The robot controller includes: a memory configured to store a first value representing a position of a first movable member detected by a first position detector when a first tool including the first movable member and the first position detector is detached from a robot or when the first movable member moves to a predetermined position; and a processor configured to execute a predetermined process in accordance with a difference between the first value stored in the memory and a second value representing a position of a second movable member detected by a second position detector when a second tool including the second movable member and the second position detector is attached to the robot or when the second movable member moves to the predetermined position after the second tool is attached to the robot.

Apparatus and methods for adaptively retooling robots include programmable adapters for detachably connecting at least one robotic peripheral to a robot, providing peripheral information associated with the robotic peripheral, and causing the robot to adaptively reconfigure based on the peripheral information.

An abnormality determination apparatus of the present invention acquires state data from work equipment provided with an attaching part to which a plural kinds of work parts are attached in a replaceable manner, identifies the kind of a work part attached to the attaching part, sets, corresponding to the identified kind of the work part, abnormality determination data for determining an abnormality of the work equipment, acquires, from among state data acquired from the work equipment, state data of a time when the identified kind of the work part was being attached, and compares the acquired state data with the set abnormality determination data to determine an abnormality of the work equipment.

Apparatus and methods for adaptively retooling robots include programmable adapters for detachably connecting at least one robotic peripheral to a robot, providing peripheral information associated with the robotic peripheral, and causing the robot to adaptively reconfigure based on the peripheral information.

Systems and methods for a universal connection interface between a robot and a plurality of modular attachments are disclosed. Also disclosed are autonomous robotic system and devices comprising a control module in operative connection to a drive module and at least one task module, the drive module configured to move the system through a space as instructed by the control module, the at least one task module configured to perform a task or set of tasks as instructed by the control module. The robotic device also includes a data receiving unit. A command is given by the user to the robotic device to perform a function, and the device then transmits the data to the accessory task module through the data receiving unit. In one exemplary implementation, a robot may be assigned a plurality of different tasks to be accomplished by connecting to a plurality of different modular attachments to using a single universal connection interface. The robotic system and/or device can perform multiple cleaning or yard maintenance tasks.

A robot quick-release assembly has a first joint member and a robot component mounted thereon, the first joint member has a first coupler and a second joint member, a robot arm mounted thereon has a second coupler, a clamp, and a locking collar. The first coupler can be coaxially aligned with the second coupler and pressed into the second joint member, and detachably connected to the second joint member. The first mechanical coupler is detachably connected to the second mechanical coupler for transferring power across the quick-release assembly. The robot component can receive an additional electrical connector, the additional electrical connector supplying power to the robot component. The quick-release assembly coupling assembly further exerts large forces with the application of a relatively small torque to the locking collar by applying a two stage wedge engagement and can further include a sequencing system.

In embodiments, a subsea manipulator tool changer comprises an ROV attachable standardized tool receiver and a tool, the subsea manipulator tool changer comprising a standardized tool latch and a standardized tool latch receiver whereby tools can be attached and detached subsea. In other embodiments, a system for changing tools while subsea comprises an ROV, a subsea manipulator tool changer, and a tool caddy configured to accept and release a tool where the tool comprises the standardized tool latch receiver.

To reduce the working hours of a user in an operation and improve an operation rate in an industrial network system. A communication setting change part is provided which automatically changes, in a timing of an end effector replacement, the communication setting in a communication part according to the communication information that corresponds to an end effector.

Provided are a tool exchange device and a tool exchange system that enable management of a coupling state according to a tool to be fixed. A tool exchange device including a male member to be detachably attached to an apparatus side and a female member to be detachably attached to a tool side includes: a proximity sensor provided in the male member; and a target provided in the female member, the target corresponding to the proximity sensor, and the target is provided in the female member in such a manner that a distance between the target and the proximity sensor in a state in which the male member and the female member are coupled together is adjustable.

A robot quick-release assembly has a first joint member and a robot component mounted thereon, the first joint member has a first coupler and a second joint member, a robot arm mounted thereon, has a second coupler, a clamp, and a locking collar. The first coupler can be coaxially aligned with the second coupler and pressed into the second joint member, and detachably connected to the second joint member. The first mechanical coupler is detachably connected to the second mechanical coupler for transferring power across the quick-release assembly. The robot component can receive an additional electrical connector, the additional electrical connector supplying power to the robot component. The quick-release assembly coupling assembly further exerts large forces with the application of a relatively small torque to the locking collar by applying a two stage wedge engagement and can further include a sequencing system.