Abstract: An industrial robot with parallel kinematics is proposed which is equipped with a robot base (1), a carrier element (2) for receiving a gripper, a tool or a machine element, at least two moveable actuating units (4), one of which ends is connected to actuating-unit drives (6) arranged on the robot base (1) and the other end is moveably connected to the carrier element (2), a telescope (13) that is moveably arranged between the robot base (1) and the carrier element (2), a first joint (17) with multiple degrees of freedom, by means of which joint the telescope (13) is moveably held on the robot base (1), a second joint (23) with multiple degrees of freedom, by means of which joint the telescope (13) is moveably held on the carrier element (2), whereby the position of the first joint (17) can be displaceably arranged relative to the robot base (1).

Abstract: A microfluidic analysis device and manufacturing method are provided. The device includes a capillary substrate, a cover substrate adjacent to a cover side of the capillary substrate and/or a bottom substrate adjacent to a bottom side of the capillary substrate, a capillary structure with at least one capillary in the interior of the capillary substrate and/or at the interface of the capillary substrate with the cover substrate and/or with the bottom substrate, and a fluid-conducting arrangement for conducting a fluid through the capillary structure. The arrangement may be designed for compartmenting the fluid using controlled pressure pulses. A linear sensor element extends toward and/or away from and/or along the capillary, a fluid contact end of which and at least an adjacent part of its feed lie in the plane of the capillary, and may be integrated in the device.

Abstract: A torque sensor (10), in particular for detecting torques occurring on or in a joint of an articulated-arm robot. The sensor has several measuring spokes (1, 2, 3, 4) that are designed to deform under the effects of torque; and several strain gauges (DR11, DR12, DR21, DR22, DR31, DR32, DR41, DR42), with two strain gauges being arranged on two opposite sides of the several measuring spokes (1, 2, 3, 4). The several strain gauges are each connected in one of at least two bridge circuits (A, B). The at least two bridge circuits (A, B) are each configured to generate a bridge voltage (Ua, Ub). By detecting and comparing differences in the bridge voltage signals (Ua, Ub) generated by the at least two bridge circuits (A, B); a reliability of the detected bridge voltage signals is determined.

Abstract: A method is provided for operating a robotic device having a kinematic chain of movable components. The method includes: detecting respective values at least one characteristic of a plurality of the movable components by sensors arranged on the kinematic chain or in the vicinity of the kinematic chain; ascertaining a maximum value based on the detected values; comparing the ascertained maximum value with a predefined first safety limit by a controller of the robotic device; and adjusting the at least one characteristic or a further characteristic of the kinematic chain when the ascertained maximum value has a predefined relationship with the first safety limit, in order to increase the operating safety of the robotic device.

Abstract: The invention relates to a method for programming a robot, in particular a robot comprising a robotic arm, in which method a movement to be performed by the robot is set up preferably in a robot programme by means of a predefined motion template, the motion template is selected from a database comprising a plurality of motion templates, the motion template comprises one or more execution modules that can be parameterized and at least one learning module, the one or more execution modules are used for planning and/or performing the robot movement or part of the robot movement, the leaning module records one or more configurations of the robot during an initialization process, in particular in the form of a teaching process, and the learning module calculates parameters for the one or more execution modules on the basis of the recorded configurations, preferably using an automatic learning process. Also disclosed is a corresponding system for programming a robot.

Abstract: A method for controlling a manipulator, with the method being particularly suitable for the respecting of predetermined monitoring limits. The method operates by initiating a halting movement or a speed capping based on an identified actual override trend, and is thus suitable, in particular, for path movements by means of spline interpolation.

Abstract: A traffic monitoring system is provided. The traffic monitoring system comprises: a camera system configured to capture images of vehicles, the camera system comprising a first wireless time receiver configured to receive a wirelessly transmitted time signal; and a light system configured to selectively illuminate the vehicles, the light system being spaced apart from the camera system, wherein the light system comprises a second wireless time receiver configured to receive the wirelessly transmitted time signal such that the image capture by the camera system and the illumination by the light system is synchronized.

Abstract: A method for operating a traffic monitoring device. A sensor signal is provided by a sensor device of the traffic monitoring device is first of all read in. An item of information is then generated using the sensor signal. Finally, the information is output to an interface to at least one vehicle.

Abstract: A manipulator system includes at least one manipulator and a control device assigned to the manipulator; and at least one mobile operating device for controlling the at least one manipulator. In addition, an electronic display device is provided, which is arranged to display at least one optically readable identifier, and at least one optical reading device, which is provided and arranged to detect the displayed optically readable identifier. The manipulator system is arranged to release control of the manipulator by means of the mobile operating device when the optically readable identifier has been correctly detected by the optical reading device.

Abstract: A handheld robot operation unit includes a housing having a handle-like grip section, a basic safety control device arranged in the housing, and at least one holder connected to the housing and configured for manually detachably coupling the housing to a device that is different from the handheld robot operation unit and which electronically communicates with the basic safety device. The holder includes a first holding arm for mechanically connecting the handheld robot operation unit to a first edge section of the device, with an opposite edge section of the device being free. A second holding arm is configured to mechanically connect the handheld robot operation unit to a second edge section of the device, adjacent the first edge section and forming a corner section of the device, with an edge section of the device opposite the second edge section being free. A corresponding method is disclosed.

Abstract: A method for actuating a manipulator system by means of a portable end device, a corresponding portable end device, and a robot system. The portable end device includes a 3-D camera that is a plenoptic camera. A three-dimensional image is acquired by means of the 3-D camera of the portable end device of at least part the manipulator system to be actuated. The image identifies at least one actuatable object in the manipulator system. A task is selected for the identified object to actuate. By selecting the identified actuatable object, the object is actuated to perform the task.

Abstract: A method for verifying the assignment of a drive to a control device of an industrial robot. A drive, comprising at least one actuator and a motion sensor, is assigned to one of the axles of the robot. The assignment is verified by outputting a suitable test signal from the control device to the drive, and comparing the output test signal with motion signals generated by the motion sensor.

Abstract: A method for controlling a manipulator system including a manipulator, several drives and a mobile platform A first converter for actuating at least two of the several drives is associated with the manipulator system. The method includes the steps of: a) identifying one of the drives of the manipulator system that is associated with the first converter and that must be used to travel over a current planned movement path of the manipulator system, and (b) actuating the one identified associated drive by means of the first converter, where the actuated drive is used for the manipulator system to travel over the planned movement path. One of the at least two drives that is not being actuated is stationary preferably fixed or secured by a mechanical brake.

Abstract: A method for moving along a predetermined path with a robot in an at least a partially automated manner includes determining a deployment position on a current path section of the predetermined path for which a distance parameter satisfies a predetermined condition, and moving to the deployment position with the robot. In one aspect, the robot may be moved to the deployment position if a deployment condition is satisfied. The distance parameter may be determined on the basis of a distance of a current position of the robot relative to the current path section. The predetermined condition may be that the distance parameter has a value that is less than or equal to the values of the distance parameter of all positions in a partial area of the current path section, which is in particular complementary to the deployment position.

Abstract: The invention relates to a method and a system for controlling a robot, which non-simultaneously shares a working space with another robot. On the basis of a determined residual period, in which the working space remains occupied, the path planning of a robot is adjusted in a cycle time-optimized manner, in order to avoid a deceleration at the working space limit and a wait for the working space to be vacated.

Abstract: A method for identifying a manipulator by means of a portable terminal device, wherein the portable terminal device comprises a 3D camera. The method operates to detect a three-dimensional image of at least one part of the manipulator to be identified by means of the 3D camera of the portable terminal device. An actual status of the manipulator is determined based on the three-dimensional image detected. The 3D camera is a plenoptic camera, and the detected three-dimensional image comprises a four-dimensional light field of at least one part of the manipulator to be identified.

Abstract: A cable guide device for guiding at least one supply cable along a robot arm includes a supply cable and a spring system configured to automatically return the supply cable from an extracted state into a retracted state. The device, has a front end section in the direction of extraction of the supply cable, and a rear end section in the direction of extraction of the supply cable. The device further includes a spring system seat permanently connected to the supply cable and on which the rear end section of the spring system is mounted, an abutment seat on which the front end section of the spring system is mounted, a fastening device configured to fasten the cable guide device to a link of the robot arm, and an adjustment device carrying the abutment seat and configured to mount the abutment seat for movement with respect to the fastening device.

Abstract: A device for the cleaning of pipes, such as household waste and sewer pipes is proposed, the device includes a nozzle movable in at least three axes within a pipe for providing a jet of cleaning fluid directed to soilage in pipes; a cleaning hose for supply of cleaning fluid is connected to the nozzle and a swivel mechanism for deflecting the nozzle at an angle relative to a longitudinal axis, a front end portion of the hose is bent in a bending direction in a bending plane; at least one drive for deflecting the nozzle around the longitudinal axis by changing the direction of bending and the bending plane without torsion to the cleaning hose.