A smart locker automated transfer system includes one or more lockers, a transfer system, and an autonomous delivery robot. Each locker includes a retractable base plate configured to hold the package. The transfer system may include a rack and rail system, one or more conveyor belts, or both. The autonomous delivery robot may be configured to receive the package from the transfer system. The autonomous delivery robot may be configured to deliver the package to a destination.

A method and to a device for handling hygiene products, in particular nappies, wherein the products are transported by a feed conveyor in a first transport direction into compartments of a removal conveyor, in particular a grouping conveyor, which transports the products in a second transport direction, wherein the second transport direction extends transversely, in particular perpendicularly, to the first transport direction. At least one intermediate conveyor which serves to reduce the transport speed of the products in the first transport direction is located between the feed conveyor and the removal conveyor.

Various embodiments are directed to a conveyor apparatus comprising: a conveyor frame embodying a structural support for a conveyor surface defining a conveyor length that extends in a length direction and comprises: a first sidewall comprising a first guide track extending along a first inner surface thereof in the length direction, and a second sidewall comprising a second guide track extending along a second inner surface thereof in the length direction; a plurality of bottom panels, each extending between the first sidewall and the second sidewall, wherein a first bottom panel of the plurality of bottom panels is engaged with the first guide track of the first sidewall and the second guide track of the second sidewall such that the first bottom panel is configured to be selectively moveable throughout a range of motion defined at least in part by the first guide track and the second guide track.

A belt curve adapted to convey an object along a curved conveying direction between a first end and a second end, wherein the conveying direction is perpendicular to a radial direction;

the belt curve comprising: a supporting frame; a conveying belt, which is arranged circumferentially on the support frame and adapted to carry the object; at least one deflection roller located at each of the first end and the second end, the conveying belt is deflected around the deflection roller; a drive adapted to provide a drive power for the conveying belt; a guiding, in particular a guide rail, adapted to guide the conveying belt in the conveying direction, thereby providing a guiding force in radial outward direction, a tensioner adapted for selective amendment of the radial guiding force to the conveying belt.

A flexible thermoplastic conveyor belt constructed of one or more belt segments having corrugated sidewalls. The one or more segments are joined end to end at one or more joints. The ends of the sidewalls at or near the joints are fastened together by fasteners to form a continuous sidewall along the length of the belt. The fasteners are toolless fasteners requiring no tools; they can be fastened and unfastened by hand alone.

A smart moving platform for transport of components in manufacturing includes a vehicle body, a transmission device, a conveying system, a detection device, a tag installation device, a control unit, and a tag reader. The conveying system conveys components. The detection device detects a location of the component and in a first predetermined area, the tag installation device installs and activates a tag on the component. The control unit writes component information to the activated tag and sets a predetermined period. The tag starts to count time elapsing, and the conveyor belt conveys the component to a second predetermined area. The tag reader reads the component information, the elapsed time, and a predetermined period of the tag. When the elapsed time matches the predetermined period, the conveying system sends the component to a third predetermined area.

There is discussed a method of picking and placing bulbs, in which bulbs are supplied on a supply surface of a bulbs supply system; the bulbs being identified and picked from the supply surface with a pick-and-place head; wherein picked bulbs are transferred from the pick-and-place head, shoot-first and roots-last to a transfer-receptacle comprising at least one bulb-receptor, wherein the bulb-receptor temporarily clutches said bulb.

An apparatus for unscrambling articles includes a transport system for transporting randomly-arranged articles on a transport plane and a system for extracting articles arranged with a predefined orientation and/or position. Devices for picking and releasing the articles are configured to pick up the articles randomly arranged on the transport system and release them to an extraction system with a predefined orientation and/or position. A detection system is designed to detect position and arrangement of the articles in transit and to provide information for controlling gripping and release devices, while a unit for processing and controlling components and drives of the apparatus is designed to receive the position and/or arrangement information of the articles and to control the gripping and release devices. The pick and release devices include a robot for picking up articles only from the first section, and a robot for picking up articles only from the second section.

A compliance mechanism for a pick and place robotic system comprising: a motion device, an end effector coupled to the motion device, wherein the end effector comprises a sheath structure, a rod, wherein the compliance mechanism is configured to: when the distal end of the rod is in not contact with an object, causing the distal end of the rod to move responsive to movement of the motion device, and when the distal end of the rod is in contact with an object and the motion device moves toward the object, causing the distal end of the rod to remain stationary by causing the sheath structure to move along a longitudinal direction of the rod.

Systems and methods for providing gaps in article or package processing. In some embodiments, the system can include a conveying path along which a first advanced article and a second advanced article can be advanced. The system can further include a first stop location and a second stop location. The first stop location can include movable fingers that are configured to raise to stop the advance of the articles and then lower at specific times to allow the articles to advance with specific distances between the articles. Additionally, the system can include a paddle that also raises and lowers. The paddle lowers to stop an advancing article again, and in doing so, front-end registers the article. Then the paddle can raise to allow the package to advance again along the conveyor.