, one or more carbon atoms within the pigment affinic group may be substituted as a silicon, oxygen, or nitrogen atom. An aliphatic portion of a pigment affinic group may be a linear or branched aliphatic chain. Pigment affinic groups of the present disclosure contain at least 4 carbon atoms, or in other approaches, at least 8, at least 10, or at least 12 carbon atoms. A pigment affinic group may be terminated by a carboxylic acid group. A pigment affinic group may include saturated or unsaturated fatty ester groups, such caprylic acid, capric acid, lauric acid, mysteric acid, palmitic acid, stearic acid, arachidic acid, behenic acid, lignoceric acid, or cerotic acid, or may be an unsaturated fatty acid like myristoleic acid, palmitoleic acid, sapienic acid, oleic acid, elaidic acid, vaccenic acid, linoleic acid, linoelaidic acid, arachidonic acid, or other fatty acids. The fatty acid group may be saturated or unsaturated and may have at least 8 carbon atoms, at least 14 carbon atoms, at least 18 carbon atoms, or at least 20 carbon atoms.

    [0066] The modified polyether dispersant includes at least one pigment affinic group. If more than one pigment affinic group is present, the pigment affinic groups may be the same or different.

    [0067] Dispersants of the present disclosure may include a mole ratio of pigment affinic groups to ether linkage groups of at least 1:20, preferably at least 1:15, 1:5, or 1:4.

    [0068] Prior water-borne universal colorant compositions required inclusion of more than one surfactant to disperse the pigment and render the composition compatible with both solvent-borne and water-borne base paints and stains. Such surfactants comparably smaller molecules, having molecular weights of less than 1000 g/mol, usually less than 500 g/mol. The modified polyether dispersants of the present disclosure are relatively large compared to the multiple surfactant approach of prior approaches. In some approaches, the modified polyether dispersants of the present disclosure may have a single modal, bi-modal, or multi-modal molecular weight. The largest average molecular weight peak of the single or multiple modes has an average molecular weight of at least 1000 g/mol, or in other approaches, at least 1500 g/mol, or 2000 g/mol.

    [0069] Furthermore, prior universal colorant compositions required more than one surfactantat least one to provide compatibility with solvent-borne (e.g., alkyd-based) base paints or stains, and at least one to provide compatibility with water-borne (e.g, latex-based) base paints or stains. In contrast, compatibility of universal colorant compositions of the present disclosure is adduced by inclusion of pigment affinic groups present in a modified polyether dispersant. In some approaches, the universal colorant composition includes a single modified polyether dispersant, but in other approaches, the universal colorant composition includes more than one modified polyether dispersant, which may be the same or different dispersants, each with the same or different pigment affinic groups.

    [0070] Thus, in contrast to colorant compositions of the present disclosure, each of the multiple surfactants employed to make prior universal colorant compositions compatible with both water-borne and solvent-borne base paints and stains generally had an average molecular weight of less than 1000 g/mol, typically less than 500 g/mol.

    [0071] While not wishing to be bound by theory, it is believed that the relatively large molecular size of the modified polyether dispersant of the present disclosure sterically hinders movement of pigment particles in a universal colorant composition and in a tinted paint or stain. Consequently, inclusion of such a large molecule which groups that are affinic to pigment particles stabilizes pigment particles in the colorant composition and prevents settling. In addition, because the polyether dispersant is larger in molecular weight than previous surfactants, colorant compositions of the present disclosure have lower viscosity drop as compared to prior universal colorant compositions. In this way, inclusion of a modified polyether dispersant as in the universal colorant compositions of the present disclosure resists viscosity drop of the base paint or stain upon tinting.

    [0072] Suitable modified polyether dispersants include: DISPERBYK-182, DISPERBYK-184, DISPERBYK-191, DISPERBYK-193, DISPERBYK-2061, DISPERBYK-2062, DISPERBYK-2090, BYK-3560, BYK-3565 from BYK-Chemie GmbH. ADD-6212, ADD-6230, ADD-6231, from ADD Additives BV. Other suitable modified polyether dispersents include TEGO Dispers 650, TEGO Dispers 651, TEGO Dispers 653, TEGO Dispers 655, TEGO Dispers 656, from Evonik Operations GmbH. as well as Dispex Ultra FA 4480, EFKA 5220, EFKA 6230, EFKA 7500, from BASF SE, as well as Alkamuls PSML-20PC, from Solvay SA.

    [0073] In prior approaches, universal colorant compositions caused a disfavorable reduction in viscosity of a base paint or stain when the colorant is added to a base paint or stain. This reduction in viscosity affects the properties of the finished, tinted paint pr stain. For example, a paint or stain with low viscosity is difficult to apply, may not provide the necessary hide or coverage, and may not have the required block or tack resistance. Moreover, as base paints are made to have low or no VOC by using softer polymers or binder resins, and low or no VOC-containing colorants added to the base paint also have a high percentage of non-volatile soft components, it is difficult to form a hard film or coating that has good mechanical characteristics, i.e. block resistance, and tack resistance, for example.

    [0074] Surprisingly, universal colorant compositions of the present disclosure provide for acceptable viscosity drop without required presence of multiple surfactants. In some embodiments, universal colorant compositions of the present disclosure provide for lower viscosity drop when added to a base paint or stain compared to prior approaches. As such, the present disclosure resists viscosity drop more than prior approaches.

    [0075] Moreover, in some embodiments, universal colorant compositions of the present disclosure provide for a more uniform viscosity drop across colorant compositions. This is particularly desirable since more than one colorant composition (each with its own pigment and color) are used to tint a base paint or stain. Uniformity in the viscosity drop associated with all colorant compositions in an array of colorant compositions provides for more predictability in the viscosity drop expected when a base paint or stain is tinted.

    [0076] The ratio of pigment to modified polyether dispersant varies depending on the one or more pigments, the one or more dispersants, and other additives present in the colorant composition. In some approaches, the pigment-to-dispersant ratio is greater than about 1. In some approaches, the pigment-to-dispersant ratio is less than about 20, or in other approaches, less than about 15, less than bout 6, less than about 4, or less than 2.5

    Low VOC

    [0077] In some approaches, the vehicle, dispersants, and other components of the universal colorant composition are selected to be low in VOCs. Preferably, the universal colorant composition contains less than 50 g/L VOC, preferably less than 20 g/L VOC, preferably less than 10 g/L VOC, and even more preferably, less than 5 g/L VOC.

    Optional Surfactants

    [0078] Although universal colorant compositions of the present disclosure may include one or more surfactants, the compositions preferably are essentially free of alkyl phenol ethoxylate surfacants (APEOs). These surfactants are usually made from a branched chain nonylphenol or octylphenol, which is reacted with ethylene oxide. In some approaches, the composition is also free of a phosphate-ester surfactant, while in other approaches the composition is essentially free of a phosphorous-based surfactant that contains an ethoxylate group. Such phosphorous-based surfactants are disfavored because, although they provide solvent-based compatibility, they tend to increase viscosity drop.

    [0079] Preferably, the universal colorant composition is substantially free of surfactants having a molecular weight of less than 1000 g/mol, as inclusion of such surfactants may introduce viscosity drop that otherwise would be reduced compared to universal colorant compositions that do not include surfactants. Preferably, the universal colorant composition is completely free of surfactants having a molecular weight of less than 1000 g/mol.

    Phospho-Lipid

    [0080] In some approaches, the universal colorant composition includes a phospho-lipid to further stabilize the composition. In some approaches, the phospho-lipid is lechiten.

    Optional Additives

    [0081] Universal colorant compositions may, in some approaches, optionally include additional components or additives. In some approaches, the colorant compositions described herein include one or more preservatives, humectants, biocides, fillers, defoamers, pH control agents, thickeners, anti-settling agents, and mixtures or combinations thereof.

    [0082] Pigments of universal colorant compositions of the present disclosure may be supplemented with extenders, inert pigments or fillers such as talc, china clay, barytes, carbonates, silicates and mixtures thereof, for example magnesium silicates, calcium carbonate, aluminosilicates, silica and various clays; organic materials including plastic beads (e.g., polystyrene or polyvinyl chloride beads), microspherical materials containing one or more voids, and vesiculated polymer particles (e.g., those discussed in U.S. Pat. Nos. 4,427,835, 4,920,160, 4,594,363, 4,469,825, 4,468,498, 4,880,842, 4,985,064, 5,5157, 084, 5,041,464, 5,409,776, and 5,510,422). Other exemplary extenders, inert pigments or fillers include EXPANCEL 551DE20 acrylonitrile/vinyl chloride expanded particles (from Expancel Inc.), SIL-CEL 43 glass micro cellular fillers (from Silbrico Corporation), FILLITE 100 ceramic spherical particles (from Trelleborg Finite Inc.), SPHERICEL hollow glass spheres (from Potter Industries Inc.), 3M ceramic microspheres including grades G-200, G-400, G-600, G-800, W-210, W-410, and W-610 (from 3M), 3M hollow microspheres including 3M Performance Additives iM30K (also from 3M), INHANCE UH 1900 polyethylene particles (from Fluoro-Seal Inc.), and BIPHOR aluminum phosphate (from Bunge Fertilizantes S.A., Brazil). The colorants may for example contain at least about 0.5, at least about 1 or at least about 2 wt. % combined weight of pigment, extender, inert pigment and filler and up to about 80, up to about 70 or up to about 60 wt. % combined weight of pigment, extender, inert pigment and filler.

    [0083] In some approaches, colorant compositions of the present disclosure include a humectant. The humectant is selected from dihydric alcohol (e.g., ethylene glycol), polyhydric alcohol (e.g., propylene glycol), polyether, and the like. In a preferred aspect, the humectant is a polyether. Exemplary polyethers include, without limitation, polyalkyl glycols (e.g., low to moderate molecular weight polyethylene and polypropylene glycols), polyhydroxy ethers (e.g., those formed from epoxide polymerization), polysaccharide compounds (e.g., polysorbitan and polysorbital), polyalkylene oxides (e.g., polyethylene and polypropylene oxide), and mixtures and combinations thereof.

    [0084] In some approaches, the colorant compositions disclosed herein include about 1 wt % to wt % humectant, preferably about 2 wt % to 18 wt % humectant based on wet weight of the colorant composition. Polyethers suitable for the compositions and methods described herein include linear ethylene glycol polyethers of low molecular weight, e.g., having an average molecular weight of 190 to 210 g/mol and medium molecular weight polyethylene glycols, e.g., having an average molecular weight of from 285 to 315 g/mol, 385 to 415 g/mol, or 585 to 615 g/mol. Medium molecular weight polyethylene glycols are advantageous for use as vehicles because they are substantially free of ethylene glycols with 5 moles ethylene oxide or less.

    [0085] Preferably, suitable ethylene glycol polyethers have an average molecular weight of from about 190 to about 800, more preferably from about 375 to 425 or 575 to 625. Particularly useful commercial polyethylene glycols are PEG 300, PEG 400, and PEG 600.

    [0086] Another useful optional additive is a humectant such as, for example, the humectant GRB-2 from Zenica, which contains glycerin and a nonionic surfactant. Additional humectants which contains glycerin and a nonionic surfactant. Additional humectants useful in practicing the present disclosure include materials such as, for example, glycols such as ethylene glycol, propylene glycol, hexylene glycol, and the like; polyethylene glycols having molecular weights of about 300 g/mol, 400 g/mol, 500 g/mol, and the like; polypropylene glycols having molecular weights of about 300 g/mol, 400 g/mol, 500 g/mol, and the like; glycerin, sorbitol, sodium polyglutamate, modified urea compounds, polyethylene oxide and ethoxylated surfactants, and the like.

    [0087] A defoaming agent may be added for ease of manufacture. Suitable defoamers include materials such as, for example, mineral oil, silica oil such as Drew L-474 from Ashland Chemical, or an organically modified silicone oil like Drew L-405 from Ashland Chemical, and the like.

    [0088] A biocide may also be added to the colorant compositions of the present disclosure to eliminate or inhibit the growth of microorganisms. The biocide will generally account for between 0 and 1% by weight of the wet colorant composition. Biocidal chemicals include chlorinated hydrocarbons, organometallics, halogen-releasing compounds, metallic salts, organic sulfur compounds, quaternary ammonium compounds and phenolics. Useful commercial biocide examples are Troysan 192 from Arxada Corporation, Kathon LS from Lanxess Corporation, and the like.

    [0089] A fungicide may also be added to the colorant compositions of the present disclosure to eliminate or inhibit the growth of microorganisms. Non-limiting examples of fungicides include compounds such as, for example, 3-Iodo-2-propynyl butyl carbamate (IPBC), chlorothalonil, Zinc Pyrithione, 2-N-octyl-4-isothiazalin-3-one, and the like. A preferred fungicide is IPBC.

    Container for Distribution

    [0090] The universal colorant compositions disclosed herein are typically distributed in a container, which is inserted into a custom-tinting machine for tinting base paints or stains at a point-of-sale retail location. In some approaches, a universal colorant composition may be provided in an easy-to-use container such as a tube, a syringe, or a caulking-type cartridge. In other approaches, the universal colorant compositions may be provided in sealed pouches allowing for the composition to be dispensed in controlled amounts. Suitable containers for use in the present disclosure include metal and plastic tubes (e.g., toothpaste style tubes), sealed plastic bags or pouches and caulking-tube cartridges (e.g., cartridges with plungers such as are described, for example, in U.S. Pat. Nos. 5,622,288; 5,560,521; and 5,297,697, which are herein incorporated by reference).

    Colorant Composition Array

    [0091] In another aspect, disclosed is a point-of-sale system for making custom-tinted water-borne and solvent-borne architectural paints and stains using an array of liquid universal colorant compositions as disclosed herein. The array preferably includes at least white, red, blue, and yellow universal colorant compositions. The point-of-sale system may be automated or manual. For instance, a variety of automated paint colorant dispensers may be used in the disclosed system and method, including the ACCUTINTER 1500, 2000, 7000 and 8000 series machines with a 1/384 fluid ounce (0.077 cm.sup.3) minimum dispensing quantity from Fluid Management, Inc., and the Sample Dispensing System with a 1/1024 fluid ounce (0.029 cm.sup.3) minimum dispensing quantity from Fluid Management, Inc. Additional automated paint colorant dispensers include the COROB MODULA HFmachine with a 1/192 fluid ounce (0.153 cm.sup.3) minimum dispensing quantity from CPS Color Equipment, Inc., and the TATOCOLOR machine with a 1/384 fluid ounce (0.077 cm.sup.3) minimum dispensing quantity from CPS Color Equipment, Inc. The chosen dispenser may for example have a minimum fluid dispensing quantity less than 0.01 fluid ounce (<0.3 cm.sup.3), preferably less than 0.007 fluid ounce (<0.2 cm.sup.3) and more preferably less than 0.005 fluid ounce (<0.15 cm.sup.3). Dispensers with even smaller minimum dispensing quantities may be employed, e.g. less than 0.001 fluid ounce (<0.03 cm.sup.3) or less than 0.0002 (<0.014 cm.sup.3) minimum dispensing quantities, but such dispensers may also require longer amounts of time to prepare strong colors in large containers. To overcome this, the dispenser may be modified to provide multiple dispensing circuits for one or more colorants, e.g., a lower flow rate, lower minimum dispensing quantity circuit and a higher flow rate, higher minimum dispensing quantity circuit for at least some (e.g., the green, blue, red and magenta if used) colorants in the dispenser. These circuits may share some common components (e.g., the withdrawal line from a colorant canister, the colorant dispensing nozzle or nozzles, or nozzle cleaning devices) and may employ some unshared components (e.g., gear pumps). The somewhat increased equipment cost necessitated by such an approach will be offset by an increased fill rate when making strong colors in large containers and by a reduced or eliminated need to use separate dispensers to handle larger or smaller colorant volumes.

    [0092] Universal colorant compositions each having a different color or pigment may be employed in the methods disclosed herein. The compositions and methods described herein preferably employ an array of 8, 9, 10, 11 or 12 colorants, but may employ fewer colorants where a limited color space is acceptable, or more colorants if additional dispenser slots are available, and an expanded color space is required and/or acceptable. To tint a base paint or stain, one or more colors of the universal colorant composition are added to a base paint or stain, in some approaches using point-of-sale tinting equipment, and the base paint or stain is mixed until uniform.

    [0093] Preferably, the array of colorant compositions of the present disclosure includes less than 14 distinct colorant compositions, each having a different color. It has surprisingly been discovered that a 12-colorant composition array composed of colorants of the universal colorant compositions of the present disclosure can accurately custom-tint paint with the same breadth and specificity of tinted paint colors as those which required 14 of prior, commercially available colorant compositions.

    Tinting Base Paint or Stain

    [0094] In some approaches, universal colorant compositions of the present disclosure are gravimetrically added to a tintable base paint or stain such that the tinted paint or stain includes about 0.05 to 15 weight percent of one or more universal colorant compositions based on the wet weight of the colorant composition and the wet weight of the base paint or stain. In other approaches, universal colorant compositions are volumetrically added to a tintable base paint or stain such that the tinted paint or stain includes about 0.05 to 15 weight percent of one or more universal colorant compositions based on the wet weight of the colorant composition and the wet weight of the base paint or stain.

    [0095] When added to a water-borne base paint or stain, universal colorant compositions of the present disclosure decrease the viscosity of the water-borne base paint or stain less than 20 Krebs Units, preferably less than 10 Krebs Units.

    [0096] In some approaches, the universal colorant compositions described herein are substantially uniform and require little mixing prior to use. In an aspect, the colorant compositions described herein require up to about 3 minutes of mechanical shaking prior to use, but preferably no shaking is required at all, even after extended shelf life.

    LIST OF EXEMPLARY EMBODIMENTS

    [0097] The following is a non-exhaustive list of exemplary embodiments of the present disclosure. Other embodiments described in the present disclosure but not included in the list of exemplary embodiments are nonetheless embodiments of the present disclosure.

    [0098] Embodiment 1: A universal colorant composition comprising: [0099] an aqueous vehicle, [0100] one or more pigments or dyes, [0101] and a modified polyether dispersant containing one or more pigment affinic groups; [0102] wherein the polyether dispersant includes one or more polyoxyalkyl, substituted or unsubstituted polyoxyphenyl, polyetherketone, polyetheretherketone, cyclic ether, or combinations thereof, and [0103] wherein the pigment affinic groups are each a saturated or unsaturated aliphatic or aromatic structural unit containing a plurality of carbon atoms; [0104] wherein the modified polyether dispersant has a peak weight average molecular weight of at least 1000 g/mol; [0105] wherein the universal colorant composition is substantially free of low molecular weight surfactants; [0106] wherein the universal colorant composition is compatible with water-borne and solvent-borne [0107] base paints and stains and is suitable for use in a point-of-sale tinting machine; and [0108] wherein the colorant composition contains less than a film-forming amount of binder.

    [0109] Embodiment 2: The universal colorant composition of any preceding embodiment, [0110] wherein the colorant composition is substantially free of surfactants.

    [0111] Embodiment 3: The universal colorant composition of any preceding embodiment, [0112] wherein the colorant composition comprises a first modified polyether dispersant including one or more pigment affinic groups; and [0113] a second modified polyether dispersant including one or more pigment affinic groups; [0114] wherein the one or more pigment affinic groups of the first modified polyether dispersant are the same or different from the one of more pigment affinic groups of the second modified polyether dispersant.

    [0115] Embodiment 4: The universal colorant composition of any preceding embodiment, wherein the polyoxyalkyl structural units include oxymethyl, oxyethyl, oxypropyl, or oxybutyl groups.

    [0116] Embodiment 5: The universal colorant composition of any preceding embodiment, wherein the polyoxyalkyl structural units are oxyethyl groups.

    [0117] Embodiment 6: The universal colorant composition of any preceding embodiment, wherein the cyclic ether groups are tetrahydrofuran or oxirane groups.

    [0118] Embodiment 7: The universal colorant composition of any preceding embodiment, wherein the one or more modified polyether dispersants are present in a total amount of at least 2, at least 5, or at least 7 weight percent based on the wet weight of the colorant composition.

    [0119] Embodiment 8: The universal colorant composition of any preceding embodiment, wherein the one or more modified polyether dispersants are present in a total amount of at most 20, at most 15, or at most 12 weight percent based on the wet weight of the colorant composition.

    [0120] Embodiment 9: The universal colorant composition of any preceding embodiment, wherein at least one pigment affinic group is a linear or branched aliphatic chain having at least 4, at least 8, at least 10, or at least 12 carbons.

    [0121] Embodiment 10: The universal colorant composition of any preceding embodiment, wherein the pigment affinic groups include an aromatic group.

    [0122] Embodiment 11: The universal colorant composition of any preceding embodiment, wherein the pigment affinic group includes a branched or unbranched C10 alkyl chain.

    [0123] Embodiment 12: The universal colorant composition of any preceding embodiment, wherein the pigment affinic groups include a saturated or unsaturated fatty acid having at least 14 carbon atoms.

    [0124] Embodiment 13: The universal colorant composition of any preceding embodiment, wherein the pigment affinic groups include a saturated or unsaturated fatty acid having at least 18 carbon atoms.

    [0125] Embodiment 14: The universal colorant composition of any preceding embodiment, wherein the pigment affinic groups include an unsaturated oleic or linoleic fatty acid.

    [0126] Embodiment 15: The universal colorant composition of any preceding embodiment, wherein the dispersant has a mole ratio of pigment affinic groups to polyoxylalkyl groups of at least 1:20, preferably at least 1:15, 1:5, or 1:4.

    [0127] Embodiment 16: The universal colorant composition of any preceding embodiment, wherein the one or more pigments or dyes are present in an amount of at least 2, or at least about 5 weight percent based on the wet weight of the colorant composition.

    [0128] Embodiment 17: The universal colorant composition of any preceding embodiment, wherein the one or more pigments or dyes are present in an amount of at most about 90, or at most about 80, or at most about 70 weight percent based on the wet weight of the colorant composition.

    [0129] Embodiment 18: The universal colorant composition of any preceding embodiment, wherein the composition contains less than 50 g/L VOC, preferably less than 20 g/L VOC, preferably less than 10 g/L VOC, or even more preferably, less than 5 g/L VOC.

    [0130] Embodiment 19: The universal colorant composition of any preceding embodiment, wherein the modified polyether dispersant has a peak weight average molecular weight of at least 1500 g/mol, or at least 2000 g/mol.

    [0131] Embodiment 20: The universal colorant composition of any preceding embodiment, wherein the colorant composition is essentially free of an alkyl phenol ethoxylate surfactant.

    [0132] Embodiment 21: The universal colorant composition of any preceding embodiment, wherein the colorant composition is essentially free of a phosphate-ester surfactant.

    [0133] Embodiment 22: The universal colorant composition of any preceding embodiment, wherein the colorant composition is essentially free of a phosphorous-based surfactant having an ethoxylate group.

    [0134] Embodiment 23: The universal colorant of any preceding embodiment, wherein the universal colorant further comprises a phospho-lipid.

    [0135] Embodiment 24: The universal colorant composition of embodiment 23, wherein the phospho-lipid is a lechitin.

    [0136] Embodiment 25: The universal colorant composition of any preceding embodiment, wherein the colorant composition is essentially free of surfactants having an average molecular weight of less than 500 g/mol, preferably less than 1000 g/mol.

    [0137] Embodiment 26: The universal colorant composition of any preceding embodiment, wherein when added to a base paint or stain, the viscosity of the base paint or stain decreases less than 20 Krebs Units, preferably less than 10 Krebs Units when measured according to the Viscosity Drop Test.

    [0138] Embodiment 27: The universal colorant composition of any preceding embodiment, wherein the pigment-to-dispersant ratio is at least 1.

    [0139] Embodiment 28: The universal colorant composition of any preceding embodiment, wherein the pigment-to-dispersant weight ratio is at most 20, at most 15, at most 6, at most 4, or at most 2.5.

    [0140] Embodiment 29: A point-of-sale system for making custom-tinted water-borne and solvent-borne architectural paints and stains, the system comprising: [0141] an array of universal colorant compositions of any preceding embodiment; the array including at least white, red, blue, and yellow colorant compositions, [0142] wherein when added to a base paint or stain, the universal colorant compositions resist negatively impacting the viscosity of tinted latex paints.

    [0143] Embodiment 30: A method of making a tinted paint or stain comprising adding one or more universal colorant compositions of any preceding embodiment to a base paint or stain and mixing the tinted base paint or stain until uniform.

    [0144] Embodiment 31: The method of embodiment 30, wherein the one or more universal colorant compositions are gravimetrically added to the base paint or stain.

    [0145] Embodiment 32: The method of embodiment 30, wherein the one or more universal colorant compositions are volumetrically added to the base paint or stain.

    [0146] Embodiment 33: A tinted paint or stain comprising: [0147] a tintable base paint or stain; and [0148] about 0.05 to 15 weight percent of one or more universal colorant compositions of any preceding embodiment.

    [0149] Embodiment 34: A system for tinting a base paint or stain comprising: [0150] an array of universal colorant compositions of any of embodiments 1 to 28, wherein the array includes at least twelve colorant compositions including at least white, red, blue, and yellow colors, and [0151] a base paint or stain.

    [0152] Embodiment 35: The system of embodiment 34, wherein when each of the universal colorant compositions are added to the base paint or stain, no more than 3, and preferably no more than 5, of the twelve colorant compositions, has more than a 10 KU viscosity drop.

    EXAMPLES

    [0153] The disclosure is illustrated by the following examples, which are not intended to be limiting on the disclosure. The particular examples, materials, amounts, and procedures are to be interpreted broadly in accordance with the scope and spirit of the disclosures as set forth herein. Unless otherwise indicated, all parts and percentages are by weight and all molecular weights are weight average molecular weight. Unless otherwise specified, all chemicals used are commercially available.

    Example 1: Preparation Of Inventive Colorant Compositions

    [0154] Colorant compositions were made by mixing water, pigment, and TEGO Dispers 651, a modified polyether dispersant having approximately 14 moles polyoxyethylene structural units per equivalent, 1 mole C10 linear aliphatic structural units per equivalent, and 3 moles aromatic structural units per equvialent (peak Mw approx. 1500 g/mol), with conventional humectants, defoamers, preservatives, and thickeners. The colorants were ground using zirconium milling beads to a 7 Hegman fineness of grind value. Table 1 shows the amounts by weight percent included in each universal colorant composition.

    TABLE-US-00001 TABLE 1 Components of Inventive Colorant Compositions (wt. %) Durable Durable Yellow Yellow Black Umber White Red Colorant Colorant Colorant Colorant Colorant Colorant TEGO Dispers 651 9.11 10.73 9.44 11.01 6.26 12.98 Water 15.38 23.45 41.44 33.36 8.58 20.40 Humectant 14.86 6.41 8.60 9.91 6.15 7.70 Defoamer 0.65 0.36 0.39 0.55 0.16 0.54 Preservative 0.26 0.36 0.26 1.68 1.52 1.33 Thickener 0.13 1.29 0.33 0.25 Inert Pigment 11.52 12.22 30.00 6.80 4.99 Pigment PY 74 14.76 8.41 PY 83 0.80 PY 184 30.31 PBk 7 9.87 0.14 PBr 7 19.38 PW 6 56.85 PR 254 17.86 Extender Paste 33.33 5.66 16.84 20.23 33.95

    Example 2: Comparison of Tinting of Base Paint Using Inventive and Existing Universal Colorant Compositions

    [0155] Colorant compositions of the present disclosure were prepared and compared to colorant compositions of the commercially available low VOC universal colorant system NovoColor II..sup.1 Colorant compositions of the NovoColor II colorant system were selected for comparison because they rely on a combination of a low molecular weight water-compatible surfactant and a low molecular weight solvent-compatible surfactant. The colorants were used to tint samples of a water-based acrylic latex paint, specifically Duration Interior Acrylic Tint (formula A96W1251); and SWP Exterior Gloss Tint (formula A2W528) solvent-borne paint, both available from The Sherwin-Williams Company, Cleveland, Ohio. The water-borne base paints were tinted at 5 ounces colorant per gallon base paint. The solvent-borne base paints were tinted at 4 ounces colorant per gallon base paint. The tinted paints were then tested according to the Rub-up Test, and Colorimeter Test, and were assessed for tint strength.

    TABLE-US-00002 TABLE 2 Tint Strength, E, Rub-Up 1 vs 15 min Red Devil shake Colorant Base Paint Paint Type Tint Strength CIE E Rub-up Black NovoColor II SW Duration Int Acrylic Water-borne 101.10% 0.14 None Colorant 8891 Latex A96W1251 SWP Exterior Gloss Oil Solvent-borne 98.86% 0.14 None Based A2W528 Black SW Duration Int Acrylic Water-borne 101.68% 0.19 None Colorant of Latex A96W1251 Example 1 SWP Exterior Gloss Oil Solvent-borne 101.19% 0.13 None Based A2W528 Umber NovoColor II SW Duration Int Acrylic Water-borne 100.55% 0.25 None Colorant 8888 Latex A96W1251 SWP Exterior Gloss Oil Solvent-borne 102.80% 0.23 None Based A2W528 Umber SW Duration Int Acrylic Water-borne 102.50% 0.26 None Colorant of Latex A96W1251 Example 1 SWP Exterior Gloss Oil Solvent-borne 102.03% 0.17 None Based A2W528 Durable NovoColor II SW Duration Int Acrylic Water-borne 99.22% 0.30 Slight Dark Red 8851 Latex A96W1251 Colorant SWP Exterior Gloss Oil Solvent-borne 96.73% 0.71 None Based A2W528 Durable Red SW Duration Int Acrylic Water-borne 100.08% 0.16 Trace Dark Colorant of Latex A96W1251 Example 1 SWP Exterior Gloss Oil Solvent-borne 100.41% 0.04 None Based A2W528 .sup.1 Available from Color Corporation of America, Marengo, Illinois.

    [0156] The data shows that the universal colorant compositions of the present disclosure have excellent compatibility with both water-borne and solvent-borne base paints

    Example 3: Comparison of Inventive and Commercially Available Colorant Compositions Viscosity Drop When Tinting Water-Borne Base Paint

    [0157] Colorant compositions of the present disclosure were compared to colorant compositions of the commercially available low VOC universal colorant system NovoColor II. Samples of Duration Interior Matte Ultradeep (formula A96T1254) water-borne latex paint 2 were tinted at 10 ounce per gallon colorant and shaken on a cradle type machine shaker for 1 minute then viscosities measured. It can be appreciated that colorants of the present show less impact on the viscosity of the tinted paint compared to the commercially available NovoColor II colorants. Data is shown in Table 3.

    TABLE-US-00003 TABLE 3 Viscosity Drop Measurements Percent Reduced Viscosity Viscosity Viscosity Sample (KU) Drop (KU) Drop Untinted Base Paint 118 Yellow NovoColor II 8813 99 19 Colorant Yellow Colorant of 105 13 31.6% Example 1 Durable NovoColor II 8818 97 21 Yellow Durable Yellow 102 16 23.8% Colorant Colorant or Example 1 Black NovoColor II 8891 84 34 Colorant Black Colorant of 109 9 73.5% Example 1 Umber NovoColor II 8888 102 16 Colorant Umber Colorant of 108 10 37.5% Example 1 White NovoColor II 8800 104 14 Colorant White Colorant of 114 4 71.4% Example 1 Durable NovoColor II 8851 99 19 Red Durable Red Colorant 106 12 36.8% Colorant of Example 1

    [0158] The data shows that the inventive universal colorant compositions have lower viscosity drop than existing universal colorant compositions such as colorants of the Novocolor II universal colorant system. For some colors, the viscosity drop was decreased by more than 50% compared to existing solutions. .sup.2 Available from The Sherwin-Williams Company, Cleveland, Ohio

    Example 4: Preparation of Inventive Colorant Compositions

    [0159] Colorant compositions were made by mixing water, pigment, and TEGO Dispers 653, a modified polyether dispersant, with conventional humectants, defoamers, preservatives, and thickeners. The colorants were ground using zirconium milling beads to a 7 Hegman fineness of grind value. Table 4 shows the amounts by weight percent of each universal colorant composition component based on the total weight of the colorant composition.

    TABLE-US-00004 TABLE 4 Components of Inventive Colorant Compositions Durable Durable Yellow Yellow Black Umber Red Component Colorant Colorant Colorant Colorant Colorant TEGO Dispers 653 9.11 10.73 9.44 11.01 12.98 Water 15.38 23.45 41.44 33.36 20.40 Humectant 14.86 6.41 8.60 9.91 7.70 Defoamer 0.65 0.36 0.39 0.55 0.54 Preservative 0.26 0.36 0.26 1.68 1.33 Thickener 0.13 1.29 0.33 0.25 Inert Pigment 11.52 12.22 30.00 6.80 4.99 Pigment PY74 14.76 8.41 PY83 0.80 PY184 30.31 PBk7 9.87 0.14 PBr7 19.38 PR254 17.86 Extender Paste 33.33 5.66 16.84 33.95

    Example 5: Comparison of Tinting of Inventive And Existing Colorant Compositions to Tint Water-Borne and Solvent-Borne Base Paints

    [0160] Colorant compositions of the present disclosure were prepared and compared to colorant compositions of the commercially available low VOC universal colorant system NovoColor II. Colorant compositions of the NovoColor II colorant system were selected for comparison because for compatibility, they rely on a combination of a low molecular weight water-compatible surfactant and a low molecular weight solvent-compatible surfactant. The colorants were used to tint samples of a water-borne acrylic latex paint, specifically Sherwin-Williams Duration Interior Acrylic Latex (formula A96W1251, identified by formula number in the Base Paint column of Table 5 below; and a solvent-borne paint, SWP Exterior Gloss Oil-based (formula A2W528, identified as solvent-based in the Base Paint column of Table 5 below), both available from The Sherwin-Williams Company, Cleveland, Ohio. The water-borne base paints were tinted at 5 ounces colorant per gallon base paint. The solvent-borne base paints were tinted at 4 ounces colorant per gallon base paint. The tinted paints were then tested according to the Rub-up Test, and Colorimeter Test, and were assessed for tint strength.

    TABLE-US-00005 TABLE 5 Tint Strength, E, Rub-Up 1 v 15 min Red Devil Shake Colorant Base Paint Paint Type Tint Strength E Rub-up Yellow NovoColor II SW Duration Int Water- 100.87% 0.11 None Colorant 8813 Acrylic Latex borne A96W1251 SWP Exterior Solvent- 112.75% 2.16 None Gloss Oil Based borne A2W528 Yellow SW Duration Int Water- 100.63% 0.20 None Colorant of Acrylic Latex borne Example 4 A96W1251 SWP Exterior Solvent- 104.14% 0.68 None Gloss Oil Based borne A2W528 Durable NovoColor II SW Duration Int Water- 100.43% 0.19 None Yellow 8818 Acrylic Latex borne Colorant A96W1251 SWP Exterior Solvent- 107.67% 1.25 None Gloss Oil Based borne A2W528 Durable Yellow SW Duration Int Water- 100.18% 0.14 None Colorant of Acrylic Latex borne Example 4 A96W1251 SWP Exterior Solvent- 101.64% 0.35 None Gloss Oil Based borne A2W528 Black NovoColor II SW Duration Int Water- 101.14% 0.13 None Colorant 8891 Acrylic Latex borne A96W1251 SWP Exterior Solvent- 99.64% 0.07 None Gloss Oil Based borne A2W528 Black Colorant SW Duration Int Water- 101.15% 0.13 None of Example 4 Acrylic Latex borne A96W1251 SWP Exterior Solvent- 100.37% 0.05 None Gloss Oil Based borne A2W528 Umber NovoColor II SW Duration Int Water- 100.83% 0.14 None Colorant 8888 Acrylic Latex borne A96W1251 SWP Exterior Solvent- 104.65% 0.39 None Gloss Oil Based borne A2W528 Umber Colorant SW Duration Int Water- 100.49% 0.06 None of Example 4 Acrylic Latex borne A96W1251 SWP Exterior Solvent- 100.52% 0.06 None Gloss Oil Based borne A2W528 Durable Red NovoColor II SW Duration Int Water- 100.19% 0.07 None Colorant 8851 Acrylic Latex borne A96W1251 SWP Exterior Solvent- 96.71% 0.70 None Gloss Oil Based borne A2W528 Durable Red SW Duration Int Water- 99.59% 0.16 None Colorant of Acrylic Latex borne Example 4 A96W1251 SWP Exterior Solvent- 97.11% 0.62 None Gloss Oil Based borne A2W528

    [0161] The data shows that the universal colorant compositions of the present disclosure have excellent compatibility with both water-borne and solvent-borne base paints.

    Example 6: Comparison Of Viscosity Drop Of Inventive And Existing Colorant Compositions

    [0162] Colorant compositions of the present disclosure were compared to colorant compositions of the commercially available low VOC universal colorant system NovoColor II. Samples of Duration Interior Matte Ultradeep (formula A96T1254) water-borne latex paint 2 were tinted at 10 ounce per gallon colorant and shaken on a cradle type machine shaker for 1 minute then viscosities measured. It can be appreciated that colorants of the present show less impact on the viscosity of the tinted paint compared to the commercially available NovoColor II colorants. Data is shown in Table 6.

    TABLE-US-00006 TABLE 6 Viscosity Drop Measurements Percent Reduced Viscosity Viscosity Viscosity Sample (KU) Drop (KU) Drop Untinted Base Paint 122 Yellow NovoColor II 8813 106 16 Colorant Yellow Colorant of 102 20 25.0% Example 4 Durable NovoColor II 8818 101 21 Yellow Durable Yellow 104 18 14.3% Colorant Colorant of Example 4 Black NovoColor II 8891 83 39 Colorant Black Colorant of 105 17 56.4% Example 4 Umber NovoColor II 8888 96 26 Colorant Umber Colorant of 103 19 26.9% Example 4 Durable NovoColor II 8851 83 39 Red Durable Red Colorant 99 23 41.0% Colorant of Example 4

    [0163] The data shows that the inventive universal colorant compositions have lower viscosity drop than existing universal colorant compositions such as colorants of the NovoColor II universal colorant system. For some colors, the viscosity drop was decreased by more than 50% compared to existing solutions.

    Example 7: Preparation of Inventive Colorant Compositions

    [0164] Colorant compositions were made by mixing water, pigment, and DISPERBYK-2061, a modified polyether dispersant, with conventional humectants, defoamers, preservatives, and thickeners. The colorants were ground using zirconium milling beads to a 7 Hegman fineness of grind value. Table 7 shows the amounts of each component included in each universal colorant composition by weight percent based on the total weight of the colorant composition.

    TABLE-US-00007 TABLE 7 Components of Inventive Colorant Compositions (wt. %) Durable Durable Yellow Yellow Black Umber Red Component Colorant Colorant Colorant Colorant Colorant DISPERBYK-2061 9.11 10.73 9.44 11.01 12.98 Water 15.38 23.45 41.44 33.36 20.40 Humectant 14.86 6.41 8.60 9.91 7.70 Defoamer 0.65 0.36 0.39 0.55 0.54 Preservative 0.26 0.36 0.26 1.68 1.33 Thickener 0.13 1.29 0.33 0.25 Inert Pigment 11.52 12.22 30.00 6.80 4.99 Pigment PY74 14.76 8.41 PY83 0.80 PY184 30.31 PBk7 9.87 0.14 PBr7 19.38 PR254 17.86 Extender Paste 33.33 5.66 16.84 33.95

    Example 8: Comparison To Commercially Available Universal Colorant Compositions

    [0165] Colorant compositions of the present disclosure were prepared and compared to colorant compositions of the commercially available low VOC universal colorant system NovoColor II. .sup.1 Colorant compositions of the NovoColor II colorant system were selected for comparison because they rely on a combination of a low molecular weight water-compatible surfactant and a low molecular weight solvent-compatible surfactant. The colorants were used to tint samples of a water-borne acrylic latex paint, specifically Duration Interior Acrylic Tint (formula A96W1251); and SWP Exterior Gloss Tint (formula A2W528) solvent-borne paint, both available from The Sherwin-Williams Company, Cleveland, Ohio. The water-borne base paints were tinted at 5 ounces colorant per gallon base paint. The solvent-borne base paints were tinted at 4 ounces colorant per gallon base paint. The tinted paints were then tested according to the Rub-up Test, and Colorimeter Test, and were assessed for tint strength.

    TABLE-US-00008 TABLE 8 Tint Strength, E, Rub-Up 1 v 15 min Red Devil Shake Colorant Base Paint Paint Type Tint Str E Rub-up Yellow NovoColor II SW Duration Int Water-borne 100.87% 0.11 None Colorant 8813 Acrylic Latex A96W1251 SWP Exterior Gloss Solvent- 112.75% 2.16 None Oil Based A2W528 borne Yellow Colorant SW Duration Int Water-borne 100.67% 0.13 None of Example 7 Acrylic Latex A96W1251 SWP Exterior Gloss Solvent- 104.02% 0.64 None Oil Based A2W528 borne Durable NovoColor II SW Duration Int Water-borne 100.43% 0.19 None Yellow 8818 Acrylic Latex Colorant A96W1251 SWP Exterior Gloss Solvent- 107.67% 1.25 None Oil Based A2W528 borne Durable Yellow SW Duration Int Water-borne 101.43% 0.20 None Colorant of Acrylic Latex Example 7 A96W1251 SWP Exterior Gloss Solvent- 119.99% 3.36 Trace Oil Based A2W528 borne Dark Black NovoColor II SW Duration Int Water-borne 101.14% 0.13 None Colorant 8891 Acrylic Latex A96W1251 SWP Exterior Gloss Solvent- 99.64% 0.07 None Oil Based A2W528 borne Black Colorant SW Duration Int Water-borne 101.01% 0.12 None of Example 7 Acrylic Latex A96W1251 SWP Exterior Gloss Solvent- 101.67% 0.19 None Oil Based A2W528 borne Umber NovoColor II SW Duration Int Water-borne 100.83% 0.14 None Colorant 8888 Acrylic Latex A96W1251 SWP Exterior Gloss Solvent- 104.65% 0.39 None Oil Based A2W528 borne Umber Colorant SW Duration Int Water-borne 101.00% 0.17 None of Example 7 Acrylic Latex A96W1251 SWP Exterior Gloss Solvent- 110.15% 1.14 Moderate Oil Based A2W528 borne Dark Durable Red NovoColor II SW Duration Int Water-borne 100.19% 0.07 None Colorant 8851 Acrylic Latex A96W1251 SWP Exterior Gloss Solvent- 96.71% 0.70 None Oil Based A2W528 borne Durable Red SW Duration Int Water-borne 99.60% 0.15 None Colorant of Acrylic Latex Example 7 A96W1251 SWP Exterior Gloss Solvent- 97.66% 0.64 Trace Oil Based A2W528 borne Dark

    [0166] The data shows that the universal colorant compositions of the present disclosure have excellent compatibility with water-borne base paints. Some colors also have excellent compatibility with solvent-borne base paints. Other colors need further optimization to improve solvent-borne compatibility.

    Example 9: Viscosity Drop Comparison to Existing Colorant Compositions

    [0167] Colorant compositions of the present disclosure were compared to colorant compositions of the commercially available low VOC universal colorant system NovoColor II. Samples of Duration Interior Matte Ultradeep (formula A96T1254) water-borne latex paint 2 were tinted at 10 ounce per gallon colorant and shaken on a cradle type machine shaker for 1 minute then viscosities measured. It can be appreciated that colorants of the present show less impact on the viscosity of the tinted paint compared to the commercially available NovoColor II colorants. Data is shown in Table 9.

    TABLE-US-00009 TABLE 9 Viscosity Drop Measurements Percent Reduced Viscosity Viscosity Viscosity Sample (KU) Drop (KU) Drop Untinted Base Paint 122 Yellow NovoColor II 8813 106 16 Colorant Yellow Colorant of 92 30 87.5% Example 7 Durable NovoColor II 8818 101 21 Yellow Durable Yellow 90 32 52.4% Colorant Colorant of Example 7 Black NovoColor II 8891 83 39 Colorant Black Colorant of 93 29 25.6% Example 7 Umber NovoColor II 8888 96 26 Colorant Umber Colorant of 90 32 23.1% Example 7 Durable NovoColor II 8851 83 39 Red Durable Red Colorant 88 34 12.8% Colorant of Example 7

    [0168] The data shows that some of the inventive universal colorant compositions have lower viscosity drop than existing universal colorant compositions such as colorants of the NovoColor II universal colorant system.

    Example 10: Assessment of Uniformity of Viscosity Drop Across Base Paints and Stains

    [0169] Colorant compositions as in Table 10 were produced by mixing one or more modified polyether dispersents having pigment affinic groups with conventional humectants, defoamers, preservatives, and thickeners. The colorants were ground using zirconium milling beads to a 7 Hegman fineness of grind value. Table 7 shows the amounts of each component included in each universal colorant composition by weight percent based on the total weight of the colorant composition.

    TABLE-US-00010 TABLE 10 Components of Inventive Colorant Compositions (wt. %) Medium Raw Durable Organic Durable Component Yellow White Magenta Umber Red Red Yellow Yellow TEGO 7.76 1.41 7.72 2.44 5.32 5.90 6.79 7.63 DISPERS 651 HYDROPALAT 1.81 9.28 5.67 4.84 1.95 2.24 WE 3317 DISPERBYK 2.04 2.75 191 Water 42.61 26.43 37.67 40.47 42.11 38.98 44.70 28.85 Humectant 7.80 5.96 10.73 8.61 9.20 9.45 9.74 5.73 Defoamer 1.01 0.16 0.83 0.57 0.58 0.63 0.83 0.39 Preservative 1.85 0.73 0.77 0.72 1.76 1.71 1.73 0.76 Thickener 0.89 0.80 0.08 0.68 0.31 0.33 0.44 1.58 Lecithin 3.08 6.08 6.23 6.84 5.92 2.06 2.52 Inert Pigment 29.06 7.21 19.85 14.20 16.89 14.49 Pigment PY 65 23.02 0.23 Pigment PY 74 13.25 0.13 14.87 7.74 Pigment PW 6 59.39 1.14 Pigment PR 122 7.06 Pigment PBk 7 0.25 Pigment PBr 7 19.65 Pigment PR 112 4.11 Pigment PR 209 3.89 Pigment PR 254 18.04 Pigment PY 184 26.51 Pigment PY 83 1.56

    [0170] To assess the viscosity drop compared to existing colorant compositions, each colorant composition was added volumetrically in the maximum volume of colorant permitted on the base paint or stain label to a one gallon container of the base paint or stain. As a control, the same test was performed using the same colors of the Novocolor II colorant composition array from the Sherwin-Williams Company, which includes a combination of a hydrophilic surfactant and a hydrophobic surfactant to make the colorant composition universal. KU (Stormer) viscosity of the base paint or stain was measured before and after addition of the colorant composition to assess the viscosity drop associated with each combination of colorant and base paint or stain. Viscosity drops between 5 KU and 10 KU are identified in underline and viscosity drops of more than 10 KU are identified in italics. Bracketed information indicates: [count of viscosity drops between 5 KU and 10 KU, count of viscosity drops above 10 KU].

    TABLE-US-00011 Viscosity Drop (KU).sup.3 Colorant Inventive Novocolor II Fill (fl Colorant Colorant Base Paint or Stain.sup.4 oz/gal) Composition Compositions Pratt & Lambert Accolade 18 1, 8, 4.7, 14.8, 2, 17.6, 13.7, Interior Premium Paint & 13.1, 14.1, 10.3, 16.2, 19.5, 39.8, Primer, Semi-gloss, Neutral 10.1 [1, 6] 17.6, 20.6 [0, 7] Base Dutch Boy Forever Interior 18 14, 5, 3.1, 7.5, 3, 9.4, 8.7, 8.3, 100% Acrylic Paint + Primer, 6.6, 8, 5.7, 7, 18.6, 11.7, Flat, Base D 5.2 [5, 1] 10.1 [4, 3] Dutch Boy Platinum Plus 28 1, 3.9, 7.8, 17, 17, 25.4, 27.7, Interior 100% Acrylic Enamel 17.7, 17.2, 8.6, 20.3, 20.8 27.7, Paint + Primer, Satin, Base B 9 [4, 3] 20.4, 19.5 [0, 8] Dutch Boy Platinum Plus 28 3, 5.4, 0.4, 21, 19, 22.5, 20.4, Interior 100% Acrylic Enamel 17.4, 13.4, 11.1, 22.9, 18.2, 26.7, Paint + Primer, Eggshell, 11.4 [1, 6] 22.9, 20 [0, 8] Base B Dutch Boy Platinum Plus 28 2.4, 17.2, 14.1, 19.4, 19.6, 15.1, Interior 100% Acrylic Enamel 16.6, 8.6, 12 33.9, 20.4, 21.6 Paint + Primer, Flat, Base B.sup.5 [1, 4] [0, 6] ColorPlace Classic Exterior 12 5, 3.6, 2.9, 2, 5, 4.1, 4.8, 0.6, House Paint, Flat, Accent 0.6, 3.8, 3.2, 1.8, 6.3, 2, 5.9 Base, from Walmart Corp., 4.7 [1, 0] [3, 0] Fayetteville, AR. Dutch Boy Maxbond 14 6, 7.2, 19.1, 7, 10.6, 17.9, Exterior, Satin, Neutral Base 7.8, 2.3, 3.6, 3.9, 8.4, 14.5, 2.4, 5 [3, 1] 3.9, 5.2 [3, 3] Dutch Boy Porch & Floor 12 6, 7.5, 7.1, 14, 19.8, 22.7, Int + Ext, Gloss, Neutral 16.3, 11, 11.4, 21.8, 22.4, 26.6, Base 11.5, 12.5 [3, 5] 8.9, 14.5 [1, 7] Pratt & Lambert 12 8, 7.7, 8.7, 9.1, 13, 14.6, 12.8, 10, Aquanamel Int + Ext, 8.3, 11, 12.5, 10.8, 27.5, 13.9, Semi-Gloss, Neutral Base 9.5 [6, 2] 13.8 [0, 8] Sherwin-Williams Pro 12 5, 17.1, 22.9, 16, 28.5, 40.8, Industrial, Gloss, 21.5, 21.2, 20.2, 23.3, 42.1, 31.5, Clear Base 18.5, 20.5 [1, 7] 19.6, 24 [0, 8] Valspar Seasonflex 12 6, 7.7, 9.5, 15.6, 12, 14.3, 16.6, 17.9, Exterior, Satin, Ultra Deep Base 10.7, 14.1, 11.9, 15.4, 24.7, 16.4, 12.8 [2, 6] 15.5 [0, 8] HGTV Home by Sherwin- 12 2, 2.3, 4.1, 6.8, 10, 9.8, 7.5, 8.8, Williams Everlast, 5.2, 7.1, 5.5, 3.8, 26.2, 13.9, Exterior SemiGloss, Base 4 7.3 [6, 0] 15.7 [3, 4] Valspar Duramax 12 2, 3.8, 7.4, 7.2, 2, 6.4, 6.7, 1.7, Exterior, Satin, Base 4 5, 7.3, 6.3, 5.3 9.1, 9.3, 4.4, 5.7 [6, 0] [6,0] HGTV Home by Sherwin 12 6, 2.4, 3.2, 21.5, 21, 25.3, 21.2, Williams Infinity, 16.6, 15.1, 15, 25.8, 21, 36.5, Interior Semi-gloss, Base 4 20.1 [1, 5] 26.1, 29.3 [0, 8] Valspar Signature 12 11, 4.8, 0.1, 23, 13.9, 16.3, Interior, SemiGloss, Base 4 12, 12.9, 15, 15.2, 12, 27.3, 13.2, 9.1[1,5] 21.8, 18.4 Valspar Simplicity 12 14, 9.6, 5.6, 20, 16.4, 15.2, Interior, Semi-Gloss, Base 4 15.5, 13.1, 12.4, 14.4, 12.3, 25.7, 12.6, 15.5 [2, 6] 17.4, 21.7 [0, 8] Valspar ExpressCoat 12 7, 7.7, 2.8, 8.9, 8, 4.4, 6.8, 6.9, Interior, Eggshell, Neutral 2.5, 4.3, 6.9, 8.1, 6.6, 7.6, 4.1 Base 4 4.1 [4, 0] [6, 0] Valspar ExpressCoat, 12 0, 3.6, 12.7, 8, 13.1, 5.7, Interior, Semi-Gloss, Base 4 16.3, 7.7, 3.3, 16.1, 3.8, 23.8, 2.3, 2 [1, 2] 13.2, 12.5 [1, 5] .sup.3Except as otherwise noted, viscosity drop data is presented in sequence of colors: Medium Yellow, White, Magenta, Raw Umber, Red, Durable Red, Organic Yellow, Durable Yellow. .sup.4Except as otherwise noted, all base paints and stains are from The Sherwin-Williams Company, Cleveland, Ohio. .sup.5Viscosity data in sequence of tested colorants Magenta, Raw Umber, Red, Durable Red, Organic Yellow.

    [0171] The data shows that the inventive colorant compositions demonstrate less viscosity drop, and a more uniform viscosity drop across all colorants in the array, compared to existing colorant compositions.