An apparatus for picking up and positioning an item includes a vacuum assembly capable of applying a suction force to the item. The apparatus further includes an item engaging plate positioned adjacent the vacuum assembly in a first position for engaging with and picking the item. The engaging plate is moveable to a second position by one or more actuators that reduce a suction force experienced at the engaging plate to deposit or place the item. The one or more fans may additionally be controlled to limit a suction force generated during a disengagement operation where the item is being deposited or placed.

A plurality of first vacuum pads for suctioning a workpiece are directly or indirectly attached to a main body. A slider is configured to slide in an outward direction of the main body. When the slider slides to protrude in the outward direction of the main body while the first vacuum pads are suctioning the workpiece, a sensor detects an end portion of the workpiece. While the sensor detects the end portion of the workpiece and the slider is stopped, a second vacuum pad holds up the end portion of the workpiece by suctioning the workpiece at a position outside from positions at which the first vacuum pads suction the workpiece.

A controller includes: a deformation information obtaining unit configured to obtain information on deformation of a suction portion that suctions an object with negative pressure, and that is deformed by the negative pressure; and an operation control unit configured to control movement of the suction portion in accordance with deformation of the suction portion.

Embodiments of the present invention pertain to a plant trimming device having a removable cutting cartridge. A direct-drive motor is magnetically coupled to the cutting cartridge. The cutting cartridge houses a blade and a set of rotating blades. Plant parts are cut by the rotating blades across the razor. The cartridge is mounted on rails and has a handle to facilitate the ease of inserting and removing the cutting cartridge. Thereby, an old cutting cartridge is readily removed and replaced by a new cutting cartridge. Furthermore, the cutting cartridge can easily be removed for cleaning and later re-inserted back into the plant trimming device.

Embodiments of the present invention pertain to a modular plant trimming system. A number of plant trimming machines are placed side by side. These plant trimming machines trim leaves from a plant. A sensor detects when one or more of the plant trimming machines are added or removed from the system. A processor then balances a load of plants to be trimmed to be split between the currently available number of plant trimming machines.

Embodiments of the present invention pertain to a tiltable tumbler for use in a plant trimming machine. Plants are placed in a tumbler. As the tumbler rotates, leaves extending through slots in the tumbler by a vacuum are trimmed off. A mechanism is used to adjust the tilt of the tumbler. Thereby, the rate by which the plant material in the tumbler is processed is faster with a higher tilt or slower with a lower tilt. The degree of tilt is adjustable either manually or automatically via a computer.

A part transfer system includes a movable support, a plurality of arms coupled to the movable support, and an end effector coupled to each of the plurality of arms. The end effector includes a body and a plurality of dividers each coupled to the body. The plurality of dividers divides the body into a plurality of partitions. The end effector includes a plurality of vacuum ports each in fluid communication with one of the plurality of partitions. The part transfer system further includes a vacuum source in fluid communication with at least one of the plurality of vacuum ports. Each of the plurality of vacuum ports is configured to draw a fluid from the plurality of partitions to establish a vacuum between the end effector and a part that is engaged with the end effector, thereby securing the part to the end effector.

An emblem installation system for installing emblems on a work piece includes an end effector for a robotic arm. The end effector has a base and multiple vacuum gripper modules repositionable along the base in different configurations. The vacuum gripper modules are configured to simultaneously grip multiple emblems and individually release the emblems. An emblem installation method includes applying a force within a first range of forces to the multiple emblems individually and in succession via vacuum gripper modules of an end effector on a robotic arm, with the emblems disposed at a first location, applying a vacuum to the vacuum gripper modules to grip the emblems with the vacuum gripper modules, and moving the robotic arm from the first location to a second location adjacent a workpiece with the emblems gripped by the vacuum gripper modules.

A robotic system comprising an end effector-mounted sensor is disclosed. In various embodiments, a robotic arm is manipulated to move a sensor to a position such that an object of interest is within a read range of the sensor. A sensor data read by the sensor is received via a communication interface. The sensor data is used to determine an attribute of the object; and the determined attribute of the object is used to determine a plan to grasp and move the object.

A robotic singulation system is disclosed. In various embodiments, sensor data including data associated with an item present in a workspace is received. The sensor data is used to determine and implement a plan to autonomously operate a robotic structure to move and place the item singly in a corresponding location in a singulation conveyance structure. The plan takes into consideration an attribute of the item determined based at least in part on the sensor data.