A method of manufacturing an automobile emblem is disclosed, which is for manufacturing an emblem that is to be disposed on a front surface of an automobile and represents a particular shape. A method of manufacturing an automobile emblem according to an embodiment of the invention can provide an automobile emblem that has a metallic texture and a silver luster without hindering the reception of waves for an automobile front radar.

A module for emitting radiations for curing and/or drying curable/dryable treatments like paints or glue applied on products includes a UV LED, emitting between 200 and 400 nm, or one IR LED, emitting between 600 and 1400 nm; a control circuit of the UV or IR LED; a supply circuit; a control circuit of the module; and a sensor detecting the product to be cured/dried.

Systems for depositing materials and related methods are described. The systems allow condensing or depositing a precursor on a substrate, and then curing condensed or deposited precursor to form a layer.

Coated grain oriented electrical steel plates and methods of producing the same are provided. In an exemplary embodiment, a method includes producing molten steel with from about 2.5 to about 4 weight percent silicon, from about 0.005 to about 0.1 weight percent carbon, and from about 90 to about 97.5 weight percent iron. The molten steel is cast into a slab and then cold rolled into a plate having a surface. The plate is decarbonized using a decarbonization anneal, and then recrystallized using a recrystallization anneal to produce grain oriented electrical steel. A coating is applied overlying the surface, where the coating includes an organic radiation curable crosslinking agent and a photo-initiator. The coating is cured by exposing it to a radiation source.

The present disclosure relates to the technical field of water-based acrylic resin coatings, in particular to a method for creating a water-based acrylic resin coating with high water resistance. It includes the following steps: selecting a commercially available water-based acrylic resin paint; mixing the water-based acrylic resin paint and ethyl acetate to obtain solution A, spraying solution A on a surface of a material or immersing the material in solution A, and then solidifying; mixing lye and a silver precursor solution to obtain solution B; immersing the cured material in solution B and then drying the cured material.

The present invention relates to a resin composition comprising 20-70 wt % of an aromatic di(meth)acrylate component; 5-25 wt % of a flexible di(meth)acrylate component; and 10-70 wt % of a crosslinker component; wherein the resin composition further comprises: 0.1-10 phr initiator; 0-10 phr silica; and 5-50 phr milled carbon fiber. The invention also relates to a polymerized coating disposed over a substrate, the coating comprising 20-70 wt % aromatic di(meth)acrylate subunits; 5-25 wt % flexible di(meth)acrylate subunits; and 10-70 wt % crosslinker subunits; wherein the coating further comprises: 0.1-10 phr silica; and 5-50 phr milled carbon fiber. The invention also relates to a method of depositing a coating over a substrate, the method comprising the steps of: providing a resin composition; applying the resin composition over a substrate; and polymerizing the resin composition to form a solid coating.

Inside a heating space of a heating chamber, a first heating treatment of moving a substrate along a substrate moving direction is performed by a first conveyor. After that, first conveyance processing of moving the substrate along a conveying direction is performed by a second conveyor. At this time, source mist is sprayed on the substrate by first thin film forming nozzles. Subsequently, second heating treatment is performed by a third conveyor. After that, second conveyance processing is performed by a fourth conveyor. At this time, source mist is sprayed on the substrate by second thin film forming nozzles.

An energy-sensitive composition that yields a cured product with excellent thermal resistance and crack resistance, a cured product of the composition, and a method of forming a cured product. The energy-sensitive composition includes a polysilane and a thermal base generator, in which the thermal base generator includes an ionic compound and a nonionic compound. An anion moiety in the ionic compound preferably includes at least one of an anion having an oxaxanthone skeleton, an anion having a ketoprofen skeleton, and an anion having a fluorenone skeleton.

Systems for depositing materials and related methods are described. The systems allow condensing or depositing a precursor on a substrate, and then curing condensed or deposited precursor to form a layer.

Systems and processes for curing a wet coating of a coated substrate are disclosed. The system includes a ventilation system and a curing room configured to receive the coated substrate being displaced along a displacement axis and includes at least an upstream curing section and a downstream curing section. The upstream curing section includes an upstream catalytic infrared heating system for producing an upstream infrared radiation at an upstream radiation intensity to heat and partially cure the wet coating while the coated substrate is being displaced through the upstream curing section. On the other hand, the downstream curing section includes a downstream catalytic infrared heating system for producing a downstream infrared radiation at a downstream radiation intensity, being lower than the upstream radiation intensity, to further cure the wet coating while the coated substrate is being displaced through the downstream curing section for producing a cured coating.