A pickup apparatus includes a plurality of pickers sliding along a first direction and a space adjuster including a plurality of space adjusting plates. Each picker includes a protruding portion combined with a picker body, and each of the space adjusting plates is between a respective pair of adjacent pickers. The protruding portion of each picker contacts sidewalls of adjacent space adjusting plates. At least one of the space adjusting plates moves along a second direction crossing the first direction. A width in the first direction of each space adjusting plate varies along the second direction.

A pickup apparatus includes a plurality of pickers sliding along a first direction and a space adjuster including a plurality of space adjusting plates. Each picker includes a protruding portion combined with a picker body, and each of the space adjusting plates is between a respective pair of adjacent pickers. The protruding portion of each picker contacts sidewalls of adjacent space adjusting plates. At least one of the space adjusting plates moves along a second direction crossing the first direction. A width in the first direction of each space adjusting plate varies along the second direction.

Systems and methods here may include a vehicle with automated subcomponents for harvesting delicate items such as berries. In some examples, the vehicle includes a targeting subcomponent and a harvesting subcomponent. In some examples, the targeting subcomponent utilizes multiple cameras to create three-dimensional maps of foliage and targets. In some examples, identifying targets may be done remotely from the harvesting machine, and target coordinates communicated to the harvesting machine for robotic harvesting.

A robotic hand includes a servo housing, a printed circuit board (PCB), a motor, a planetary gear transmission assembly and a plurality of claws rotatably connected to the servo housing. The motor is electrically connected to the PCB. An input end of the planetary gear transmission assembly is connected to an output shaft of the motor. An output end of the planetary gear transmission assembly includes a cam having a number of protruding portions in a circumferential direction thereof. Each two adjacent protruding portions are spaced apart from each other by a space, thereby forming a curved circumferential surface. One end of each of the claws stays in contact with the curved circumferential surface, enabling the claws to be rotatable toward or away from one another when driven by the cam.

A gripping device with linear actuation for a robotic arm for seizing and gripping Petri dishes and other light items. The gripping device has a support and first and second gripping arms slidably retained relative to the support by guide rods. A motorized drive mechanism actuates the gripping arms through an operating member that acts only on the first gripping arm. Through an interconnection mechanism, movement of the first gripping arm actuates a simultaneous and dependent opposite movement of the second gripping arm so that the gripping arms are movable between a slack position and a clamping position. The operating member acts on the first gripping arm through a resiliently compressible member, the distortion of which is measured to provide a clamping limitation mechanism.

An end effector for use and connection to a robot arm of a robotic surgical system, wherein the end effector is controlled and/or articulated by at least one cable extending from a respective motor of a control device of the robot surgical system, is provided. The end effector includes a wrist assembly, and a jaw assembly. The jaw assembly includes a cam pulley rotatably supported on at least one support plate of the jaw assembly, wherein the cam pulley is operatively connected to a proximal end of each of the jaws of the jaw assembly such that rotation of the cam pulley results in one of an opening and closing of the jaw assembly.

A mechanical device for grasping an object includes a receiver having a distal end shaft with an internal bore, the internal bore defining a recessed track. The recessed track defines a curvilinear path having two sets of resting peaks, each set of resting peaks being at a different height relative to a centerline of the curvilinear path. An actuator is slidably engaged with the receiver and includes a central shaft and an activator disposed at a distal end portion of the central shaft. A rotatable sleeve is disposed within the internal bore of the receiver and is coupled to the actuator. The rotatable sleeve has opposed protrusions, the opposed protrusions being disposed within the recessed track of the receiver. A pilot is secured to a distal end portion of the receiver and a grasping device is mounted to the pilot and coupled to the activator.

An end effector apparatus for a surgical instrument is disclosed including a housing having a first jaw mounted on a revolute joint and providing a first electrical conduction path between the housing and the first jaw. A second jaw is mounted on a revolute joint within the housing and is insulated from the housing, the jaws each having a manipulating portion and a lever arm. A yoke is received within the housing and mechanically coupled to the lever arms and to a control link and is moveable in response to movements of the control link to cause opening and closing of the jaws, the yoke being electrically insulated from the housing and the first jaw. A second electrical conduction path is provided between the control link and the second jaw. The electrical conduction paths facilitate conduction of an electrocauterization current through tissue grasped between the jaws.

Examples described here include a device that has a housing defining a cavity, and a force sensor. The device also includes a first hydraulic actuator positioned in the cavity, and a second hydraulic actuator positioned in the cavity. The first and second hydraulic actuators move between respectively relaxing modes and thrusting modes along respective longitudinal axes. The longitudinal axis of the first hydraulic actuator is substantially parallel to the longitudinal axis of the second hydraulic actuator. The device also includes a first actuated member coupled to the first hydraulic actuator, and a second actuated member coupled to the second hydraulic actuator.

A gripper has a body with a jaw support portion and powering portion. A powering assembly is positioned in the powering portion. A stationary jaw is secured to the jaw support portion. A movable jaw is pivotally secured to the jaw support portion about a pivot pin. A rod from the powering assembly connects in a slot on the movable jaw. The pivot pin is positioned on an opposite side of an axis of the rod on the clevis portion away from the stationary jaw. The non-clamping end of the movable jaw is incapable of extending below an end plane of the body of the stationary jaw side of the gripper.