A method for preparing a material for use as a surface of a medical device may include printing, with an ink jet printer and using ink that is curable with ultraviolet light, content onto a surface of material that includes woven ticking fabric laminated with polyurethane. The method may also include curing the ink with the ultraviolet light. The method may also include cutting a section of the material in registration to the content printed on the surface for use in a medical device.

There is provided an image recording apparatus including: head configured to discharge a photo-curing liquid to a medium; irradiator configured to irradiate a curing light to cure the photo-curing liquid; distance measurer including first light emitter configured to emit a ranging light to measure a distance to the medium, and first light receiver configured to receive the ranging light; and casing housing the head, the irradiator and the distance measurer, and having a window through which an inside of the casing is visually perceptible. First filter is provided on the window, the first filter having a function of restraining transmission of the curing light more compared to transmission of a visible light. Second filter is provided on the first light receiver, the second filter having a function of restraining transmission of the visible light more compared to transmission of the ranging light.

An image-forming apparatus which can improve the heating stability of the recording material in the heating unit is provided. An image-forming apparatus constitutes an image forming apparatus having: a recording-material heating unit disposed in an upstream side of an image-former; a chassis that covers the recording-material heating unit; a pressurizer that is provided in the chassis and increases an air pressure in the chassis; and a gas inflow opening that is provided in the chassis and supplies air to the pressurizer from outside the chassis.

A printing apparatus, including a discharging head, a relative movable assembly to move a printable medium and the discharging head relatively, and a lighting unit including a plurality of light sources to emit light for curing the ink, is provided. A part of the plurality of light sources is arranged in a first lighting area, and another part of the plurality of light sources is arranged in a second lighting area. A quantity of the light sources per unit area in the second lighting area is smaller than a quantity of the light sources per unit area in the first lighting area. A direct distance from the discharging head to the second lighting area in a direction parallel to the predetermined direction is shorter than a direct distance from the discharging head to the first lighting area.

A method of manufacturing an aircraft photoluminescent marker that comprises a substrate includes providing an ink or coating adapted to be cured with ultra violet (UV) radiation and printing one or more markings directly onto the substrate of the photoluminescent marker with the ink or coating, followed by curing the ink or coating with UV radiation. The substrate is one of a photoluminescent material or a housing, and the marking comprises at least one of a pattern, wording, images, blocks, or indicia.

A production line is for aerosol containers (AC) whose exterior surface is printed with inks in a predetermined pattern to form a desired design including both imagery and graphics. The line includes an inking station and a varnish application station through which aerosol containers successively pass. Inks are applied to containers at the inking station and a varnish to the inked exterior of the container at the varnish station. A LED light module (12) installed between the ink station and varnish station emits a light within a predetermined frequency range onto inked containers. The temperature produced by the LED light source is cooler than that of Uv light sources that could be used for the same purpose. The exterior surface of finished containers exhibit no lapping or discolorations and have improved scratch resistance.

A printed material includes a base material, an image layer, and an adhesive layer. The image layer includes an image of a first shape. The adhesive layer has a second shape. The image layer and the adhesive layer are on opposite sides of the base material.

Systems, apparatuses and methods provides for technology that applies, with a printhead of a printing system, ink to a substrate as the substrate remains stationary and the printhead moves across the substrate. The technology determines, with a distance encoder, a distance that the printhead has moved, and controls application of the ink from the printhead to the substrate based on the distance.

A method is disclosed to provide a DTS machine that is simple to operate and can through human operator control provide economic and competitive throughput speeds as compared to more complex DTS machines utilizing multiple printing tunnels and material handlers. The present method repositions a print carriage and a reconfigures an inkjet printhead bank to accommodate different sizes and shapes of media. The allows for the printing of a single piece of media in a single each printing event, but maintains a printing throughput similar to DTS machines having the capability to print media in parallel printing events. Media is moved from a media loading area on the machine by a single operator into a printing tunnel and then the operator adjusts the angle of the media relative to a reconfigurable array of ink-heads to meet inkjet expression distance requirements.

A system is disclosed to provide a DTS machine that is simple to operate and can through human operator control provide economic and competitive throughput speeds as compared to more complex DTS machines utilizing multiple printing tunnels and material handlers. The present invention utilizes a repositionable print carriage and a re-configurable inkjet printhead bank. The printing carriage is vertically positionable and tiltable, and includes a resizable spindle so that varying geometries of print media may be accommodated. The printer prints a single piece of media at each printing event, but maintains a printing throughput similar to DTS machines having the capability to print media in parallel printing events. Media is moved from a media loading area on the machine by a single operator into a printing tunnel and then the operator adjusts the angle of the media relative to a reconfigurable array of ink-heads to meet inkjet expression distance requirements.