A multi-station cam carrying mechanism, including a baseplate, a rotary shaft in the middle of the baseplate, an electric motor connected to the bottom of the rotary shaft, a rotary plate at an upper part of the rotary shaft, mounting frames on the baseplate, a mounting plate on the mounting frames, an annular sliding groove on a bottom face of the mounting plate along a cam trajectory, and multiple grabbing and transferring assemblies annularly and uniformly arranged at intervals, with bottom parts slidably arranged on the rotary plate and top parts slidably arranged in the sliding groove. The electric motor drives multiple stations to carry products simultaneously, and undergoes a reciprocating movement along the cam trajectory, grabhooks on the assemblies reciprocate vertically to grab and transfer the products, so that the products are sequentially transferred from one station to the next station.

A storage, retrieval and processing system for processing objects is disclosed that includes a plurality of bins including objects to be distributed by the storage, retrieval and processing system, the plurality of bins being provided on an input conveyance system, a programmable motion device that includes an end effector for grasping and moving any of the objects, a perception system for providing perception data regarding a selected object that is presented to the perception system by the programmable motion device, and a routing conveyance system for receiving the selected object, and for moving the selected object in each of horizontal and vertical directions toward a destination container responsive to the perception data, the destination container being provided among a plurality of destination containers in a row that are provided as a set on a destination conveyance system.

According to one embodiment, a holding apparatus includes a holding part, a rotating part, a supporting part, and a moving mechanism. The holding part is configured to hold an article. The rotating part is configured to rotate the holding part. The supporting part is configured to support the article from below. The moving mechanism is configured to move the holding part with respect to the supporting part.

A rejection mechanism for a conveyor system, which pushes parcels across a surface, includes a linear actuator and a paddle mounted to the linear actuator for movement between a first position and a second position. The paddle includes a bracket portion, an upright portion, and a lateral wall portion. The lateral wall portion is configured to push parcels across a surface positioned below the lateral wall portion as the paddle is moved from the first position to the second position. In some embodiments, the rejection mechanism can further include a way cover which expands and contracts with movement of the paddle. In some embodiments, the lateral wall portion can be configured to rotate about an axis of rotation defined by a hinge to transition between an engaged and a disengaged position.

A robotic system includes a hub assembly rotatable about a vertical axis. A robotic arm has a first end connected to the hub assembly and an opposite second end connected to an end effector, which is configured for holding an item. The system is configured to support an agent on or above the hub assembly for working on the item held by the end effector. The operation of the robotic arm and end effector to move the item does not obstruct operation of the agent.

A system includes a robot configured to load and/or unload from a location, such as a cargo carrier or building. The robot includes a base unit that has a transport system to move the base unit. A mast extends from the base unit, and the mast has a mast conveyor. An End of Arm Tool (EoAT) is coupled to the mast. The EoAT includes an EoAT conveyor configured to move a cargo item to and from the mast conveyor. A gripper mechanism is configured to move between a retracted position where the gripper mechanism is clear of the cargo item on the EoAT conveyor and an extended position where the gripper mechanism is able to grip the cargo item.

Techniques for product-stacking and case-packing are particularly adapted for product that is packaged in envelopes or flexibly-sided containers. Such products include may different types, such as foodstuffs, books, boxed goods, etc. In an example, a product-stacking and case-packing system may include a product-stacking assembly and a case-packing assembly. In the example, the product-stacking assembly may be configured with a plurality of pairs of flights, each pair of flights programmed to move according to operation of an associated pair servo motors, and programmed to receive and down-stack incoming product items into groups. In the example, the case-packing assembly may include a robotic arm and end-of-arm tool configured to grasp one or more groups of stacked product items, when pushed from the product-stacking assembly, and place each group of stacked product items in a case (e.g., a cardboard box).

According to one embodiment, a holding apparatus includes a holding part, a rotating part, a supporting part, and a moving mechanism. The holding part is configured to hold an article. The rotating part is configured to rotate the holding part. The supporting part is configured to support the article from below. The moving mechanism is configured to move the holding part with respect to the supporting part.

Actuating an air conveyor device is disclosed, including: causing an airflow to be generated by an airflow generator of an air conveyor device, wherein the airflow generator is configured to cause the airflow to enter an intake port of the air conveyor device and exit from an outlet port of the air conveyor device in response to receiving air at an air input port of the air conveyor device; causing a target object to be captured by the air conveyor device using the airflow; activating a positioning actuator mechanism to position the air conveyor device; and causing the target object to be ejected from the air conveyor device.

A picking station for picking goods has a source container conveyor for automated transporting of source containers, a target container conveyor for automated transporting of target containers and a fully automated robot system. The source container conveyor includes a first removal area, where a first source container is provisioned, and a second removal area, where a second source container is provisioned. The target container conveyor includes a first loading area, where a first target container is provisioned, and a second loading area, where a second target container is provisioned. The robot system includes a robot having a gripping unit configured to remove goods according to different orders from the first source container and/or second source container and place them into the first target container and/or second target container, and a sensor system for capturing the goods in the first and second source containers. A method automatically picks goods.