Devices, systems, and methods for automatically exchanging a first end-effector on a robot arm with a second end-effector housed in a docking station. The first end-effector has a clamp that either engages or disengages the robot arm based upon an application of force of the robot arm onto the end-effector. The clamp has a spring loaded clip that disengages the first end-effector to allow the robot arm to move away from the released first end-effector. The robot arm is configured to automatically move to a port of a docking station housing the desired second end-effector using magnetic coils on the robot arm and the docking station to guide the robot arm.

A system for dismantling a pallet includes a feed system configured to convey the pallet along a direction of travel. The feed system has a measuring station and a staging area. The measuring station is configured to obtain dimensions of the pallet. A saw is configured to dismantle the pallet. A manipulator includes a robotic arm. The manipulator is configured to move the pallet from the staging area to the saw for dismantling.

An autonomous floor cleaning robot includes a transport drive and control system arranged for autonomous movement of the robot over a floor for performing cleaning operations. The robot chassis carries a first cleaning zone comprising cleaning elements arranged to suction loose particulates up from the cleaning surface and a second cleaning zone comprising cleaning elements arranged to apply a cleaning fluid onto the surface and to thereafter collect the cleaning fluid up from the surface after it has been used to clean the surface. The robot chassis carries a supply of cleaning fluid and a waste container for storing waste materials collected up from the cleaning surface.

An end effector system is disclosed for a robotic system that includes a primary acquisition system that includes a primary end effector, and a secondary retention system that substantially surrounds at least a portion of the primary acquisition system, wherein at least a portion of the primary acquisition system may be drawn up within at least a portion of the secondary retention system such that the primary end effector system may be used to select an object from a plurality of objects, and the secondary retention system may be used to secure the object for rapid transport to an output destination.

An end effector system is disclosed for a robotic system that includes a primary acquisition system that includes a primary end effector, and a secondary retention system that substantially surrounds at least a portion of the primary acquisition system, wherein at least a portion of the primary acquisition system may be drawn up within at least a portion of the secondary retention system such that the primary end effector system may be used to select an object from a plurality of objects, and the secondary retention system may be used to secure the object for rapid transport to an output destination.

A multiple suction cup apparatus for lifting an object includes the capability of exchanging a large and small suction cup. At least one interlock enables the large or small suction cup to be deployed. The interlocks include passive interlocks, such as ball detents and conventional magnets, and active interlocks, such as a twist lock and electronic actuated magnets.

An apparatus and method for transferring a pattern from a universal surface to an ultimate package. The apparatus comprises an end effector for a pattern transfer robot. The end effector comprises a crowder plate with crowder plate slats spaced apart a distance to form openings between the crowder plate slats. The universal surface comprises a finger wall with finger wall slats spaced apart a distance to form openings between the finger wall slats. A portion of the crowder plate slats are sized to pass between a portion of mating finger wall slats.

A programmable motion system is disclosed that includes a dynamic end effector system. The dynamic end effector system includes an end effector that is coupled via a dynamic coupling to the programmable motion system, wherein the dynamic coupling provides that at least a portion of the end effector may spin with respect to an other portion of the end effector.

Provided are systems and apparatuses for manufacturing aircraft support structures. An example robotic end effector comprises a rotatable reel with a flat strip of material wound around the reel. The end effector further includes a forming shoe including a forming surface contacting the strip of material. A first end of the forming surface corresponds to a start shape and a second end of the forming surface corresponds to an end shape. As the strip of material passes from the first end of the forming surface to the second end of the forming surface, the strip of material transitions from the first shape to the end shape and is deposited as a formed stringer ply onto an application surface. The forming shoe may further include a vacuum system to suction air through a plurality of ports along the forming surface to urge the strip of material against the forming surface.

Provided are systems and apparatuses for manufacturing aircraft support structures. An example robotic end effector comprises a rotatable reel with a flat strip of material wound around the reel. The end effector further includes a forming shoe including a forming surface contacting the strip of material. A first end of the forming surface corresponds to a start shape and a second end of the forming surface corresponds to an end shape. As the strip of material passes from the first end of the forming surface to the second end of the forming surface, the strip of material transitions from the first shape to the end shape and is deposited as a formed stringer ply onto an application surface. The forming shoe may further include a vacuum system to suction air through a plurality of ports along the forming surface to urge the strip of material against the forming surface.