An ultraviolet bottom coating system including a conveyor mechanism configured to route a plurality of cans in a machine direction, wherein the plurality of cans each have a bottom surface and uncured coating material applied on the bottom surface. The system also includes at least one ultraviolet light-emitting diode (UV-LED) device configured to emit ultraviolet radiation towards the plurality of cans, wherein the ultraviolet radiation is configured to cure the uncured coating material onto the bottom surface.

The objective of the present invention is to provide a coating device capable of stably coating a coating agent onto a member to be coated, while preventing the supply of excess coating agent. A coating device is provided with: a roller which rotates in one direction; a tank in which an opening is formed facing the roller and which supplies a coating agent via the opening; a doctor blade provided at the side of the opening on the rotation exit side of the roller; and a doctor blade provided at the side of the opening on the rotation entry side of the roller; wherein a gap formed between the doctor blade and the roller is larger than a gap formed between the doctor blade and the roller.

A method is provided for decision support in regulating an adhesive coating applied to Yankee dryers. Online sensors are configured to continuously measure stock characteristics, and additional sensors provide actual stock flow rate and machine speed. A controller predicts potential natural coating application from a fibrous sheet generated from the stock to the Yankee dryer surface, substantially in real time, based on the measured characteristics and sensed actual machine values. An output signal may be provided to a display unit, wherein an optimal adhesive coating feed rate may be determined and displayed for operator decision support. The controller may in an automatic mode be configured to regulate the adhesive coating feed rate based on a comparison of one or more determined optimal values associated with respective actual values. The method may include identifying fiber source changes in real time, and predicting a natural coating potential based partly on predetermined correlations.

A bookbinding machine calculates a rotational speed coefficient, which represents the percent change of a rotational speed of a pump 6 relative to the reference rotational speed of the pump, depending on a thickness of a book block P to be bound and a conveying speed of a clamper by use of a first function defining a relationship between the thickness of the book block and the rotational speed coefficient and a second function defining a relationship between the rotational speed coefficient and the conveying speed of the clamper, calculates the set value of the rotational speed of the pump based on the rotational speed coefficients and the reference rotational speed, and sets the rotational speed of the pump according to the set value of the rotational speed.

A bookbinding machine calculates a rotational speed coefficient, which represents the percent change of a rotational speed of a pump 6 relative to the reference rotational speed of the pump, depending on a thickness of a book block P to be bound and a conveying speed of a clamper by use of a first function defining a relationship between the thickness of the book block and the rotational speed coefficient and a second function defining a relationship between the rotational speed coefficient and the conveying speed of the clamper, calculates the set value of the rotational speed of the pump based on the rotational speed coefficients and the reference rotational speed, and sets the rotational speed of the pump according to the set value of the rotational speed.

A sealing system for applying resin to a cut edge of a composite structure, the cut edge having exposed carbon fibers. The system includes: a tool that comprises a nozzle and a resin source; a controller configured to control: a movement of the tool, and flow of resin from the resin source to the nozzle; and an application tip connected to the nozzle of the tool and configured to apply the resin to the cut edge of the composite structure. The application tip may have an exterior surface with a circular cross section and an indentation for a first length along a longitudinal axis of the application tip and a first end and a second end configured such that a resin flows from the first end to the second end.

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 coating treatment apparatus for applying a coating solution to a peripheral portion of a substrate, includes: a holding and rotating part holding and rotating the substrate; a coating solution supply nozzle supplying the coating solution to the peripheral portion of the substrate; a moving mechanism moving the coating solution supply nozzle; and a controller controlling the holding and rotating part, coating solution supply nozzle, and moving mechanism, wherein the controller performs control of, while rotating the holding and rotating part: by controlling the moving mechanism while supplying the coating solution by the coating solution supply nozzle, both moving the coating solution supply nozzle from an outside of a perimeter of the substrate to a predetermined position at a periphery on the substrate at a first speed and then moving the coating solution supply nozzle from the predetermined position to the outside of the perimeter at a higher second speed.

A remote adhesive monitoring system is used in connection with adhesive applied to workpieces moving along a production line. A reservoir, pump, and applicator apply the adhesive to the workpieces. A monitor control computer has an associated data processing program. A pump cycle sensor senses pump cycles. An applicator sensor senses when the adhesive is applied to the workpieces. A workpiece sensor senses the workpieces moving along the line. The monitor control uses input from the applicator sensing means and the workpiece sensor to determine an ON time per each workpiece at a predetermined speed. The monitor control uses input from the workpiece sensor and the pump cycle sensor to determine the number of workpieces per pump cycle. The monitor control calculates an ON time to TOTAL time ratio per each workpiece. The monitor control will then calculate an amount of adhesive used for the given ON time to TOTAL time ratio.

An application device for applying at least one fluid product on a substrate, including an application member having an outlet orifice for the fluid product(s) outside the application device and, for at least one fluid product, an adjusting member able to adjust a dosing flow of the fluid product through the outlet orifice as a function of a command input of the adjusting member provided by a command module, the application device also including a speed measuring device able to determine a measured speed of the outlet orifice relative to an inertial reference, the command module being configured to determine the command input as a function of the measured speed.