The present invention relates to an automatic cushion-attaching device for attaching cut cushions or cutting and attaching cushions to a cutting plate so that the cushions are attached along both sides of the position at which a blade portion is mounted to the cutting plate. At least two of the attached cushions are automatically attached to the cutting plate next to the blade portion according to the shape of the blade portion. Since the operation of attaching the cushions to the cutting plate is automatically performed in a single machine, the present invention has the effect of achieving very high attachment speed and good productivity.

The present invention provides a film forming method of forming a film on a substrate, wherein the substrate includes a region including a first concave portion and a second concave portion, the first concave portion has a width larger than that of the second concave portion, and the film forming method includes: selectively supplying a first material into the first concave portion and molding the first material; and supplying a second material onto the region and molding the second material, such that the second concave portion is filled with the second material and a planarization film of the second material is formed over all of the region.

The present invention aims at developing a robot for applying coating in regions called “difficult access areas” of offshore platforms and ships, such as curved, vertical surfaces, or surfaces with negative inclination angles. The design concept was developed based on a low-weight painting system, integrated into a vehicle with magnetic shoes (104), which produces a constant magnetic force on the metallic surface, capable of guaranteeing the support of the vehicle in the different areas of application. The floating magnetic system aims at ensuring that the wheels (102) have the necessary friction for the vehicle to move. The use of the equipment allows greater productivity, with agility and speed in the application of coatings, reduction of coating losses during the process, repeatability and guarantee of the thickness of the applied layer, in addition to allowing the application of the coating on vertical surfaces, with negative inclinations or curves, without the need for access using scaffolding, dispensing with scaffolding assembly and disassembly services and the use of ropes by professionals for work on the sea, with the consequent reduction in the number of workers on the sea and the reduction of exposure of the man in unhealthy environments.

The present invention aims at developing a robot for applying coating in regions called “difficult access areas” of offshore platforms and ships, such as curved, vertical surfaces, or surfaces with negative inclination angles. The design concept was developed based on a low-weight painting system, integrated into a vehicle with magnetic shoes (104), which produces a constant magnetic force on the metallic surface, capable of guaranteeing the support of the vehicle in the different areas of application. The floating magnetic system aims at ensuring that the wheels (102) have the necessary friction for the vehicle to move. The use of the equipment allows greater productivity, with agility and speed in the application of coatings, reduction of coating losses during the process, repeatability and guarantee of the thickness of the applied layer, in addition to allowing the application of the coating on vertical surfaces, with negative inclinations or curves, without the need for access using scaffolding, dispensing with scaffolding assembly and disassembly services and the use of ropes by professionals for work on the sea, with the consequent reduction in the number of workers on the sea and the reduction of exposure of the man in unhealthy environments.

Disclosed is a dual slot die coater capable of discharging a coating solution through an outlet after removing air bubbles contained in the coating solution. The dual slot die coater according to the present disclosure includes a first air vent installed in the first manifold region and an uppersecond air vent installed in the second manifold region.

Provided herein is a device for forming a conductive film. The device includes a deposition device and an air supply. The deposition device is configured to form a wet film having conductive nanostructures and a fluid carrier on a web. The web is moved in a first direction while forming the wet film. The air supply is disposed at a side of the web and configured to apply an air flow onto the wet film. The air flow is directed onto the wet film in a second direction perpendicular to the first direction to reorient a direction of some conductive nanostructures in the wet film to define reoriented conductive nanostructures.

A control device includes: a first generator generating a first command position of a control object on a plane in each control cycle based on a target trajectory; a first control part generating a first operation amount by model predictive control using a first dynamic characteristic model and the first command position; a second generator generating a second command position of the control object on an orthogonal axis in each control cycle; and a second control part generating a second operation amount by model predictive control using a second dynamic characteristic model and the second command position. Based on shape data indicating a surface shape of an object and the first command position, the second generator generates the second command position so that a distance between the control object and a surface of the object is constant.

A control device includes: a first generator generating a first command position of a control object on a plane in each control cycle based on a target trajectory; a first control part generating a first operation amount by model predictive control using a first dynamic characteristic model and the first command position; a second generator generating a second command position of the control object on an orthogonal axis in each control cycle; and a second control part generating a second operation amount by model predictive control using a second dynamic characteristic model and the second command position. Based on shape data indicating a surface shape of an object and the first command position, the second generator generates the second command position so that a distance between the control object and a surface of the object is constant.

According to the present disclosure, there is provided a coating determining device of a coating head that can prevent coating defect caused by clogging in multiple successive coatings. The coating determining device according to the present disclosure can determine a coating state of the coating head, wherein the coating head having a plurality of nozzles for ejecting paint, the plurality of nozzles being configured to eject the paint out of the nozzles so as to coat a workpiece with the ejected paint while moving in a direction, the coating determining device of the coating head being characterized by comprising: an image acquiring unit for acquiring an image of the coated workpiece; and a determination unit for determining, based on the image acquired by the image acquiring unit, whether coating the workpiece is implemented normally.

According to the present disclosure, there is provided a coating determining device of a coating head that can prevent coating defect caused by clogging in multiple successive coatings. The coating determining device according to the present disclosure can determine a coating state of the coating head, wherein the coating head having a plurality of nozzles for ejecting paint, the plurality of nozzles being configured to eject the paint out of the nozzles so as to coat a workpiece with the ejected paint while moving in a direction, the coating determining device of the coating head being characterized by comprising: an image acquiring unit for acquiring an image of the coated workpiece; and a determination unit for determining, based on the image acquired by the image acquiring unit, whether coating the workpiece is implemented normally.