A device for depositing paste patterns on the surface of the channel of a tube, the device comprising a frame supporting a first mechanical assembly for holding, positioning and moving the tube, and a second mechanical assembly for extruding paste for depositing said paste patterns, the assemblies cooperating with one another.

An apparatus and method for coating an electrode slurry are disclosed herein. In some embodiments, the apparatus includes a coater configured to coat an electrode slurry on a metal foil, a measuring unit is configured to measure a remaining oil level on a surface of the metal foil before the coater coating the electrode slurry, and a controller configured to control the coater to coat the electrode slurry based on a measurement value of the remaining oil level of the surface of the metal foil.

A coating apparatus includes a discharge unit, moving unit, and a controller. The discharge unit includes a nozzle array in which a plurality of nozzles is arranged, and discharges a coating material from each of the plurality of nozzles. The moving unit moves a position of the discharge unit with respect to a to-be-coated surface along a plurality of paths substantially orthogonal to the nozzle array. The controller determines, based on coating information, a width of a recoated portion on which the coating material is discharged in an overlapping manner between two adjacent paths among the plurality of paths, and determines a discharge amount from each of the plurality of nozzles so that a discharge amount from each of nozzles at an end portion of the nozzle array corresponding to the recoated portion is less than a discharge amount from each of other nozzles of the nozzle array.

A coating apparatus includes a discharge unit, moving unit, and a controller. The discharge unit includes a nozzle array in which a plurality of nozzles is arranged, and discharges a coating material from each of the plurality of nozzles. The moving unit moves a position of the discharge unit with respect to a to-be-coated surface along a plurality of paths substantially orthogonal to the nozzle array. The controller determines, based on coating information, a width of a recoated portion on which the coating material is discharged in an overlapping manner between two adjacent paths among the plurality of paths, and determines a discharge amount from each of the plurality of nozzles so that a discharge amount from each of nozzles at an end portion of the nozzle array corresponding to the recoated portion is less than a discharge amount from each of other nozzles of the nozzle array.

An application device according to an embodiment includes a liquid nozzle part, an air nozzle part, and an ejection controlling unit. The liquid nozzle part ejects liquid to be applied to an electronic component mounted on a substrate. The air nozzle part ejects air toward the substrate. The air nozzle is concentrically arranged with respect to the liquid nozzle part. The ejection controlling unit ejects the air from the air nozzle part at a timing in synchronization with an ejection timing of the liquid to be applied by the liquid nozzle part.

An application device according to an embodiment includes a liquid nozzle part, an air nozzle part, and an ejection controlling unit. The liquid nozzle part ejects liquid to be applied to an electronic component mounted on a substrate. The air nozzle part ejects air toward the substrate. The air nozzle is concentrically arranged with respect to the liquid nozzle part. The ejection controlling unit ejects the air from the air nozzle part at a timing in synchronization with an ejection timing of the liquid to be applied by the liquid nozzle part.

An assembly for decorating a plurality of objects, such as egg-shaped objects. The assembly has a support structure; a vessel for containing decorating material, with an dispensing opening at the bottom; a tether with a first tether end attached to the support structure and a second tether end attached to the vessel; and a substrate base for supporting the plurality of objects. The vessel is configured to swing freely over the objects on the substrate base to dispense the decorating material contained therein to the objects.

A measurement sensor is integrated with a control object so that a position separated from a processing object by the control object along a target trajectory is a measurement point. A control device includes: a first generator that generates a first command position of the control object on a plane; a first control part that generates a first operation amount using a model predictive control; a second generator that generates a second command position of the control object on an orthogonal axis that is orthogonal to the plane; and a second control part that generates a second operation amount using the model predictive control. The second generator generates the second command position so that the distance between the control object and the surface of an object is constant, based on the measurement result of the measurement sensor and the first command position.

Aspects herein are directed to an article of apparel having a vent opening formed by overlapping the edges of a first panel and a second panel. A plurality of discrete overlay film structures are applied to the second panel adjacent to the vent opening. When the article of apparel is exposed to an external stimulus, the film structures undergo a reversible increase in dimension in at least the z-direction which cause the second panel of material to undergo a reversible decrease in dimension in the direction of a longitudinal axis of the vent opening thereby causing the vent opening to dynamically transition from a closed state to an open state.

A surface of a workpiece has a smooth region, and a stepped region including a step. A three-dimensional object printing method includes first print operation of ejecting liquid from a head onto the smooth region, and second print operation, antecedent to or subsequent to the first print operation, of ejecting liquid from the head onto the stepped region. The amount of change in an angle of ejection, which is angle formed by a first normal line and a second normal line, during execution of the second print operation is larger than the amount of change in the angle of ejection during execution of the first print operation. The first normal line is a line normal to the ejection face. The second normal line is a line normal to the surface of the workpiece at a point of intersection with the first normal line.