Methods and systems for spreading out and folding a suspended laundry article are described. A robotic system for spreading out and folding a laundry article includes at least three lifters disposed about a perimeter of a surface, two or more sensors disposed at fixed locations about the surface, and a controller in operative communication with the two or more sensors and the at least lifters. The controller is configured to receive output signals from the two or more sensors, determine whether the laundry article suspended by at least two lifters of the at least three lifters is spread out, and instruct, based on a determination of the laundry article being spread out, one or more of the at least three lifters to fold the spread out laundry article one or more times.

A robotic attacher includes a main arm that is suspended vertically from a rail, and a supplemental arm that is coupled to and extends horizontally from the main arm along a longitudinal axis. The supplemental arm includes a pivot assembly that pivots a gripping portion around a vertical axis that is substantially parallel to the main arm of the robotic attacher, in a direction transverse to the longitudinal direction of the supplemental arm, and between at least a maximum-left position, a maximum-right position, and a centered position. The pivot assembly includes a first actuator that extends and retracts a first cable coupled to a left side of the gripping portion in order to pivot the gripping portion. The pivot assembly further includes a second actuator that extends and retracts a second cable coupled to a right side of the gripping portion in order to pivot the gripping portion.

A robotic imaging system includes a camera configured to obtain one or more images of a target site. A robotic arm is operatively connected to the camera, the robotic arm being adapted to selectively move the camera in a movement sequence. A force-based sensor is configured to detect and transmit sensor data related to at least one of force and/or torque imparted by a user for moving the camera. The system includes a controller configured to receive the sensor data. The controller has a processor and tangible, non-transitory memory on which instructions are recorded. The controller is adapted to selectively execute a collision avoidance mode, including applying a respective correction force to modify the movement sequence when the camera and/or the robotic arm enter a predefined buffer zone.

Systems for autonomously batching a plurality of separated laundry articles into sorted loads for washing and drying are described. For example, each one of a plurality of collection bins is configured to receive a sorted load of separated articles including at least one common one of one or more washing and drying characteristics. A plurality of conveyors are configured to receive thereon the bins and position one bin into a loading position adjacent to an exit orifice of a sorting surface. At least one sensor disposed at least one of on, adjacent to, and within the surface is configured to detect the washing and drying characteristics. A controller in operable communication with a drive of the plurality of conveyors and the at least one sensor is configured to instruct the conveyors to move the bins to batch each separated laundry article into a bin matching the washing and drying characteristics.

The present invention relates to a device for moving piece goods from a supply device to a receiving device, comprising: A supply device, such as a conveyor belt, for delivering piece goods; A receiving device, such as a tray, for receiving piece goods;
wherein The supply device and the receiving device are essentially in the same plane; A suspension point located above the plane, relative to which a first part of a: telescopic arm is suspended at a first location thereof so as to be rotatable about two axes of rotation, which axes of rotation each extend substantially parallel to the plane and at a, preferably straight, angle to each other, so that a second location, located at a distance towards the plane of the first location, formed by an end of the first part of the telescopic arm: is movable relative to the plane with a directional component in two mutually perpendicular directions parallel to the plane; and where the telescopic arm comprises a second part, which is telescopically movable relative to the first part in a direction from the first location to the second location, thus with a directional component from the suspension point to and from the plane, which second part is provided on a side facing the plane with an engaging means for engaging at least one of the piece goods.

The invention further relates to an assembly of devices of the aforementioned type, as well as to a method for operating these devices.

A robotic imaging system includes a camera configured to obtain one or more images of a target site. A robotic arm is operatively connected to the camera, the robotic arm being adapted to selectively move the camera in a movement sequence. A force-based sensor is configured to detect and transmit sensor data related to at least one of force and/or torque imparted by a user for moving the camera. The system includes a controller configured to receive the sensor data. The controller has a processor and tangible, non-transitory memory on which instructions are recorded. The controller is adapted to selectively execute a collision avoidance mode, including applying a respective correction force to modify the movement sequence when the camera and/or the robotic arm enter a predefined buffer zone.