A robotic surgical system includes a robotic arm, a carriage coupled to the robotic arm, a drive belt, and a motor supported by the carriage. The carriage rotatably supports an instrument rotation pulley and a motor axis pulley. The drive belt is coupled to the instrument rotation pulley and the motor axis pulley. The motor includes a coupling that is driven by the motor upon an actuation of the motor. The coupling is engaged with the motor axis pulley such that rotation of the motor axis pulley rotates the drive belt to rotate the instrument rotation pulley.

A robotic surgical system includes a robotic arm, a carriage coupled to the robotic arm, a drive belt, and a motor supported by the carriage. The carriage rotatably supports an instrument rotation pulley and a motor axis pulley. The drive belt is coupled to the instrument rotation pulley and the motor axis pulley. The motor includes a coupling that is driven by the motor upon an actuation of the motor. The coupling is engaged with the motor axis pulley such that rotation of the motor axis pulley rotates the drive belt to rotate the instrument rotation pulley.

The arm structure of a robot includes a first motor and a second motor attached to an arm member, a first bearing attached to the arm member, an arm member supported on the arm member by the first bearing, a first gear rotating together with the first bearing, a first motor transmission gear transmitting rotation force of the first motor to the first gear, a second bearing attached to the arm member and having a center axis perpendicular to a center axis of the first bearing, a rotary member supported on the arm member by the second bearing and rotatable relative to the arm member, a second gear attached to the rotary member, and a second motor transmission gear transmitting rotation force of the second motor to the second gear to make the rotary member rotate.

A sterile interface module for coupling an electromechanical robotic surgical instrument to a robotic surgical assembly is provided. The surgical instrument includes an end effector and is configured to be actuated by the robotic surgical assembly. The sterile interface module includes a body member and a drive assembly. The body member is configured to selectively couple the surgical instrument to the robotic surgical assembly. The body member is formed of a dielectric material. The drive assembly is supported within the body member and is configured to transmit rotational forces from the robotic surgical assembly to the surgical instrument to actuate the surgical instrument to enable the surgical instrument to perform a function.

A robot that includes a first shaft unit in which a first motor drives a second member relative to a first member; a second shaft unit in which a second motor drives a fourth member relative to a third member; and a securing member that is provided in a detachable manner between the second member and the third member and that integrally secures the second member and the third member to each other.

Systems and methods to manipulate objects may include an adjustable robotic end of arm tool including a pair of static forks or arms and a pair of movable forks or arms. The static forks may be configured to lift objects, such as pallets, totes, or bins. The movable forks may be configured to move between a plurality of positions, including a storage position and a lifting position. When in the lifting position, the movable forks may also be configured to lift objects, such as pallets, totes, or bins, such that the adjustable robotic end of arm tool may simultaneously or concurrently lift and manipulate multiple objects using the static forks and the movable forks, thereby improving speed and efficiency of operations or processes utilizing the adjustable robotic end of arm tool.

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 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.

A robot is provided which has: a first arm portion to which an end effector is attached, a second arm portion configured to support, at a tip portion thereof, the first arm portion swingably about a first axis, a third arm portion configured to support a base end portion of the second arm portion rotatably about a second axis orthogonal to the first axis, a tube arranged from the base end portion side toward the tip portion side of the second arm portion and connected to the end effector; and a first recess portion and a second recess portion, which are formed along an arrangement direction of the tube between the base end portion and the tip portion on one side and the other side in a direction orthogonal to both of the first and second axes, respectively.

A surgical instrument holder includes a carriage, a housing, and a drive assembly. The carriage is configured for engagement to a surgical robotic arm and for supporting an instrument drive unit. The housing extends from the carriage and defines a channel. The drive assembly includes a pulley, a belt, and an annular member. The pulley is rotatably disposed within the housing and in operable engagement with a motor of the carriage such that actuation of the motor rotates the pulley. The belt is rotatably disposed within the housing and in operable engagement with the pulley such that rotation of the pulley effects rotation of the belt. The annular member is disposed within the channel of the housing and configured for non-rotatable receipt of an instrument drive unit. The annular member is in operable engagement with the belt such that rotation of the belt effects rotation of the annular member.