A safety monitoring system (1) is provided with: a second sensor (30) for monitoring a second area; a first sensor (20) for monitoring a first area; a first processing unit (100) for detecting an approach of a human (6) to the second area; a second processing unit (200) for detecting an entry of the human into a dangerous area; and a mode determination unit (300). The mode determination unit determines a first mode when an approach of the human to the second area is not detected, and a second mode when an approach of the human to the second area is detected, and the operation differs between the first mode and the second mode.

Provided is a method for detecting an imminent collision between an object and a component of an autonomous system in the real environment including at least one real, decentralized autonomous component, whereby of at least a part of the autonomous system a virtual image is available, emulating at least one aspect of the autonomous system.

A robot control method includes, storing, in a memory, shape information about a robot including a tool attached to a tip and about a peripheral object located on a periphery of the robot. A teaching program also is stored in the memory. The teaching program includes a setting speed when operating the robot. By a processor connected to the memory, a distance between the robot and the peripheral object, based on the shape information, is calculated at each operation position when operating the robot according to the teaching program. By the processor, it is determined whether or not the calculated distance is changing in a decreasing direction. In response to determining that the calculated distance is changing in the decreasing direction, by the processor, the robot is operated at a speed lower than the setting speed in the teaching program.

A system having a sensor system comprising distance sensors for monitoring a hazardous zone at a movable machine part having at least one protected zone, wherein a tool is arranged at the movable machine part, wherein the distance sensors are arranged at a holder at the movable machine part, wherein a plurality of distance sensors are arranged, with the detection beams of the distance sensors forming a protected field shell, wherein the holder has the distance sensors, with the holder having a disk-shaped housing, with the disk-shaped housing having round surfaces and not having any corners at the outer surfaces, with the system comprising a fastening system, the fastening system comprises one of a first fastening adapter and a second fastening adapter at which the holder is respectively arranged for fastening the holder to the movable machine part.

A robot system is provided that includes movable parts, one or more object detecting sensors, and one or more processors, wherein the one or more object detecting sensors is dispose at or near the elbow, the wrist, or the position between the elbow and the wrist of the robot. Multiple embodiments are introduced for the implementation of the object detection of the robot system.

A safety system for use in robotics includes a plurality sensors, preferably a heterogeneous set of commercial off the shelf sensors, and at least one processor that assesses an operational state of the sensors, validates a system status based on the assessed operational states of the sensors to determine whether sufficient sensors are operable to provide a safety certified system, and monitors an operational environment for violations of safety rules that specify rules regarding proximity of humans to robots. A control system for use in robotics includes at least one processor that performs motion planning taking into account safety monitor rules implemented by the safety system to thereby reduce triggering of stoppages, slowdowns or precautionary occlusions by the safety system.

An accident monitoring system based on UWB-based real-time positioning comprises a UWB tag, a plurality of UWB anchors installed around a processing line and receiving the worker's position from the UWB tag and sensing predetermined information for the processing line, an AP receiving the worker's position and the predetermined information for from the plurality of UWB anchors, a server receiving the worker's position and the predetermined information for from the AP, storing the worker's position and the predetermined information for, and determining whether the worker is in a preset access-limited area, and a programmable logic control (PLC) box, upon receiving proximity information indicating that the worker is the access-limited area from the server through the AP, controlling to stop the industrial robot, the conveyor belt, and the motor in the processing line.

In the field of robot technologies, a robot control method and apparatus are for protecting safety of a human during interaction between the human and a robot. The method includes: detecting a current location of the human; determining at least two regions surrounding the human according to the detected current location; and controlling movement of the robot in any region of the at least two regions, to protect safety of the human during interaction with the robot. Because the region is set surrounding the human, movement of the human does not affect the interaction between the human and the robot. In addition, using a protected object as a target, the robot is controlled to move in regions that surround the human. Compared with a case in which the robot is limited in fixed space, no matter how the human moves, safety of the human may be effectively protected.

A vehicle assembly system includes a vehicle chassis of a vehicle; at least one object sensor mounted to the vehicle chassis, where the at least one object sensor generates sensor data based on at least one detected object; a vehicle controller mounted to the vehicle chassis and configured to receive the sensor data from the at least one object sensor, where, during assembly, the vehicle controller is configured with production control software that enables the vehicle controller to generate production object data from the sensor data, monitor for a safety event based on the production object data, and generate a safety event signal in response to detecting the safety event; and a safety controller configured to receive the safety event signal from the vehicle controller and alter a movement of a surveilled machine corresponding to the safety event.

Various embodiments for enforcing safe operation of machinery performing an activity in a three-dimensional (3D) workspace includes computationally generating a 3D spatial representation of the workspace; computationally mapping 3D regions of the workspace corresponding to space occupied by the machinery and a human; and based thereon, restricting operation of the machinery in accordance with a safety protocol during physical performance of the activity. Limited-access zones are defined within which the presence of a human will not affect operation of the machinery.