A system for delivering and applying a flowable mixture to an article (311-313) is disclosed. The system includes a mixture delivery system (200) and a skinning system (300). The mixture delivery system (200) includes a mixer (220) configured to mix a dry material and a fluid to produce the flowable mixture, and a pump (235) configured to pump the flowable mixture to a delivery line. The skinning system (300) receives the flowable mixture from the mixture delivery system (200) through the delivery line. The skinning system (300) includes a skinning pipe (310) configured to apply the flowable mixture to the article (311-313) and a manifold (305) that supports the skinning pipe (310). The skinning system (300) also includes an article feeding mechanism (315) configured to push the article (311-313) into the skinning pipe (310). The skinning system (300) includes a transfer system (320) configured to hold the article (311-313) and move the article (311-313) out of the skinning pipe (310).

The present application discloses a coating method including: detecting a shape of an object over a coating zone which extends from a start point position to an end point position to generate first detection data before application of coating agent to the object; moving a bracket for holding a nozzle for discharging the coating agent with bringing the bracket into contact with the object to apply the coating agent to the object over the coating zone; detecting a shape of the object after application of the coating agent over the coating zone, to generate second detection data; extracting first extraction data and second extraction data in correspondence to detection positions intermittently set in the coating zone from the first detection data and the second detection data; and comparing the first extraction data with the second extraction data to detect a coating state of the coating agent.

When a portion for measuring the plating adhesion amount reaches an upstream side position, plating adhesion amount estimation values are calculated by using a plating adhesion amount estimation expression at positions away from a position that faces the distance sensors, that is, the upstream side position, by strip-width direction distances, of the surfaces of the steel strip. When the portion for measuring the plating adhesion amount reaches a downstream side position, the strip-width direction distances of the plating adhesion amount meters are matched to the strip-width direction distances, and the plating adhesion amount actual measurement values are obtained. The plating adhesion amount estimation expression is corrected on the basis of the differences between the plating adhesion amount estimation values and the plating adhesion amount actual measurement values. Accordingly, the control accuracy of the plating adhesion amount is improved.

A method of installing a glass panel on a vehicle that includes an opaque coating formed about a perimeter of the glass panel that includes a plurality of voids where the opaque coating is absent. The method includes determining whether a primer has been applied to the opaque coating by inspecting the glass panel to determine whether at least some of the plurality of voids have been covered by the primer. After determining whether a primer has been applied to the opaque coating, it is determined whether the primer has been correctly applied to the opaque coating by inspecting the glass panel to determine whether each of the plurality of voids has been covered by the primer. Then, after determining whether the primer has been correctly applied, an adhesive may be applied to the primer and the glass panel may be installed on the vehicle.

A system for applying material to a substrate includes a nozzle, robot, actuator, sensor, and controller. The robot provides primary movement such that the nozzle traverses a predefined global bead path across and spaced apart from the substrate. The actuator provides secondary relative movement between the nozzle and substrate. The sensor senses a first location on the substrate that is spaced apart from a location where the nozzle deposits material by a distance based on a sensor response time and relative speed of the nozzle and substrate. The controller detects a feature of the substrate based on the data received from the sensor. The controller directs the actuator to provide the secondary relative movement such that a bead of material is applied to the substrate along a feature-relative bead path. The controller controls the actuator to provide the secondary relative movement based on the response time and the relative speed.

Methods of dispensing fluid are disclosed. A first applicator is positioned above a first dispense site at a first dispense region of a first electronic substrate by moving the first applicator using a primary positioner. A second applicator is simultaneously positioned above a first dispense site at a second dispense region of the first electronic substrate by moving the second applicator together with the first applicator using the primary positioner and moving the second applicator relative to the first applicator using a secondary positioner. It is then determined that the first or the second dispense region is misaligned relative to the other of the first or the second dispense region. Fluid is dispensed from the first applicator while moving the first applicator using the primary positioner to form a first fluid pattern at the first dispense region and fluid is simultaneously dispensed from the second applicator while moving the second applicator using the primary positioner and the secondary positioner.

An apparatus (100) for depositing a radius filler (102), made of a homogeneous material, into a groove (104), formed in a workpiece (106) comprises a chassis (110), first means (120) for extruding the radius filler (102) along an extrusion axis (112), second means (130) for providing the homogeneous material to the first means (120), and third means (140) for compacting the radius filler (102) in the groove (104). The apparatus (100) also comprises a first sensor (150) configured to provide first-sensor output. The apparatus (100) further comprises a controller (180), operatively coupled to the first means (120), the second means (130), and the first sensor (150). Based on the first-sensor output, the controller (180) is configured to determine the first geometric characteristics of the groove (104). In addition, based on the first geometric characteristics, the controller (180) is configured to control second geometric characteristics of the radius filler (102), extruded by the first means (120), as the tool center point (122) is moved relative to the groove (104).

An apparatus for accurately coating discrete patches of coating on a moving substrate is described. The coating system applies coating to a moving substrate using a coating distribution device. A flow pump pumps the coating from a reservoir into the coating distributing device where a portion of the coating is deposited and the remainder is allowed to returned back to the reservoir. The coating distribution device selectively meters a portion of the coating it receives from the flow pump onto the substrate at a variable rate. When the coating distribution device transitions from metering to not metering and to reverse metering, it induces a vacuum in the coating distribution device. The induced vacuum causes a portion of the coating being distributed onto the substrate to flow in reverse quickly breaking the deposition of the coating.

An imprint apparatus includes a mold stage that holds a mold, a substrate stage that holds a substrate, a dispensing device that dispenses resin on the substrate, and a controller configured to obtain a result of a foreign substance inspection conducted on the substrate. In a case that the obtained result indicates existence of a foreign substance, the controller controls the dispensing device to dispense the resin onto the foreign substance, cures the dispensed resin without bringing the resin into contact with the mold, controls the dispensing device to dispense the resin again on a first chip region of the substrate where the foreign substance and the cured resin thereon exists, and performs imprint processing to the first chip region.

An apparatus and method for displaying digital content onto a vehicle, the apparatus including a foam apparatus, a sensor configured to detect vehicle dimension data, at least a processor and a memory communicatively connected to the at least a processor, wherein the memory contains instructions configuring the at least a processor to receive the vehicle dimension data, calculate a concentration requirement based on the vehicle dimension data, transmit the concentration requirement to the foam apparatus, wherein the foam apparatus is configured to disperse foam onto the vehicle based on the concentration requirement, and a display device including a digital content projector, wherein the display device is configured to display a plurality of digital content onto the foam dispersed onto the vehicle.