This disclosure relates to a multi-functional merchandiser device, and more particularly to a handheld multi-functional tool and its method of use. In particular implementations, the improved merchandiser device may comprise multiple end effectors for a set of distinct merchandising operations.

A collapsible grabber device, comprises a telescoping pole; a jaw assembly at the distal end of the pole comprising two jaws movably coupled by a pivot for releasably gripping an object in a closed position, a handle at the proximal end configured to house the telescoping pole and the jaw assembly in the collapsed state; a lever on handle for controlling the jaw assembly; a spring within the jaw assembly for biasing the jaws in either an open position or a closed position; and a cable coupling the jaw assembly and the lever. Advantages of the grabber include compactness, concealability, higher usage rates, collapsibility/extendibility, ruggedness, precision and attractiveness.

An end effector assembly for a picking robot, and a tool unit is disclosed, the end effector assembly comprising a first end effector part, a second end effector part, and an end effector device mounted on the second end effector part, wherein the first end effector part and the second end effector part are connected via a joint connection comprising a first joint having at least a first degree of freedom, the joint connection comprising a first spring construction having a first end and a second end, the first end connected to the first end effector part and the second end connected to the second end effector part.

A robotic arm control system including a robotic arm configured to deploy one or more tools in an operating space, one or more sensors, and a control system operably configured to: scan the operating space with the one or more sensors, identify a surface of the operating space based at least in part upon information sensed by the one or more sensors, establish a virtual barrier offset from the surface, and limit movement of the robotic arm based at least in part upon the virtual barrier.

A self-checkout system can include a plurality of telescoped bagging arm segments moveably coupled together in an order according to respective diameters of the plurality of telescoped bagging arm segments. A scanning system can be configured to provide a characteristic of an item purchased by a user of the self-checkout system and a processor circuit can be operatively coupled to the plurality of telescoped bagging arm segments and to the scanning system, where the processor circuit can be configured to move the plurality of telescoped bagging arm segments relative to one another based on the characteristic of the item to be placed in a bag in use with the self-checkout system.

A surgical instrument includes an end effector, a shaft assembly, a drive, and an activating mechanism. The end effector includes first and second jaws. At least one of the first and second jaws is pivotable relative to the other of the first and second jaws between open and closed positions. The shaft assembly extends proximally from the end effector. The drive is operatively connected to a portion of at least one of the end effector or the shaft assembly. The activating mechanism includes an actuation body operatively connected to the drive. The portion is configured to perform a first actuation profile in response to the actuation body moving along a first predetermined path or perform a second actuation profile in response to the actuation body moving along a second predetermined path. Selection of the first predetermined path is configured to prevent the actuation body from accessing the second predetermined path.

Systems, methods, and computer-readable media are disclosed for concentric suction cup tools with parallel pistons. In one embodiment, an example picking assembly may include a first piston subassembly with a first air cylinder, a first sliding rail that slides relative to the first air cylinder, and a first suction cup. The example picking assembly may include a second piston subassembly comprising a second air cylinder, a second sliding rail that slides relative to the second air cylinder, and a second suction cup, where the first and second piston subassemblies may be configured to independently actuate from a retracted position to an extended position. The example picking assembly may include a first guide plate with a first aperture for the first piston subassembly and a second aperture for the second piston subassembly, a shell that forms a housing for the picking assembly, and an airflow coupler.

An object gripping mechanism is provided for use with a robotic arm. A robotic arm and method of manufacturing an object gripping mechanism are also provided. The object gripping mechanism includes an attachment modular configured to connect the object gripping mechanism to the robotic arm. The object gripping mechanism also includes a plurality of retractable arms each pivotably connected with the attachment modular. The object gripping mechanism also includes one or more movement mechanisms collectively configured to pivot the plurality of retractable arms to a desired position. The object gripping mechanism further includes a drive mechanism positioned within each of the plurality of retractable arms and configured to pivot the object engagement feature using a gear and timing belt configuration.

A mechanical arm designed to provide automated garbage collection with smooth, constant movement (i.e. movement that has minimal jerk/shock) thereby resulting in limited shock stress on the components and leading to high durability. The mechanical arm including a horizontal displacement system having a plurality of sections rollingly engaged to one another and a motor mounted to an immobile section for drivingly extending section in a generally horizontal orientation, a vertical displacement system having a plurality of masts rollingly engaged to one another and a motor mounted to a first mast for drivingly extending a second mast in a generally vertical orientation, and/or a grabber system having a plurality of fingers mounted to a frame and operated by a single motor.

A harvesting system includes a vertical frame, a plurality of linear robots, a plurality of cameras and a processor. The vertical frame is configured to be positioned opposite a sector to be harvested. The robots are arranged in pairs stacked vertically in the frame, each pair including first and second robots that are configured to move together along a vertical axis, to move independently of one another along a horizontal axis, and have respective first and second robot arms that are configured to approach the sector and harvest fruit. The plurality of cameras is configured to acquire images of the sector. The processor is configured to identify the fruit in the images and control the robots to harvest the fruit.