The objective of the present invention is to provide a deburring control device capable of easily identifying the cause of a deburring failure. A deburring control device according to one aspect of the present disclosure controls deburring processing for removing burrs on a workpiece by moving a deburring tool along a ridge line of the workpiece by means of a robot, and is provided with: an offset amount calculating unit for calculating an offset amount between the actual path of the robot and a taught path thereof; a pressing force acquiring unit for acquiring the pressing force of the deburring tool; a rotational speed acquiring unit for acquiring the rotational speed of the deburring tool; a failure detecting unit for detecting a deburring failure, in which the deburring processing could not be performed appropriately, on the basis of the offset amount, the pressing force, and the rotational speed; and a recording unit for recording a failure reason, which is the reason for the failure detecting unit determining the deburring failure, when the deburring failure is detected.

A tool that is either hand-guided, or machine-guided, for performing surface treatments, such as mopping, of overhead surfaces includes a head for carrying an agitator having a generally planar face that is applied against the overhead surface being treated in uses. A transmission transmits power from a drive motor to the agitator, and an interface on the head is provided for connection to a mounting device by which the head is oriented and guided.

A method for recognizing a deburring trajectory, relevant to be performed by a controller or a computer, includes the steps of: according to a process flow of a workpiece, analyzing a CAD file of the workpiece, determining a burr processing area and obtaining a mathematical model of boundary contour curve; applying a linear contour sensor to scan the workpiece to obtain contour section information of the workpiece; performing curve fitting upon the contour section information of the workpiece and the mathematical model of boundary contour curve so as to obtain a boundary curve function; and, utilizing the boundary curve function to determine deburring position information of the workpiece and to further generate a processing path. In addition, a system for recognizing a deburring trajectory is also provided.

A method applying a bead of a coating product to a surface by a print head equipped with nozzles, each centered on a central axis, the coating product application moves the print head and the surface relative to each other, by moving the print head along a fixed trajectory relative to the surface without rotating the print head about an axis parallel to the central axes of the nozzles. The method includes selecting certain nozzles for a point of the trajectory based on the trajectory direction at this point, and activating the selected nozzles at this point. The selected nozzles are arranged in a line, or form part of a nozzle group delimited by a line, whose regression line coincides with a line as close as possible to a line perpendicular to the trajectory direction from among lines that can be defined with nozzles of the print head.

An applicator head for applying an adhesive tape on a surface or substrate, wherein the adhesive tape comprises a material and at least one removable liner, the applicator head comprising: an application tip; a cutting mechanism positioned adjacent an outer most point of the application tip; a positioning device is configured such that the cutting mechanism severs the material while maintaining the at least one removable liner intact.

-- A method for welding together two parts along a weld line using a welding system enabling an operator to remotely perform welding operations. The operator defines reference points on the parts to be welded and/or on the weld line to be followed. A general movement direction of the welding torch is defined from the reference points. A local frame of reference is defined relative to the general movement direction of the welding torch. The welding torch is automatically moved from a welding starting point in the general movement direction. A flow of movement instructions linked to actions of the operator on the human-machine interface is generated to move the welding torch away from the general movement direction to adapt a trajectory of the welding torch to an actual shape of the weld line. The welding torch is moved corresponding to the flow of instructions generated by the human-machine interface.

The present invention relates to a robot and method for estimating an orientation on the basis of a vanishing point in a low-luminance image, and the robot for estimating an orientation on the basis of a vanishing point in a low-luminance image according to an embodiment of the present invention includes a camera unit configured to capture an image of at least one of a forward area and an upward area of the robot and an image processor configured to extract line segments from a first image captured by the camera unit by applying histogram equalization and a rolling guidance filter to the first image, calculate a vanishing point on the basis of the line segments, and estimate a global angle of the robot corresponding to the vanishing point.

A system for applying material to a part includes an application nozzle attached to a distal end of a robotic arm, a sensor coupled to the distal end of the robotic arm, an actuator mechanically coupled to the application nozzle, and a controller in communication with the actuator and configured to receive data from the sensor and detect a feature of the substrate. The robotic arm is configured to hold the application nozzle in a fixed position and/or traverse a predefined path such that the application nozzle traverses a predefined global bead path across and spaced apart from a substrate. The controller is configured to direct the actuator to move the application nozzle independent of the distal end of the robotic arm such that a bead of material flowing out of the application nozzle is applied to the substrate along a feature-relative bead path.

A system comprising: a source of a tape comprising a material associated with an adhesive and at least one removable liner; an applicator head; a cutting mechanism; at least one drive feeding mechanism configured to index the tape from the source to the applicator head at a controlled rate; wherein the applicator head is controllable to apply the material on a surface or a substrate; and wherein the applicator head comprises a cutting mechanism configured to sever the material while leaving the at least one removable liner intact.

A feeding system configured to transport a material to a tape applicator, the feeding system comprising: a flexible conduit coupled between a spool unloading device and a tape applicator, wherein the flexible conduit receives the material from a source; and a fluid amplifier coupled to the flexible conduit to facilitate movement of the material therein by creating a vacuum effect.