Provided is a coating apparatus including: a liquid coating section; an adjusting section which is configured to be capable of coming into contact with and/or separating from the liquid coating section, and which adjusts an amount of the liquid in the liquid coating section; and a hardware processor differentiating the contact timing between the coated medium and the liquid coating section and the contact timing between the liquid coating section and the adjusting section in a case where the coated medium is coated with the liquid.

Systems and methods for coating a thin film with a viscous material, such as a liquid, a paste, or an adhesive, at a desired thickness. In such a system, two films move adjacent to one another, optionally in opposite directions, atop two rollers separated by a known gap that defines a coating thickness, with the material being transferred from one film to the other. The rollers may be maintained in their relative positions by springs and/or linear actuators and positioned using linear encoders. In alternative arrangements, the material to be coated could be low viscosity material such as a polymeric solution. Air knives may be provided near the gap to create an air flow that aids in preventing the free flow of low viscosity materials outside the bounds of the film during coating.

Systems and methods for coating of a thin film with a viscous material, such as a liquid, a paste, or an adhesive, at a desired thickness. In such a system, two films move adjacent to one another, optionally in opposite directions, atop two rollers separated by a known gap that defines a coating thickness, with the material being transferred from one film to the other. The rollers may be maintained in their relative positions by springs and/or linear actuators and positioned using linear encoders. In alternate arrangements, the material to be coated could be low viscosity material such as a polymeric solution. Air knives may be provided near the gap to create an air flow that aids in preventing the free flow of low viscosity materials outside the bounds of the film during coating.

Liquid applicators and methods. The liquid applicators include a frame and an applicator head operably coupled to the frame and configured to support a section of an applicator fabric for operable application of a liquid to a substrate. The liquid applicators further include a fabric conveyance system that is operably coupled to the frame and includes a fabric pay-out assembly configured to supply the applicator fabric to the applicator head and a fabric take-up assembly configured to receive the applicator fabric from the applicator head. The liquid applicators further include a liquid delivery system configured to deliver the liquid to the section of the applicator fabric. The methods include delivering the liquid to the section of applicator fabric, engaging the section of applicator fabric with the substrate, and moving the section of the applicator fabric across the substrate to apply the liquid thereto.

Liquid applicators and methods. The liquid applicators include a frame and an applicator head operably coupled to the frame and configured to support a section of an applicator fabric for operable application of a liquid to a substrate. The liquid applicators further include a fabric conveyance system that is operably coupled to the frame and includes a fabric pay-out assembly configured to supply the applicator fabric to the applicator head and a fabric take-up assembly configured to receive the applicator fabric from the applicator head. The liquid applicators further include a liquid delivery system configured to deliver the liquid to the section of the applicator fabric. The methods include delivering the liquid to the section of applicator fabric, engaging the section of applicator fabric with the substrate, and moving the section of the applicator fabric across the substrate to apply the liquid thereto.

An ultraviolet bottom coating system including a conveyor mechanism configured to route a plurality of cans in a machine direction, wherein the plurality of cans each have a bottom surface and uncured coating material applied on the bottom surface. The system also includes at least one ultraviolet light-emitting diode (UV-LED) device configured to emit ultraviolet radiation towards the plurality of cans, wherein the ultraviolet radiation is configured to cure the uncured coating material onto the bottom surface.

Apparatus and method are described and useful for, among other things, providing a layer by layer coating of materials on a belt. A directional gas curtain producing element is used to provide a gas curtain blowing on the belt in an upstream direction that simultaneously meters liquid from the belt and dries the belt.

Apparatus and method are described and useful for, among other things, providing a layer by layer coating of materials on a belt. A directional gas curtain producing element is used to provide a gas curtain blowing on the belt in an upstream direction that simultaneously meters liquid from the belt and dries the belt.

A system and method is provided for creating a structure including a vasculature network. A film deposition device is configured to dispense droplets onto a surface of a substrate to form a curable fugitive pre-patterned liquid film on the surface of the substrate. An electrohydrodynamic film patterning (EHD-FP) device has a patterned electrode structure formed to generate an electric field and to subject the film on the surface of the substrate to the electric field. The film thereby being formed by the EHD-FP into patterned features in response to being subjected to the electric field. Then a casting system is configured to cover the patterned features in an epoxy to form patterned structures, wherein the patterned structures comprise a fugitive vasculature structure.

A system and method is provided for creating a structure including a vasculature network. A film deposition device is configured to dispense droplets onto a surface of a substrate to form a curable fugitive pre-patterned liquid film on the surface of the substrate. An electrohydrodynamic film patterning (EHD-FP) device has a patterned electrode structure formed to generate an electric field and to subject the film on the surface of the substrate to the electric field. The film thereby being formed by the EHD-FP into patterned features in response to being subjected to the electric field. Then a casting system is configured to cover the patterned features in an epoxy to form patterned structures, wherein the patterned structures comprise a fugitive vasculature structure.