A device and a process for feeding articles to be packaged with a packaging apparatus are presented. The articles are transported on a first conveying line and can be arranged according to a desired pattern, which is repeated on a second conveying line from which the articles will be picked up in a subsequent station. For this purpose, at least one transfer device is provided for transferring the articles from the first conveying line to the second conveying line, with a self-moving transfer arm and a respective gripping device to pick up the articles. The gripping device has a plurality of gripping elements which are movable between a first configuration, in which the gripping elements are aligned with each other to grip the articles from the first conveying line, and a second configuration, in which at least two of the gripping elements are staggered with respect to each other, to lay the articles according to a predetermined pattern.

A control system and method for a vacuum attachment system has a programmable controller that interprets feedback from vacuum level sensors and battery sensors to responsively provide warnings and limit or alter machine functions to reduce risk exposure. Vacuum levels and vacuum level change over time are used to evaluate conditions such as vacuum generator function, excessive altitude, vacuum system condition and leakage due to incompatibility of attachment device and load. Warnings are engaged if parameters or limits are not met. At designated/calculated thresholds and conditions the device can adjust its utilization of resources to ensure the safest condition. If conditions are detected that indicate a reduced ability to maintain the attachment, the programmable controller may limit functions such as preventing the operator from initiating another attachment.

A plate handling system (500, 600) for transporting printing plates between workstations in a process workflow. A plurality of vacuum gripper end effectors (512) configured to grip the printing plates are mounted to a computer-controlled transporter (514) configured to translate in at least three orthogonal directions and to rotate about at least one rotational axis. At least one sensor (560) detects orientation of the plate relative to a staging location and a controller (630) causes the transporter to move based upon programmed instructions in accordance with information provided by the sensor. A mobile preparation table (1000) may be provided in the staging location. A thickness measurement system (1090) may be included in some embodiments.

An automated method and system for transitioning a bottle from a horizontal belt conveyor to the entrance of an air conveyor, and vice versa, from an air conveyor to a horizontal belt conveyor. An indexer in a circular arrangement moves around 180 degrees clockwise until the bottle drops into the air conveyor (e.g., pneumatic tube). This motion controls the bottle's movement; otherwise, the bottle would free-fall off the conveyor. The indexer rotary device provides control of the vial transition, keeping it vertical so it goes into the tube in a controlled manner.

An automatic tray loading system and a use method of the same are provided, which includes a stacked tray assembly, including at least one tray which is stacked up, where the at least one tray is provided with several locating slots; a tray lifting platform which includes a tray supporting table being connected with a elevating mechanism; a tray pick and place platform having a working region covers a tray input module, where the tray pick and place platform includes a manipulator which is connected with a multidimensional motion mechanism; and a delivery table including a tray placement plate, where each of the tray placement plate is provided with a groove which is configured to place the at least one layer of trays, and each of the tray placement plates is connected with a linear driving mechanism.

Robotic gripping devices and methods for performing a picking operation. The methods described herein may involve positioning a gripping device with respect to an item to be grasped and then executing a first picking operation using the gripping device to obtain a grasp on the item. The methods may then involve executing at least two of a force detection procedure to detect a force applied to a portion of the gripping device, a grasping space detection procedure to detect an item in grasping range of the gripping device, a pressure detection procedure configured to detect pressure in an airflow path, and an item load detection procedure to detect force in a mechanical load path of the gripping device.

A part-processing machine having, in series, consecutive parts on a belt (2) moving same along a main conveying line. Selectively identified non-compliant parts are removed from the conveying line, into a transfer device (1) by pickup tools (8) supported on the periphery of a rotating drum (6) mounted transversely to the conveying line and arranged to rotate about itself so as to pass over the belt, enabling the non-compliant parts to be picked up by the pickup tools and released once the parts have been transported away from the conveying line. The pickup tools have pneumatic gripping heads, more particularly for example suction cups. The pneumatic gripping heads are depressurized relative to the surrounding air by a low-pressure chamber provided inside the drum, to which each head is connected by a tube inside a tool support arm.

A system and method for a dynamic robot kitting line that can include: processing a set of order requests and setting a packing fulfillment plan process for a robotic kitting line, wherein robotic kitting line comprises a conveyor system, a set of robotic workcells arranged along the conveyor system, and where each robotic workcell includes at least one robotic pick-and-place machine and a set of item bins; and managing operation of the robotic kitting line according to the packing fulfillment plan, which includes: conveying item totes through the set of robotic workcells, and for each item tote, progressively packing items of an order request assigned to an item tote by incrementally packing items at robotic workcells of the set of robotic workcells.

Equipment for the logistics of slab-shaped articles comprises supply line(s) of slab-shaped article(s) and outlet line(s) of the slab-shaped article(s); robotic gripping assembly(s) of the slab-shaped article(s) provided with at least three degrees of freedom and positioned between the supply line(s) and the outlet line(s); first movement device/unit/component/etc. of the gripping assembly(s) along a direction(s) of movement; where the supply line(s) and said outlet line(s) are substantially aligned to each other along the direction(s) of movement. Equipment also comprises temporary storage stations of the slab-shaped article(s) arranged laterally to the gripping assembly and substantially aligned to each other to define at least one row substantially parallel to the direction of movement, wherein the gripping assembly(s) picks the slab-shaped article(s) coining from the supply line(s); positions the slab-shaped article(s) on the storage station(s); and picks the slab-shaped article(s) from the storage station(s) and bring it to the outlet line(s).

A system including a programmable motion device and an end effector for grasping objects to be moved by the programmable motion device is disclosed. The system includes a vacuum source that provides a high flow vacuum such that an object may be grasped at an end effector opening while permitting a substantial flow of air through the opening, and a dead-head limitation system for limiting any effects of dead-heading on the vacuum source in the event that a flow of air to the vacuum source is interrupted.