A robotic arm according to various implementations includes: a tool driver configured to hold a surgical tool; a first section comprising a first end coupled to a base, a second end distal from first end; a first link that includes a motor configured to rotate at least a portion of the first section around a pitch axis; a second link coupled to the first link, the second link including a motor configured to rotate at least a portion of the first section around a roll axis; and a second section comprising: a first end coupled to the second end of the first section, a second end distal from the first end, a first link that includes a motor configured to rotate at least a portion of the second section around a roll axis, a second link coupled to the first link.

A robot includes a base plate rotatable around a rotation axis, a first arm connected to the base plate at a first axis which is perpendicular to the rotation axis and around which the first arm is rotatable, a second arm connected to the first arm at a second axis which is parallel to the first axis and around which the second arm is rotatable, a third arm connected to the second arm at a third axis which is parallel to the first axis and around which the third arm is rotatable, a turnable link connected to the third arm at a fourth axis which is perpendicular to the third axis and around which the turnable link is rotatable, a distal-end swingable portion connected to the turnable link at a fifth axis which is perpendicular to the fourth axis and around which the distal-end swingable portion is rotatable, a distal end connected to the distal-end swingable portion at a sixth axis which is perpendicular to the fifth axis and around which the distal end is rotatable, and a welder connected to the distal end.

A mounting mechanism includes a base plate, a support arm, and a fixing frame. The support arm is mounted at the base plate. The fixing frame includes a connection end and a mounting end opposite to each other. The connection end is mounted at the support arm and configured to rotate relative to the support arm. The mounting end is configured to be selectively engaged with or separated from the base plate. The support arm is configured to be fixed relative to the base plate to clamp at a track when the mounting end is engaged with the base plate, and rotate relative to the base plate when the mounting end is separated from the base plate.

Robotic arms and surgical robotic systems incorporating such arms are described. A robotic arm includes a roll joint connected to a prismatic link by a pitch joint and a tool drive connected to the prismatic link by another pitch joint. The prismatic link includes several prismatic sublinks that are connected by a prismatic joint. A surgical tool supported by the tool drive can insert into a patient along an insertion axis through a remote center of motion of the robotic arm. Movement of the robotic arm can be controlled to telescopically move the prismatic sublinks relative to each other by the prismatic joint while maintaining the remote center of motion fixed. Other embodiments are also described and claimed.

Provided is a robot for retrieving objects with different sizes, shapes, weights, placements, configurations, and/or other characteristics from a floor or raised height. The robot may include a motorized base, a lift that raises to a plurality of heights from the base, an upper platform attached over the lift, a vertical extension extending downwards from a frontside of the upper platform and in front of the lift, a lower platform with a proximal end coupled to the vertical extension and a distal end extending in front of the robot and directly over a ground surface on which the motorized base moves when the lift is in a lowered position, and a retriever for retrieving an object onto the lower platform.

Systems and methods for mounting a robotic arm for use in robotic-assisted surgery, including a mobile shuttle that includes a support member for mounting the robotic arm that extends at least partially over a gantry of an imaging device. Further embodiments include a mounting apparatus for mounting a robotic arm to a base or support column of an imaging device, to a patient table, to a floor or ceiling of a room, or to a cart that extends over the top surface of the patient table.

Exemplary embodiments relate to soft robotic gripper systems suited to grasping target objects in cluttered environments. Some embodiments provide extension rods, hinges, and/or rails that allow a soft robotic actuator to be extended towards or away from a robotic base and/or other actuators. Accordingly, a gripper including the actuator may be reconfigured into a size and/or shape that allows for improved access to the cluttered environment. Further embodiments relate to soft robotic gripper systems for supporting grasped objects during high acceleration movements using vacuum, gripper, and/or bellows devices. Still further embodiments relate to specialized grippers for manipulating food items.

The disclosure concerns a pivoting unit for a handling robot for opening a flap (e.g. door) of a motor vehicle body, comprising a mounting flange, a gripper arm and a first gripping tool for gripping an engagement on the flap to be opened, the first gripping tool being mounted on the gripper arm, and a pivoting head for pivoting the gripper arm between an initial position and an engaged position. The disclosure provides that a second gripping tool is also mounted on the gripper arm, and that the two gripping tools on the gripper arm are adapted to be inserted in different insertion directions into engagement with the openable flap of the motor vehicle body, in particular from top to bottom for the first gripping tool and from bottom to top for the second gripping tool. The disclosure further comprises an associated method.

A robot includes: a manipulator that is provided with an n-th (n is an integer of 1 or larger) arm which is capable of rotating around an n-th rotation axis, an (n+1)-th arm provided on the n-th arm to be capable of rotating around an (n+1)-th rotation axis having an axial direction which is different from an axial direction of the n-th rotation axis, and an (n+2)-th arm provided on the (n+1)-th arm to be capable of rotating around an (n+2)-th rotation axis. In a first state, an outline of the manipulator is positioned on an inner side of a first circle or on the first circle with the n-th rotation axis as the center thereof, and with first length between a distal end of the manipulator and the n-th rotation axis, as a radius, when viewed in the axial direction of the n-th rotation axis.

A robot includes a first arm rotatable around a first axis, a second arm connected to the first arm at a second axis which is parallel to the first axis and around which the second arm is rotatable, a third arm connected to the second arm at a third axis which is parallel to the first axis and around which the third arm is rotatable, a distal-end swingable portion rotatably connected to the third arm, a distal end rotatably connected to the distal-end swingable portion, a fourth actuator configured to rotate the distal-end swingable portion and including a first motor having a first motor rotation axis, and a fifth actuator configured to rotate the distal end and including a second motor having a second motor rotation axis that is parallel to the first motor rotation axis.