The present invention has to do with an efficient system for coating and caring engineered wood products (EWP) in general, and the edges of EWPs in particular. An efficient system for coating and curing coatings is provided.

A UV/LED printing and finishing process is disclosed. The printing and finishing process improves the manner in which printing, permanent bonding, and finishing is performed on products containing low surface energy plastics, such as high-density polyethylene furniture. The process includes abrading a surface of the low surface energy plastic and then applying a corona or plasma treatment to the surface of the low surface energy plastic to increase the adhesion capabilities of the surface. Once the surface has been treater, the process may include printing a polymer ink onto the surface of the low surface energy plastic, such as by utilizing a UV/LED flatbed or hybrid printer. The process may also include curing the printed surface of the low surface energy plastic, and then finally applying a clear inorganic top coating onto the printed surface to protect the UV/LED cured polymer ink.

A method for printing a surface (1) with a printed pattern (2) includes printing a first partial structure (3) of the printed pattern (2), printing a second partial structure (3) of the printed pattern (2) at a distance from the first printed structure (3) and treating at least one region (7) between the first printed structure (3) and the second printed structure (3), and the irradiating the region (7) between the first printed structure (3) and the second printed structure (3) with electromagnetic waves and/or soundwaves.

The invention relates to a branched carboxylic acid functional polyester resin P1 as described herein. The invention further relates to a thermosetting powder coating composition (PCC A1) comprising a binder K1, said binder K1 comprising the P1 and a crosslinker X1. The invention further relates to a cured PCC A1. The invention further relates to a process for making said PCC A1 and processes for coating an article with said PCC A1. The invention further relates to an article having coated thereon said PCC A1 as well as to an article having coated and cured thereon said PCC A1. The invention further relates to a thermosetting powder coating composition B (PCC B) comprising a physical mixture of the thermosetting powder coating composition A1 (PCC A1) with a separate, distinct thermosetting powder coating composition A (PCC A). The invention further relates to a process for making said thermosetting powder coating composition B and processes for coating an article with said PCC B. The invention further relates to a cured PCC B. The invention further relates to an article having coated thereon said thermosetting powder coating composition B as well as to an article having coated and cured thereon said thermosetting powder coating composition B. The invention further relates to use of: the polyester resin P1, the PCC A1, the cured PCC A1, the PCC B, the cured PCC B, articles coated with the PCC A1, articles coated with the PCC B, articles having coated and cured thereon the PCC A1, articles having coated and cured thereon the PCC B. The invention further relates to the use of the polyester resin P1 for matt powder coatings. The invention further relates to the use of the PCC B for matt powder coatings.

Wax-modified hyperbranched polyols and wax-modified flexible hyperbranched polyols are described, as are coating compositions containing these polyols. These polyols provide excellent coatings, especially matte coatings, and allow for the exclusion of silica in coatings.

The present disclosure provides a heating system for performing thermal spray coating. The heating system includes (a) a thermal spray element configured to be coupled to a robotic arm, (b) a heating unit configured to be coupled to the robotic arm, (c) at least one processor, and (d) data storage comprising program instructions executable by the at least one processor to cause the heating system to perform functions including (i) receiving a first indication of a spray coating material positioned in the thermal spray element, (ii) receiving a second indication of a material of a substrate onto which the spray coating material is to be sprayed, (iii) heating the substrate for a time period until the substrate reaches a desired temperature that is determined based on both the spray coating material and the material of the substrate, and (iv) spraying the spray coating material onto the substrate.

The invention relates to a thermosetting powder coating composition B (PCC B) comprising a physical mixture of a thermosetting powder coating composition A (PCC A) with a separate, distinct thermosetting powder coating composition A1 (PCC A1). The invention further relates to a process for making said thermosetting powder coating composition B and processes for coating an article with said PCC B. The invention further relates to a cured PCC B. The invention further relates to an article having coated thereon said thermosetting powder coating composition B as well as to an article having coated and cured thereon said thermosetting powder coating composition B. The invention further relates to use of: the PCC B, the cured PCC B, articles coated with the PCC B, articles having coated and cured thereon the PCC B. The invention further relates to the use of the PCC B for matt powder coatings.

A method for manufacturing an enameled wire includes providing a conductor with an enamel coating thereon, and exposing the conductor to a light with a wavelength absorbable by a solvent included in the enamel coating to evaporate the solvent. The light includes a peak wavelength of less than 4 m.

Disclosed herein are methods comprising illuminating a first location of an optothermal substrate with electromagnetic radiation, wherein the optothermal substrate converts at least a portion of the electromagnetic radiation into thermal energy. The optothermal substrate can be in thermal contact with a liquid sample comprising a plurality of capped particles and a plurality of surfactant micelles, the liquid sample having a first temperature. The methods can further comprise generating a confinement region at a location in the liquid sample proximate to the first location of the optothermal substrate, wherein at least a portion of the confinement region has a second temperature that is greater than the first temperature such that the confinement region is bound by a temperature gradient. The methods can further comprise trapping and depositing at least a portion of the plurality of capped particles.

A digitally produced heat transfer can be manufactured by digitally printing an image onto the protective coating that is receptive to ink and/or toner to form a printed area and an unprinted area of the protective coating, and digitally printing an attractant precisely onto the printed area and not onto the unprinted area. An adhesive powder can be applied onto the printed area and the unprinted area. The adhesive powder can then be removed from the unprinted area and the remaining adhesive powder can be bonded to the printed area. A digitally produced heat transfer can include a protective coating that is receptive to ink and/or toner, a digital image printed onto the protective coating to form a printed area and an unprinted area of the protective coating, an attractant digitally printed precisely onto the printed area, and an adhesive powder applied onto the attractant.