A control device controlling a robot including a robot arm, a drive section causing the robot arm to pivot around a pivot axis, a shaft that is provided at a position of the robot arm different from the pivot axis and that moves parallel to the pivot axis, and an angular velocity sensor that is provided in the robot arm and that detects angular velocity around an axis orthogonal to an axial direction of the pivot axis and parallel to a plane including the pivot axis and an axis of the shaft, the control device includes a processor that is configured to control the robot, wherein the processor is configured to perform feedback control on the drive section based on the angular velocity.

A robot is provided. The robot includes an arm configured to turn around a turning axis and a cover including a first member having first rigidity and a second member having second rigidity higher than the first rigidity, the cover being provided on the arm, the second member being located in a position closer to the turning axis than the outermost periphery of the first member in a plan view from a direction of the turning axis.

A teaching method is for teaching a position and attitude of a robot arm to a robot configured to switch between a first state where the third axis is located at one side of a first imaginary line and a second state where the third axis is located at the other side of the first imaginary line, the first imaginary line being set as a straight line passing through a first axis and a second axis when the robot arm is viewed from a direction along the first axis. The method includes performing a switching operation of switching between the first state and the second state according to a result of detection by a force detection unit.

An apparatus for cutting containers. The apparatus includes an ultrasonic cutting blade that has a flat cutting edge of a cutting length; a container positioner that secures a container in a position relative to the ultrasonic cutting blade so that the flat cutting edge of the ultrasonic cutting blade may be positioned to be in contact with a flat surface of the container; a press actuator that causes the flat surface of the container and the flat cutting edge of the ultrasonic cutting blade to press against each other; and a control system that operates the ultrasonic cutting blade and the press actuator to cause the ultrasonic cutting blade to vibrate ultrasonically while the container and the flat cutting edge of the ultrasonic cutting blade press against each other until the ultrasonic cutting blade penetrates the flat surface of the container by a predefined depth.

A horizontal articulated robot includes a support unit, a movable unit provided in the support unit, from which an end effector is detachable, and a control unit that controls the movable unit, wherein the control unit is provided in the support unit and the end effector is connected to the control unit.

A multiaxial robot includes a first rotation module, a second rotation module, and a connecting member. The first rotation module includes a base and a plurality of arms. The arms are configured to rotate parallel to a first plane relative to the base. The second rotation module includes at least one wrist. The wrist is connected to the farthest arm arranged from the base in the first rotation module and configured to rotate parallel to a second plane relative to the first rotation module. The connecting member is pivotally connected to the base and connected to an adjacent one of the arms, or is connected between adjacent two of the arms and the wrist.

A vacuum operated object lifting system is disclosed that can use air pressure differentials to anchor the lifting system to the floor or other structure. The vacuum lifting system includes a main structure having a space defined in the bottom thereof and a lifting arm system extending from the main structure for grasping and moving a load. The vacuum lifting system includes a vacuum pumping system including an air pump and a conduit system extending from the air pump to the space in the bottom of the main structure. Use of the air pump to draw air out of the conduit system creates pressure differential between ambient air pressure and air pressure in the space of the main structure to anchor the vacuum lifting system to the ground. The vacuum pumping system may also grasp the load by suction.

A control method executes a first step of actuating a brake to decelerate a robot arm, a second step of releasing or relaxing the actuation of the brake when one of Conditions A1, A2, and A3 is satisfied after deceleration of the robot arm, and a third step of actuating the brake again to restrict driving of the robot arm when one of Conditions B1, B2, and B3 is satisfied after release or relaxation of the brake, Condition A1: a velocity of the robot arm becomes a predetermined value or less; Condition A2: a contact state between the robot arm and the object becomes stable; Condition A3: time TA elapses; Condition B1: time TB elapses; Condition B2: a movement amount of the robot arm becomes a predetermined value or more; and Condition B3: the contact state between the object and the robot arm is released or relaxed.

An apparatus includes a spindle platform; a traversing platform configured to move in a first direction; a lift system connected to the spindle platform and the traversing platform, the lift system configured to move the spindle platform in a second direction perpendicular to the first direction; a movable arm connected to the spindle platform, the movable arm including a first link connected to the spindle platform, a second link connected to the first link, and a third link connected to the second link, and a first actuator connected to the spindle platform and configured to cause a rotation of the first link, and a second actuator in the movable arm and configured to cause a rotation of the second link. The first actuator extends from the spindle platform into the first link to occupy a combined thickness of the spindle platform and the first link.

A coating system includes coating robots configured to coat a vehicle, and an operation robot. The operation robot includes a first arm configured to turn around a first axis; a second arm configured to turn around a second axis parallel to the first axis; a third arm configured to turn around a third axis parallel to the first axis; a fourth arm configured to turn around a fourth axis perpendicular to the first axis; a fifth arm configured to turn around a fifth axis parallel to the fourth axis; and a tip jig is supported at the fifth arm and is configured to turn around a sixth axis. The sixth axis is selectively parallel to the fifth axis or perpendicular to a plane which includes the fourth axis and the fifth axis.