Described herein is a process of preparing a structural colored coating film including steps of i) applying colloidal particles dispersed in a solvent mixture including at least two organic solvents onto a substrate to form a colloidal particles layer; ii) drying the colloidal particles layer to form a photonic crystal structure layer; iii) applying a coating composition including at least one thermally crosslinkable resin and at least one crosslinking agent onto the photonic crystal structure layer to form a coating; and iv) heat curing. Also described herein is an article having at least one structural colored coating film obtainable or obtained from the process.

A coated article that demonstrates a sparkle effect and vibrant color over an expanded range of color space is described. A first coating of at least one fluoroolefin and at least one pigment is applied to a substrate, followed by a second coating of at least one fluoroolefin and at least one effect additive. The effect additive is glass flake designed to provide a sparkle effect. The cured film may be provided in a wide range of colors warrantied similar to conventional coatings. A method of making these coated articles is also provided.

A coated article that demonstrates a sparkle effect and vibrant color over an expanded range of color space is described. A first coating of at least one fluoroolefin and at least one pigment is applied to a substrate, followed by a second coating of at least one fluoroolefin and at least one effect additive. The effect additive is glass flake designed to provide a sparkle effect. The cured film may be provided in a wide range of colors warrantied similar to conventional coatings. A method of making these coated articles is also provided.

A special light saber blade coating and a process to make the coated blade which provides a replica sword as an authentic-looking device as seen in “Star Wars” movies, out-takes and re-enactments. The sword blade device provides a unique and realistic replica of the light saber. The process using epoxy, color glitter and other materials is a set of repetitive steps to place the mixture of epoxy onto the blade with a method that is economic and repeatable producing a light saber blade with quality and durability.

An multi-layer coating film 12 includes: a luster coat 15 containing a luster material; a color coat 16 applied on the luster coat 15, containing a pigment 21, and having translucency; and a coloring flake 22 included in the luster coat 15 and acting as the luster material to color a surface of a luster flake with a coloring material in the same type of color as a color type of the color coat 16.

The purpose of the present invention is to obtain a method for forming an excellent multi-layer coating film of high chroma and brightness and a rich color. With the method, color mottling does not occur easily in the coating film and the design obtained is homogeneous even without strict control of variations in film thickness during coating. The method for forming the excellent multi-layer coating film comprises: forming a metallic base coating film on the surface of the object to be coated by applying a metallic base coating containing a shiny material; then forming a color base coating film by applying a color base coating; subsequently forming a clear coating film by applying a clear coating on the color base coating film; and heat-curing the metallic base coating film, the color base coating film and the clear coating film obtained. In the method, the light reflectance of the metallic base coating film is in a specified range and the light transmittance of the single color base coating film obtained by heat-curing the color base coating film as a single film is adjusted to a specified range.

The purpose of the present invention is to obtain a method for forming an excellent multi-layer coating film of high chroma and brightness and a rich color. With the method, color mottling does not occur easily in the coating film and the design obtained is homogeneous even without strict control of variations in film thickness during coating. The method for forming the excellent multi-layer coating film comprises: forming a metallic base coating film on the surface of the object to be coated by applying a metallic base coating containing a shiny material; then forming a color base coating film by applying a color base coating; subsequently forming a clear coating film by applying a clear coating on the color base coating film; and heat-curing the metallic base coating film, the color base coating film and the clear coating film obtained. In the method, the light reflectance of the metallic base coating film is in a specified range and the light transmittance of the single color base coating film obtained by heat-curing the color base coating film as a single film is adjusted to a specified range.

Disclosed are coating material compositions including (i) at least one polyol component (A), (ii) at least one crosslinking agent component (B) having groups reactive toward hydroxyl groups of component (A), (iii) at least one polyamide component (P1) in which the acid amide groups are connected by a saturated, aliphatic hydrocarbyl radical having 6 to 10 carbon atoms. Component (P1) is used in particulate form in which a size distribution (D.sub.50) is 20 to 100 μm. The coating material compositions further include (iv) at least one polycarboxamide component (P2) possessing the following structural formula ##STR00001##
in which s is 1, 2 or 3, t is 0 or 1, s+t is 2 or 3, R is a specific (s+t)-valent organic radical, and at least one of the radicals R.sup.1 and R.sup.2 carries at least one hydroxyl group. Also disclosed are methods of producing the coating material compositions.

Disclosed are coating material compositions including (i) at least one polyol component (A), (ii) at least one crosslinking agent component (B) having groups reactive toward hydroxyl groups of component (A), (iii) at least one polyamide component (P1) in which the acid amide groups are connected by a saturated, aliphatic hydrocarbyl radical having 6 to 10 carbon atoms. Component (P1) is used in particulate form in which a size distribution (D.sub.50) is 20 to 100 μm. The coating material compositions further include (iv) at least one polycarboxamide component (P2) possessing the following structural formula ##STR00001##
in which s is 1, 2 or 3, t is 0 or 1, s+t is 2 or 3, R is a specific (s+t)-valent organic radical, and at least one of the radicals R.sup.1 and R.sup.2 carries at least one hydroxyl group. Also disclosed are methods of producing the coating material compositions.

This coated metal sheet for exterior covering has a metal sheet and a top coating layer disposed on the metal sheet, the top coating layer is configured from a fluororesin and contains a gloss control agent comprising 0.01-15 vol % of microporous particles and a matte agent comprising primary particles, and the coated metal sheet satisfies the belowmentioned formulae. In the number-based particle size distribution of the gloss control agent and the matte agent, R is the number average particle size (μm) of the gloss control agent, D1.sub.97.5 and D2.sub.97.5 represent the 97.5% particle size (μm) of the gloss control agent and the matte agent, Ru is the upper limit particle size (μm) of the gloss control agent, and T is the top coating layer thickness (μm).

D1.sub.97.5/T≦0.9

Ru≦1.2T

R≧1.0

0.5≦D2.sub.97.5/T≦7.0

3≦T≦40.