Methods for simultaneously dispensing a first fluid pattern at a first dispense region with a first applicator and a second fluid pattern at a second dispense region with a second applicator. The first and second applicators are moved toward their respective dispense regions with a positioner. While dispensing, the second applicator is moved relative to the first applicator in a direction or directions parallel to a first axis, a second axis, and/or a third axis, the axes being mutually orthogonal. The first dispense region may be provided with a unique first tilt and/or a unique first contour relative to the reference plane and along the third axis. Systems for dispensing fluid include a primary positioner supporting a first applicator, and a secondary positioner coupled to the primary positioner and supporting a second applicator and configured to move the second applicator relative to the first applicator.

A method of depositing material on an electronic substrate with a dispensing system includes acquiring an image of a first feature of a first component and an adjacent second feature of a second component, performing a measure command to measure an actual distance of a gap between the first feature of the first component and the second feature of the second component, dividing the length of the gap into segments to determine a gap width for each segment, based on the gap width, determining a number of dots to be dispensed by the dispensing unit for each segment, and performing the dispense operation for each segment.

Provided are a pump position feedback type dispenser and dispensing method, in which an image of a work, to which a viscous liquid is to be dispensed, is captured to determine an accurate position and direction of the work, and then a position of a pump is received in real time so as to dispense the viscous liquid to the work while ensuring that the pump reaches the accurate position of the work.

There is disclosed a slot-die coating method and apparatus, and a substrate having a patterned coating layer. The method comprises controlling an intermittent transfer of the coating fluid from a slot-die coating head onto the substrate surface to provide, by said intermittent transfer, coated areas on the substrate surface separated by uncoated areas. The substrate surface comprises a pre-patterned layer of high surface energy areas and low surface energy areas; wherein a contact angle of the coating fluid on the substrate surface is lower in the high surface energy areas than in the low surface energy areas. Boundaries between the low surface energy areas and high surface energy areas are arranged along a slit direction of the slot die coating head. The method further comprises synchronizing the intermittent transfer with a passage of an outflow opening over the boundaries between the low surface energy areas and high surface energy areas wherein the transfer is enabled when the outflow opening passes over a high surface energy area and wherein the transfer is disabled when the outflow opening passes over a low surface energy area.

The imprint apparatus of the present invention includes a holding unit configured to hold a mold; a particle inspection unit configured to inspect whether or not particle is present on an imprint area, in which the resin pattern is formed, of the substrate; a dispenser configured to apply an uncured resin to the imprint area; a movable unit configured to move the imprint area with respect to the holding unit; and a controller. The movable unit is capable of moving the imprint area to each of an inspection position by means of the inspection unit, an application position by means of the dispenser, and a contacting position by means of the holding unit. Also, the controller causes the inspection unit to perform inspection of the imprint area in association with the movement of the imprint area by means of the movable unit.

Apparatus and associated methods relate to dynamically generating commands to manage the flow rate of a powder as a function of time in response to arbitrarily shaped target parts traveling along a conveyor. In an illustrative example, a controller may receive shape information about each target part as the part travels along the conveyor. The controller may dynamically generate commands to a pump to control the flow rate of powder to a reciprocating nozzle. In some embodiments, the controller may generate motion trajectory commands to the reciprocating nozzle to deliver a predetermined amount of powder to the target part as the target part travels along the conveyor.

A film deposition system includes a substrate carrier, a film deposition device, a transport device and a cooling device. The substrate carrier includes a carrier body that defines an isolated space therein, and a phase transition material that is filled into the isolated space and that has a melting point ranging between 18 C. and 95 C. The phase transition material is capable of absorbing thermal energy from the carrier body as latent heat to change the phase of the phase transition material from solid to liquid. The cooling device is configured to absorb thermal energy from the substrate carrier so as to change the phase of the phase transition material from liquid to solid.

An automated apparatus and method for coating medical devices such as an intravascular stent, are disclosed in the method, a 2-D image of a stent is processed to determine (1) paths along the stent skeletal elements by which a stent secured to a rotating support element can be traversed by a dispenser head whose relative motion with respect to the support element is along the support-element axis, such that some or all of the stent skeletal elements will be traversed (2) the relative speeds of the dispenser head and support element as the dispenser head travels along the paths, and (3), and positions of the dispenser head with respect to a centerline of the stent elements as the dispenser head travels along such paths The rotational speed of the support and relative linear speed of the dispenser are controlled to achieve the desired coating thickness and coating coverage on the upper surfaces, and optionally, the side surfaces, of the stent elements

An adhesive coating device for coating an inner wall surface of a workpiece provided with holes with an adhesive. A control device automatically executes an operation of applying the adhesive, the operation including positioning of the workpiece, relative positioning of a nozzle that applies the adhesive in a non-contact manner with respect to the workpiece, and moving of the nozzle, in which the adhesive is ejected and applied in an oblique direction from the nozzle to the inner wall surface of the hole, and the angle of the oblique direction is such an angle that the adhesive linearly ejected from the nozzle located outside the hole can be applied to the inner wall surface of the hole with a desired depth without interfering with an opening part of the hole.

A method and apparatus for applying a sealant to a structure. The method comprises scanning a surface of the structure with a vision system to form scanned data. The method further determines a sealant application path for the structure using the scanned data. The method also controls movement of an application tip along the sealant application path using a controller.