Described herein are methods for printing conductive ink on a substrate. In one embodiment, the method for printing a conductive ink on a substrate, comprises (a) printing, using a printer, one or more layers of a non-conductive material on a surface of the substrate such that one or more channels are formed to produce a template on the surface of the substrate; and (b) printing one or more layers of the conductive ink within the one or more channels In another embodiment, substrates produced by the methods described herein are provided. In another embodiment, systems for implementing the procedures described herein are provided.

A method for manufacturing the texture of an artificial stone slab, comprising the following steps: Step S01: using a printer to print an image in accordance with the size of an artificial stone slab to arrive at a print of the image; Step S02: placing the front face of the print onto a side of the artificial stone slab and smoothing out the print on the artificial stone slab; Step S03: feeding the artificial stone attached to the print into a heat and ink transferring machine and using the upper and lower clamp plates of the heat and ink transferring machine to tightly clamp the print to the artificial stone slab; Step S04: heating the artificial stone slab to 120° C. to 185° C. and maintaining for the temperature constant for 5-15 minutes, wherein the ink on the print is transferred onto the surface of the artificial stone slab; and Step S05: feeding the artificial stone slab, heated in accordance with the above step, out of the heat and ink transferring machine, removing the print, and cooling the artificial stone slab to room temperature.

This disclosure describes container(s) having an ultraviolet (UV)-cured matrix and methods to create the same. The glass container according to this disclosure has a bottom and a body extending in a direction away from the bottom along a longitudinal axis. The body has a surface having an UV-cured matrix including UV-curable varnish drops arranged in a plurality of layers and having voids existing therebetween to form a porous matrix structure. A method of printing a UV-cured matrix on a glass container is also disclosed that includes identifying a plurality of locations on a body of the container where the UV-cured matrix will be formed, determining a height value of the UV-cured matrix at each location, applying at least one varnish layer to the body according to an assigned grayscale or numeric value at each location, and applying UV light to cure each respective varnish layer.

The disclosure relates to methods of manufacturing surface materials for construction or manufacturing use and the surface materials produced by such methods. Substrate materials, such as synthetic or engineered stone or fiber-reinforced resinous panels, can be formed in conventional ways such as casting, molding, or pressing. Layers are printed onto substrate materials to form textures, which may include inks to selectively color the printed texture, thereby enabling a wide variety of high-resolution appearances. A clear, protective topcoat is then applied to the surface materials and cured to provide a finished material.

A coating material for the production of a UV-curing primer coating. The coating material includes at least 60 to 90 wt.-% of at least one monofunctional cycloaliphatic acrylate monomer or at least one monofunctional aryloxy alkyl acrylate monomer, 1 to 10 wt.-% of at least one amino-functional silane, 1 to 10 wt.-% of at least one photoinitiator, and up to 10 wt.-% of at least one of at least one acrylate oligomer and at least one methacrylate oligomer, each based on a total weight of the coating material.

The present invention relates to a method of high-speed recording and reading data on or in a layer (10) of a first material and to a device for high-speed recording and reading data on or in a layer (10) of a first material using a laser source (19, a galvanometer (4) and a digital micromirror (5) adapted to emit multiple laser beams.

Systems and methods for printing a plurality of images on a substrate include, for each of the plurality of images: determining whether that image is a removable image or a permanent image, identifying, based on the determination, at least one layer to be used for printing that image in addition to a marking material layer that forms the image. The at least one layer may be a pre-coat layer applied under the marking material layer and/or a post-coat layer applied over the marking material layer. The marking material layer and the at least one layer are then printed on the object.

A digital dispense system and methods for preparing samples for analysis. The digital dispense system includes a fluid droplet ejection system housed in a housing unit. The fluid droplet ejection system contains a fluid droplet ejection head and fluid cartridge containing one or more fluids to be dispensed. A cartridge translation mechanism is provided for moving the fluid droplet ejection head and fluid cartridge back and forth over a sample holder in an x direction. A sample tray translation mechanism moves a sample tray back and forth beneath the fluid droplet ejection head and fluid cartridge in a y direction orthogonal to the x direction.

Ink for producing laser light sources. The ink is used for inkjet printing to produce laser light sources of a certain scale. The ink comprises a luminescent dye, a host material, and a solvent. The use of the ink makes it possible to produce laser light sources through inkjet printing. This provides a novel technical solution for cheap and industrial manufacturing of laser light sources and other related products through inkjet printing.

Method for providing a natural colour and optical depth to a dental object comprising the steps: providing a framework of the dental object, taking an object colour picture of an adjacent dental object or reference dental object, and uploading the object colour picture into a computing device, calibrating and adjusting the uploaded object colour picture into a target object colour picture in a computing device, (pre)determining the thickness profile of the enamel material to be applied on the framework, correcting in a computing device of the digital picture elements of the target object colour picture for the thickness profile of the enamel material to be applied on the position of the digital picture elements and providing a print colour picture of the corrected digital picture elements, printing the print colour picture as a print layer on the framework, applying the enamel material in the predetermined profile-thickness upon the print layer upon the framework.