Apparatus and method for a painting machine are provided. The painting machine may include an end effector controlled by custom software. The custom control software may be capable of coordinated n-axis manipulation of an end. Illustrative end effectors may include an inkjet head, brush, air brush or any suitable tool for applying ink, paint, color and/or texture to a surface. For example an end effector may utilize oil-based ink or ultraviolet-cured ink. Illustrative surfaces may include canvas, paper, brick, glass etc. The custom control software may control manipulation of the end effector based on a variety of electronic inputs. The custom software may manipulate different end effectors in different ways depending on the input data, type of ink/paint being used, type of surface receiving the ink/paint or any other variable.

The disclosure relates to a coating method including the specification of at least one coating path for moving a paint impact point along at least one coating path over the surface, the at least one coating path running through a surface region of the component to be coated which is bounded by edges. The disclosure also includes, presetting reference values of the spatial edge point positions and/or of the edge point orientations of the surface region, spatial measurement of position, orientation and/or shape of the component to be coated or of a part of the component to be coated with a measuring system, where, in the course of the spatial measurement, measured values of the edge point positions and/or of the edge point orientations of the edge points on the edges of the surface region are measured. Lastly, the disclosure includes determining the deviation between the measured values of the edge point positions and/or the edge point orientations and the reference values of the edge point positions and/or the edge point orientations, and adapting the coating path as a function of the deviation between the reference values of the edge point positions and the measured values of the edge point orientations.

An apparatus for dispensing a viscous fluid includes a dispenser module including a nozzle which dispenses a viscous fluid according to a profile; a robot module configured to move the nozzle according to the profile; a vision module configured to generate an image by photographing a workpiece to which the viscous fluid is dispensed; and a control module configured to integrally control the dispenser module and the robot module based on the image received from the vision module to dispense the viscous fluid according to the profile, wherein, in order to generate the profile, the control module provides a user with an interface which enables the user to input a pattern of the viscous fluid in such a way as to draw the pattern on the image. A user may freely generate a pattern of a viscous fluid, and may accurately dispense the viscous fluid according to the generated pattern.

An overspray-free paint system includes: a paint robot including an overspray-free paint applicator; and a first fixture robot for lifting and orienting a fixture assembly relative to at least one of the paint robot and the overspray-free paint applicator, the fixture assembly configured to hold an object to be painted by the overspray-free paint applicator, the first fixture robot including a first gripper configured to grab a first portion of the fixture assembly, and the first fixture robot configured to lift and orient the fixture assembly via the first gripper.

A multi-axis robot having a kinematic chain with a tool member and at least one additional member, the tool member supporting a first tool. The associated robot control mechanism comprises a kinematic control mechanism designed to receive the movement path of the first tool using a parameterizable tool center point and to control members of the kinetic chain in such a way that the tool center point follows the movement path. The robot control mechanism maintains all the members along the kinematic chain of the tool member of another member which supports the second tool in a fixed position, it parameterizes the tool center point on a working point of the second tool, and transfers the movement path of the second tool to the kinematic control mechanism so that the latter, under the condition that the fixed position of the members is maintained, controls the remaining members of the kinematic chain using the newly parameterized tool center point so that the tool center point follows the movement path of the second tool.

A system for painting an interior wall of housing is disclosed. The system includes a semi-automatic painting robot 106 and a user device 104. The semi-automatic painting robot 106 includes a microprocessor 304, a servo drive module 306, a DC motor drive module 316, a magnetometer 312, a distance sensor module 318, a first servo motor 708, a second servo motor 714, a spray gun 710, and a belt driven linear actuator 804. A user device 104 captures one or more images of the interior wall to be painted, processes and sends the one or more images to the microprocessor 304 in co-ordinates of the interior wall. The microprocessor 304 receives the co-ordinates and performs the operations of painting on the interior wall using one or more painting strokes. The user 102 may control the semi-automatic painting robot 106 with the user interface present in the user device 104.

A method comprising scanning a first painted surface of a first vehicle having two or more paint layers with a robotic terahertz radiation instrument to obtain a first painted surface thickness data and map for each of the two or more paint layers, comparing the first thickness map to a control map, and adjusting one or more paint application parameters based on a comparison of the first thickness map with the control map for painting a second surface of a second vehicle different than the first vehicle.

A liquid material application device can alleviate programming work for drawing a line. The device includes a discharge head (50) for discharging a liquid material, a worktable (25) on which a workpiece is placed, a robot (20) for moving the discharge head and the worktable relative to each other in XYZ directions, and a control unit including an arithmetic device and a storage device for storing an application program, the liquid material application device applying the liquid material to be drawn in the form of a line on the workpiece while the workpiece and the discharge head are moved relative to each other, the control unit includes a first control unit (30) for moving the workpiece and the discharge head relative to each other in accordance with the application program, and a second control unit (40) for controlling a discharge amount of the discharge head.

Apparatus and method for a painting machine are provided. The painting machine may include an end effector controlled by custom software. The painting machine may include a self-contained medium circulation system. The custom control software may be capable of coordinated n-axis manipulation of an end. Illustrative end effectors may include an inkjet head, brush, air brush or any suitable tool for applying ink, paint, color and/or texture to a surface. For example an end effector may utilize oil-based ink or ultraviolet-cured ink. Illustrative surfaces may include canvas, paper, brick, glass etc. The custom control software may control manipulation of the end effector based on a variety of electronic inputs. The custom software may manipulate different end effectors in different ways depending on the input data, type of ink/paint being used, type of surface receiving the ink/paint or any other variable.

CLEAN COPY OF THE ABSTRACT

A method to control a closed robotised system comprises a learning step and a reproduction step, wherein, during the learning step, an operator exerts a force and/or a torque (Fc) on a driving assembly, whose sensor detects an applied force and/or torque (Fext); and wherein a processing system carries out an admittance control obtaining, depending on the data detected by the sensor, indications (Xref, X*ref) of movement for the robot manipulator in the Cartesian space; the processing system, following the admittance control, delivers the indications (Xref, X*ref) of movement in the Cartesian space to a trajectory interpolation unit of the robotised system so as to generate a desired trajectory through interpolation.