KR 10 R1100-2 (AGILUS)

Maximum mass the robot can carry at the wrist flange, including the gripper/tool. Higher means it can handle heavier parts.

Maximum horizontal distance from the base axis to the wrist — defines the size of the work area. Higher means a larger envelope.

How close the robot returns to the same taught point on repeated tries (ISO 9283, ±). Lower is better — tighter precision.

Number of independently driven joints / degrees of freedom. 6 is standard for articulated arms; 4 for SCARA/palletizers; 7 adds elbow redundancy.

Mass of the manipulator (arm) without controller. Lighter eases mounting and mobile use; heavier often means stiffer/higher payload.

Orientations the robot can be installed in (floor, ceiling/inverted, wall, tilted, mobile base).

The control cabinet / unit that runs the robot.

Ingress protection of the body against dust/water (IEC 60529). First digit = dust, second = water. Higher resists harsher environments.

Ingress protection at the wrist, often higher than the body for wet/washdown duty.

Whether the robot is designed to work safely next to people without fencing (power-and-force-limited).

Certified safety standards (ISO 10218-1, ISO/TS 15066) and functional-safety level (PLd/PLe, SIL2/3).

How the robot is taught: pendant, hand-guiding (lead-through), block/flow-chart, scripting, offline simulation.

Native robot programming language(s) — e.g. KRL (KUKA), RAPID (ABB), URScript (UR), INFORM (Yaskawa).

Robot Operating System driver availability (none / ROS 1 / ROS 2 / both).

The handheld programming/jog device supplied.

Whether programs can be built and validated offline in a digital twin before deployment.

Industrial networks supported for PLC/cell integration (PROFINET, EtherNet/IP, EtherCAT, Modbus TCP, CC-Link, etc.).

Mechanical interface at the wrist for mounting tools (ISO 9409-1 pattern).