Example embodiments may relate to methods and systems for selecting a grasp point on an object. In particular, a robotic manipulator may identify characteristics of a physical object within a physical environment. Based on the identified characteristics, the robotic manipulator may determine potential grasp points on the physical object corresponding to points at which a gripper attached to the robotic manipulator is operable to grip the physical object. Subsequently, the robotic manipulator may determine a motion path for the gripper to follow in order to move the physical object to a drop-off location for the physical object and then select a grasp point, from the potential grasp points, based on the determined motion path. After selecting the grasp point, the robotic manipulator may grip the physical object at the selected grasp point with the gripper and move the physical object through the determined motion path to the drop-off location.

Example embodiments may relate to methods and systems for selecting a grasp point on an object. In particular, a robotic manipulator may identify characteristics of a physical object within a physical environment. Based on the identified characteristics, the robotic manipulator may determine potential grasp points on the physical object corresponding to points at which a gripper attached to the robotic manipulator is operable to grip the physical object. Subsequently, the robotic manipulator may determine a motion path for the gripper to follow in order to move the physical object to a drop-off location for the physical object and then select a grasp point, from the potential grasp points, based on the determined motion path. After selecting the grasp point, the robotic manipulator may grip the physical object at the selected grasp point with the gripper and move the physical object through the determined motion path to the drop-off location.

A conveying system, such as a conveying system for material including non-ferrous metals, includes a conveying belt and a stabilizer. The conveying belt includes a conveying surface and is adapted to convey the material on the conveying surface. The stabilizer is configured to apply a stabilizing force onto the material on the conveyor belt such that the material is stabilized while being conveyed. A method of stabilizing material on a conveyor belt includes receiving the material on the conveying surface of the conveyor belt, conveying the material at a conveying speed with the conveyor belt, and applying the stabilizing force onto the material with a stabilizer such that vertical displacement of at least some of the material is dampened and/or minimized at the conveying speed.

Example embodiments may relate to methods and systems for selecting a grasp point on an object. In particular, a robotic manipulator may identify characteristics of a physical object within a physical environment. Based on the identified characteristics, the robotic manipulator may determine potential grasp points on the physical object corresponding to points at which a gripper attached to the robotic manipulator is operable to grip the physical object. Subsequently, the robotic manipulator may determine a motion path for the gripper to follow in order to move the physical object to a drop-off location for the physical object and then select a grasp point, from the potential grasp points, based on the determined motion path. After selecting the grasp point, the robotic manipulator may grip the physical object at the selected grasp point with the gripper and move the physical object through the determined motion path to the drop-off location.

Example embodiments may relate to methods and systems for selecting a grasp point on an object. In particular, a robotic manipulator may identify characteristics of a physical object within a physical environment. Based on the identified characteristics, the robotic manipulator may determine potential grasp points on the physical object corresponding to points at which a gripper attached to the robotic manipulator is operable to grip the physical object. Subsequently, the robotic manipulator may determine a motion path for the gripper to follow in order to move the physical object to a drop-off location for the physical object and then select a grasp point, from the potential grasp points, based on the determined motion path. After selecting the grasp point, the robotic manipulator may grip the physical object at the selected grasp point with the gripper and move the physical object through the determined motion path to the drop-off location.

A modular, scalable prescription dispensing and verification system includes a four-tiered central conveyor, dispensing control system with stored patient orders for creating dispensing and routing itineraries, carriers transporting itineraries and dispensed medications, induction station, pairs of processing stations divided by the conveyor, including automated and manual dispensing, verification, cold chain, and ambient packaging. Crossover conveyors transport carriers between dispensing station pair members for dispensing multiple products per station pair. One conveyor tier returns empty carriers to induction, another transports carriers from each dispensing station to verification, then to packaging, another transports carriers from induction to dispensing, then to additional dispensing, another conveys carriers from induction to dispensing stations. Carrier stops halt carriers at stations for removal for processing, replacement, and transport to the next station, or deposit on another tier and transport to a different station. The system may include two conveyor modules, one for refrigerated or ambient unit-of-use items, another for ambient countables.

A modular, scalable prescription dispensing and verification system includes a four-tiered central conveyor, dispensing control system with stored patient orders for creating dispensing and routing itineraries, carriers transporting itineraries and dispensed medications, induction station, pairs of processing stations divided by the conveyor, including automated and manual dispensing, verification, cold chain, and ambient packaging. Crossover conveyors transport carriers between dispensing station pair members for dispensing multiple products per station pair. One conveyor tier returns empty carriers to induction, another transports carriers from each dispensing station to verification, then to packaging, another transports carriers from induction to dispensing, then to additional dispensing, another conveys carriers from induction to dispensing stations. Carrier stops halt carriers at stations for removal for processing, replacement, and transport to the next station, or deposit on another tier and transport to a different station. The system may include two conveyor modules, one for refrigerated or ambient unit-of-use items, another for ambient countables.

System (1) for sorting products, comprising: a conveyor (11) comprising carrying bodies (113) one after another, extending parallel to each other, the carrying bodies associated with a pusher body (114), an electric motor (117) for moving the pusher body along the carrying body in a sort direction, a central control server (12) arranged for transmitting destination data relating to a sorting locationa plurality of controllers (13), in communication with the central control server and moveable in the transport direction, each to control two or more electrical motors in accordance with destination data received from the central control server, a stationary Access Point, AP (14), communicating with the server, anda pair of stationary radiating cables (15, 16) connected to the AP, one radiating cable extending in the transport direction and the other radiating cable extending against the transport direction, the radiating cables arranged for communication with the controllers.

A parcel transfer system transfers a parcel or a similar article directly between a conveyor and a self-driving vehicle (SDV) while the conveyor and SDV are moving. The conveyor, SDV, or both may be configured to initially transport a parcel in a first direction of travel and then subsequently offload the parcel in a second direction of travel. The SDV is configured to travel alongside of the conveyor in the first direction of travel and either receive the parcel as it is offloaded from the conveyor or offload the parcel onto the conveyor in the second direction of travel. The parcel transfer system further includes a vision and control subsystem, which regulates movement of the SDV and offloading of the parcel from the conveyor or SDV.

A parcel transfer system transfers a parcel or a similar article directly between a conveyor and a self-driving vehicle (SDV) while the conveyor and SDV are moving. The conveyor, SDV, or both may be configured to initially transport a parcel in a first direction of travel and then subsequently offload the parcel in a second direction of travel. The SDV is configured to travel alongside of the conveyor in the first direction of travel and either receive the parcel as it is offloaded from the conveyor or offload the parcel onto the conveyor in the second direction of travel. The parcel transfer system further includes a vision and control subsystem, which regulates movement of the SDV and offloading of the parcel from the conveyor or SDV.