In an apparatus for adjustable counterbalance mechanism and a method for controlling the apparatus, the apparatus includes a reference surface, a link, an elastic member, a wire, an idle roller and a compensation torque. The link has a first end rotationally connected to the reference surface to form a rotational center, and a weight center of the link is spaced apart from the rotational center. The elastic member has a first end combined with the link. The wire has a first side combined with a second end of the elastic member, and a second side combined with the reference surface. The idle roller is combined with the link to support a portion between first and second ends of the wire. The compensation torque controller is equipped to the link, to control the position of the idle roller and an elastic force of the elastic member.

A surgical tool configured to receive rotary inputs from a robotic surgical system. The surgical tool comprises a distal end effector comprising jaws for clamping tissue therebetween, an intermediate shaft portion coupled to the distal end effector, and a proximal housing coupled to the intermediate shaft portion. The proximal housing comprises an arrangement of rotary drives comprising a first rotary drive. The first rotary drive comprises an input shaft configured to receive a rotary input from the robotic surgical system, a transition nut slidably positioned on the input shaft, and an output gear. The first rotary drive further comprises a high-speed gear configured to selectively drive the output gear, a high-torque gear configured to selectively drive the output gear, and a spring arrangement configured to bias the transition nut along the input shaft from a high-speed operating state to a high-torque operating state upon obtaining a threshold torque.

A surgical tool configured to receive rotary inputs from a robotic surgical system. The surgical tool comprises a distal end effector comprising jaws for clamping tissue therebetween, an intermediate shaft portion coupled to the distal end effector, and a proximal housing coupled to the intermediate shaft portion. The proximal housing comprises an arrangement of rotary drives comprising a first rotary drive. The first rotary drive comprises an input shaft configured to receive a rotary input from the robotic surgical system, a transition nut slidably positioned on the input shaft, and an output gear. The first rotary drive further comprises a high-speed gear configured to selectively drive the output gear, a high-torque gear configured to selectively drive the output gear, and a spring arrangement configured to bias the transition nut along the input shaft from a high-speed operating state to a high-torque operating state upon obtaining a threshold torque.

A robot arm includes a first arm having a housing with a first stopper provided therein, a second arm rotating relative to the first arm, and a joint unit including an outer ring portion fixed to the second arm, a second stopper provided in the outer ring portion and restricting rotation of the second arm relative to the first arm in cooperation with the first stopper, and an inner ring portion fixed to the first arm and rotating coaxially with the outer ring portion, wherein the housing has a first opening portion opening toward the outer ring portion in a position facing the outer ring portion, and the first stopper projects from the first opening portion.

A robot arm includes a first arm having a housing with a first stopper provided therein, a second arm rotating relative to the first arm, and a joint unit including an outer ring portion fixed to the second arm, a second stopper provided in the outer ring portion and restricting rotation of the second arm relative to the first arm in cooperation with the first stopper, and an inner ring portion fixed to the first arm and rotating coaxially with the outer ring portion, wherein the housing has a first opening portion opening toward the outer ring portion in a position facing the outer ring portion, and the first stopper projects from the first opening portion.

An installing device includes a connection member and a linear motion support. The connection member is disposed at a base end portion of a hollow arm which extends in an extension direction and which has a hollow extending in the extension direction. A linear object passing through the hollow is connectable to the connection member. The linear motion support supports the connection member slidably with respect to the hollow arm in the extension direction.

An installing device includes a connection member and a linear motion support. The connection member is disposed at a base end portion of a hollow arm which extends in an extension direction and which has a hollow extending in the extension direction. A linear object passing through the hollow is connectable to the connection member. The linear motion support supports the connection member slidably with respect to the hollow arm in the extension direction.

A pharmacy order processing system includes a container disassembly workstation defining a container disassembly workspace and a bulk container area including a plurality of bulk containers configured to receive a plurality of pharmaceuticals. The container disassembly workstation includes a holding area, a cutter device, a container manipulation device, a pharmaceutical receptacle, and a container receptacle. The cutter device includes a cutter head and is configured to cut through at least one wall of at least one container to separate at least a first portion of the at least one container of the plurality of containers from a second portion of the at least one container when the at least one container is in a cutter position. The container manipulation includes a gripper device and is configured to move the at least one container between at least the holding position and the cutter position within the container disassembly workspace.

A pharmacy order processing system includes a container disassembly workstation defining a container disassembly workspace and a bulk container area including a plurality of bulk containers configured to receive a plurality of pharmaceuticals. The container disassembly workstation includes a holding area, a cutter device, a container manipulation device, a pharmaceutical receptacle, and a container receptacle. The cutter device includes a cutter head and is configured to cut through at least one wall of at least one container to separate at least a first portion of the at least one container of the plurality of containers from a second portion of the at least one container when the at least one container is in a cutter position. The container manipulation includes a gripper device and is configured to move the at least one container between at least the holding position and the cutter position within the container disassembly workspace.

A substrate processing apparatus including a frame, a first SCARA arm connected to the frame, including an end effector, configured to extend and retract along a first radial axis; a second SCARA arm connected to the frame, including an end effector, configured to extend and retract along a second radial axis, the SCARA arms having a common shoulder axis of rotation; and a drive section coupled to the SCARA arms is configured to independently extend each SCARA arm along a respective radial axis and rotate each SCARA arm about the common shoulder axis of rotation where the first radial axis is angled relative to the second radial axis and the end effector of a respective arm is aligned with a respective radial axis, wherein each end effector is configured to hold at least one substrate and the end effectors are located on a common transfer plane.