Abstract: A robot system according to embodiments includes a position command generating unit that corrects a position command of a motor based on a rotation angle of the motor, which drives a link of a robot via a speed reducer, and a rotation angle of an output shaft of the speed reducer.

Abstract: An electronic device processing system is disclosed. The system includes a transfer chamber including facets and a plurality of single-entry process chambers coupled to the facets, wherein at least some process chambers are non-focalized process chambers, at least one load lock chamber, and a robot apparatus operable to transport substrates between the process chambers and the load lock chamber(s). Robot apparatus includes an upper arm, a forearm, and a wrist member adapted for independent rotation relative to the forearm about a wrist axis, and an end effector adapted to carry a substrate. Various degrees of yaw may be imparted to the wrist member in order to service the non-focalized process chambers. Systems and methods are also provided as are other aspects.

Abstract: The various embodiments disclosed herein relate to improved robotic surgical systems, including robotic surgical devices having improved arm components and/or biometric sensors, contact detection systems for robotic surgical devices, gross positioning systems and devices for use in robotic surgical systems, and improved external controllers and consoles.

Abstract: Disclosed are methods and systems for using hieroglyphs for communication in a rapid fabrication environment. The method includes receiving, by a control system for an articulated robotic arm, one or more images of a fabrication machine build space. The method includes identifying, by the control system, a hieroglyph present in the one or more images and translating the identified hieroglyph into one or more instructions for manipulation of the articulated robotic arm. The method includes causing the articulated robotic arm to carry out the instructions translated from the identified hieroglyph. Accordingly foreign objects are inserted into fabricated objects during an automated rapid fabrication process without extensive redesign of the rapid fabrication machine. In some implementations, an unmodified third-party stereolithographic rapid fabrication machine can be used.

Abstract: A steerable multi-linked device may include a first multi-linked mechanism and a second multi-linked mechanism. At least one of the first multi-linked mechanism and the second multi-linked mechanism may include a first link, a plurality of intermediate links, a second link movably coupled to a second one of the intermediate links and a reinforcing member. A first one of the intermediate links may be movably coupled to the first link, and the reinforcing member may extend from a first end of a third one of the intermediate links toward a second end of the third one of the intermediate links.

Abstract: A robotic arm assembly includes a first arm and second arm coupled by a shaft and bearing assembly, forming a joint at which the first arm rotates about a joint axis. The bearing assembly includes angular contact cartridge bearings contacting corresponding angled surfaces of the assembly, and a bearing cap. The shaft is attached to the first arm, extends through the second arm, and is attached to the bearing cap such that the bearing assembly is axially compressed between the bearing cap and the first arm. The bearing assembly may include components for preloading the bearing assembly and enabling components to self-align during assembly.

Abstract: A jointed arm has an upper arm member joined to a second shoulder member, a first forearm member joined to the upper arm member by a first bending and stretching mechanism, and a wrist member joined to the first forearm member by a second bending and stretching mechanism, the first forearm member has a first turning mechanism that rotates the second bending and stretching mechanism, a hand section is joined to the wrist member by a second turning mechanism, and the rotation axes of the first and second turning mechanisms are offset. The upper arm member has a housing recessed portion that houses part of the first forearm member, part of the first turning mechanism, and part of the second bending and stretching mechanism in a state in which the first forearm member bends toward the upper arm member and the wrist member bends toward the first forearm member.

Abstract: A master-slave manipulator includes a remote manipulation device, a slave manipulator, and a control unit. The remote manipulation device as a master gives an operating command corresponding to a plurality of degrees of freedom. The slave manipulator includes a plurality of joints corresponding to the degrees of freedom. The slave manipulator includes a redundant joint among the joints. The control unit controls operations of the joints in accordance with the operating command. The control unit calculates an orientation change of the remote manipulation device from the operating command at predetermined time intervals and selects and drives one of the joints in redundancy relationship among the joints in accordance with the orientation change.

Abstract: A joint mechanism includes a motor including a motor shaft and a hypoid pinion provided at a tip end of the motor shaft and a speed reducer configured to reduce a rotation speed of the motor at a speed reduction ratio. The speed reducer includes a screw-shaped input shaft and a ring-shaped gear meshing with the screw-shaped input shaft and three-dimensionally intersecting the screw-shaped input shaft at a right angle. Further, the screw-shaped input shaft includes a shaft body provided with a screw portion and a hypoid gear arranged at one end of the screw-shaped input shaft and configured to mesh with the hypoid pinion. Furthermore, the screw-shaped input shaft has an axis three-dimensionally intersecting the motor shaft at a right angle.

Abstract: A pivot port that can provide a pivot point for a surgical instrument. The pivot port may be held in a stationary position by a support arm assembly that is attached to a table. The pivot port may include either an adapter or a ball joint that can support the surgical instrument. The pivot port allows the instrument to pivot relative to a patient.

Abstract: A spherical transmission joint has an input shaft connected to a driving source to rotate, an input link fixed to the input shaft to be rotated by the input shaft and having a bent shape, a coupler link rotatably mounted to a first rotary shaft mounted to the input link and having a bent shape, an output link rotatably mounted to a second rotary shaft mounted to the coupler link and having a bent shape, and an output shaft fixed to the output link. This spherical transmission joint for rotating power transmission of inclined shafts is widely used for transmission joints with certain gradients since a rotating angle between an input shaft and an output shaft is ranged wide.

Abstract: A jointed arm has an upper arm member joined to a second shoulder member, a first forearm member joined to the upper arm member by a first bending and stretching mechanism, and a wrist member joined to the first forearm member by a second bending and stretching mechanism, the first forearm member has a first turning mechanism that rotates the second bending and stretching mechanism, a hand section is joined to the wrist member by a second turning mechanism, and the rotation axes of the first and second turning mechanisms are offset. The upper arm member has a housing recessed portion that houses part of the first forearm member, part of the first turning mechanism, and part of the second bending and stretching mechanism in a state in which the first forearm member bends toward the upper arm member and the wrist member bends toward the first forearm member.

Abstract: A system for externally actuating an animatronic figure. The system including a first robotic mechanism configured as a remote center mechanism for rotating a first rod about a first remote center point. The first rod is attached to a first driven part of the figure with the first remote center point spaced apart from the figure. The system includes a second robotic mechanism rotating a second rod about a second remote center point. The second rod is attached to the second driven part of the animatronic figure, and the second remote center point is spaced apart from the animatronic figure. The system includes a third robotic mechanism rotating a third rod about a remote center point, with the third rod attached to a third driven part of the figure, and the three robotic mechanisms are concurrently operable via a computer-based controller to provide the figure with twenty-one degrees of freedom.

Abstract: A substrate transport apparatus including a frame, a drive section connected to the frame and including at least one independently controllable motor, at least two substrate transport arms connected to the frame and comprising arm links arranged for supporting and transporting substrates, and a mechanical motion switch coupled to the at least one independently controllable motor and the at least two substrate transport arms for effecting the extension and retraction of one of the at least two substrate transport arms while the other one of the at least two substrate transport arms remains in a substantially retracted configuration.

Abstract: A rotating shaft has: a first shaft member that includes a rail member and a first connecting portion which is disposed at the rail member; and a second shaft member that includes a slider which is movably installed to the rail member, a tubular unit which is secured to the slider, and a second connecting portion which is disposed at the tubular unit. The slider includes a plurality of roller type rolling elements. The plurality of roller type rolling elements includes: first roller type rolling elements which roll along a rolling path and when torque in a first direction is inputted, transfer running torque between the slider and the rail member; and second roller type rolling elements which roll along a rolling path and when torque in a second direction, which is opposite of the first direction, is inputted, transfer running torque between the slider and the rail member.

Abstract: A control device (1) for a robot arm (8) which, if a person approach detection unit (3) detects approach of a person, performs control according to an impact between the robot arm (8) and the person. The control performed according to the impact is performed through an impact countermeasure motion control unit (4) and by setting individual mechanical impedances for respective joint portions of the robot arm (8) based on a movement of the person detected by a human movement detection unit (2).

Abstract: A method for controlling a redundant robot arm includes the steps of selecting an application for performing a robotic process on a workpiece with the arm and defining at least one constraint on motion of the arm. Then an instruction set is generated based upon the selected application representing a path for a robot tool attached to the arm by operating the arm in one of a teaching mode and a programmed mode to perform the robotic process on the workpiece and movement of the arm is controlled during the robotic process. A constraint algorithm is generated to maintain a predetermined point on the arm to at least one of be on, be near and avoid a specified constraint in a robot envelope during movement of the arm, and a singularity algorithm is generated to avoid a singularity encountered during the movement of the arm.

Abstract: A holding device for medical purposes having a carrier arm on whose distal end a medical instrument can be secured and having at least one joint for positioning the carrier arm and/or the medical instrument, where the joint can be converted between the position that releases the joint and the position that blocks the joint. The holding device provides simple operation, reliable positionability, and can be cleaned well. The joint comprises at least two joint members that enter into active connection with one another by mutually engaging catching elements, where the catching elements are positioned essentially perpendicular to the longitudinal direction of the carrier arm and are pre-tensed with respect to one another by a spring element, and that in the joint at least one hydraulically or pneumatically spreadable expansion element is positioned by which the joint can be converted into the position that releases the joint.

Abstract: A mechanism for articulating a right arm, a left arm, a right forearm, and a left forearm of a humanoid, the arms are coupled with a torso of the humanoid by humeroscapular joints. Each of the forearms is coupled with a humerus of the respective arm, by a respective proximal radioulnar joint. The mechanism includes a first transmission, a second transmission, a first actuator, a second actuator, and a controller. The first actuator is coupled with the right humeroscapular joint and with the left proximal radioulnar joint via the first transmission. The second actuator is coupled with the left humeroscapular joint and with the right proximal radioulnar joint via the second transmission, the controller controlling the movements of each of the first actuator and of the second actuator.

Abstract: Systems and methods that facilitate cables to pass through moving, space-constrained joints and conveying power and/or signals to various robotic joint-associated elements utilize a unitary and flat laminated cable slack within the joint to accommodate the relative motion between mechanical elements of the joints. In various embodiments, the cable has multiple insulated sub-cables; each sub-cable is insulated and physically separable from all other sub-cables. Some of the sub-cables are separated from the cable and electrically connected to joint-associated components for conveying signals and power thereto without mechanically interfering with relative motion between mechanical elements of the joint.

Abstract: A mechanical joint includes a first axial bracket, a first bearing, a second bearing, a sleeve, a second axial bracket, and an anti-jamming mechanism. The first axial bracket includes a rotary shaft. The first bearing, the second bearing, and the sleeve sleeve on the rotary shaft of the first axial bracket in turn, the sleeve being sandwiched between the first and second bearings. The second axial bracket is rotatably assembled to the first axial bracket via the first and second bearings. The anti-jamming mechanism is resiliently assembled within the second axial bracket and sleeves on the sleeve. One end of the anti-jamming mechanism resists the second axial bracket and the opposite second bearing.

Abstract: Aspects of the subject technology relate to a robotic finger digit including a distal finger joint coupled between a distal finger part and a middle finger part, a middle finger joint coupled between the middle finger part and a proximal finger part and an extend tendon coupled at a first end to the distal finger joint, and coupled at a second end to an actuation device. In certain aspects, the robotic finger can further include a flex tendon coupled at a first end to the distal finger joint, and coupled at a second end to the actuation device, wherein the actuation device is configured to move the extend tendon and the flex tendon substantially the same distance in order to flex and/or extend the robotic finger digit.

Abstract: A robot hand which can be formed in the shape of a human hand and improves maintenance performance, and generates fingertip force is provided. A robot hand (1) of the present invention is provided with a hand section (3) and an arm section (5). The hand section (3) corresponds to the portion of a human hand which is forward from the wrist thereof. The arm section (5) is provided with a drive device (d5) including a plurality of motors and generates driving torque for driving each movable section of the hand section (3). The hand section (3) and the arm section (5) are configured in such a manner that a group (g36) of wrist-mounted pulleys which are first driving torque transmitting members coaxially arranged and a group (r5) of arm pulleys which are second driving torque transmitting members coaxially arranged transmit driving torque generated by the drive device (d5) to each movable section of the hand section (3) via gears meshing with each other.

Abstract: An NC machine tool system includes an NC machine tool (10), a first operation panel (22) and a second operation panel (24) for the NC machine tool, a multi-joint robot (40), a memory (450), and a robot controller (50). The multi-joint robot (40) is disposed above the NC machine tool. The memory (450) stores a wait position return program by which the multi-joint robot (40) is operated. The robot controller (50) controls the multi-joint robot (40) in accordance with the program. Operation panels (22, 24) are respectively provided with switch keys (22c, 24c) operated to execute the wait position return program stored in the memory (450) so as to operate the multi-joint robot (40).

Abstract: A delta robot includes a base plate and at least three drives fastened thereon, which are connected to an arm, with at least one drive connected at an opposite end relative to the arm to two rods. The rods run parallel and are connected at one end by an additional ball joint to a movable parallel plate. The two ball joints are oriented mirror-symmetrically to each other and each hollow ball segment is pressed onto a ball segment head by tensioning a permanently elastic element between two rods that are parallel to each other. The center point of a ball segment head is displaced relative to the longitudinal support axis of the rod with the direction of displacement pointing away from the hollow ball segment with the displacement always being smaller than the radius of the spherical segment head.

Abstract: A programmable robot system includes a robot provided with a number of individual arm sections, where adjacent sections are interconnected by a joint. The system furthermore includes a controllable drive mechanism provided in at least some of the joints and a control system for controlling the drive. The robot system is furthermore provided with user a interface mechanism including a mechanism for programming the robot system, the user interface mechanism being either provided externally to the robot, as an integral part of the robot or as a combination hereof, and a storage mechanism co-operating with the user interface mechanism and the control system for storing information related to the movement and further operations of the robot and optionally for storing information relating to the surroundings.

Abstract: A robotic arm includes: an arm having one or more joints; an arm securing unit provided at at least one of the one or more joints and configured to secure, by electrostatic adhesion, a positional relationship between two parts coupled by each of the at least one of the one or more joints; and a control unit configured to turn on and off the electrostatic adhesion of the arm securing unit.

Abstract: A force transmission transmits a force received by an input gimbal plate having two degrees of freedom to an output gimbal plate. The input gimbal plate is coupled to a first end of least three lever arms supported by a pivot. The output gimbal plate is coupled to a second end of the lever arms. The output gimbal plate may be coupled to the lever arms by flexible cables. The cables may be substantially contained within a tube. The output gimbal plate may be substantially smaller than the input gimbal plate. The force transmission may include a secondary output gimbal plate coupled to secondary levers that are coupled to the lever arms. The secondary levers may be third class levers. The secondary output gimbal plate may move proportionately to movement of the output gimbal plate. The force transmission may control a surgical end effector in a robotic surgical instrument.

Abstract: An multi-axis transmission includes a frame, a motor, a housing, a first output mechanism, a second output mechanism, and a output control mechanism. The motor is secured to the frame, the motor includes a rotary shaft. The housing is axially slidably attached to the frame. The first output mechanism is secured to the frame. The second output mechanism is rotatably attached to the housing. The output control mechanism is secured to the rotary shaft, the output control mechanism is selected to engage the first output mechanism to output a first movement or to engage the second output mechanism to output a second movement angular with the first moment.

Abstract: The invention relates to an industrial robot which comprises a robot arm having multiple connecting links that are connected by means of joints, in which at least two adjacent connecting links, respectively, are connected by means of a joint, which is designed as a swivel joint, can be adjusted by means of a motor and is defined in its maximum rotatable adjustment angle by means of a mechanical stop device, which connecting links comprise a stop projection which is connected to one of the two adjacent connecting links, an engaging piece which is connected to the other one of the two adjacent connecting links and a drag stop which can be adjusted by the engaging piece, which drag stop comprises a drag stop body and an annular body which is connected with the drag stop body which is pivoted in an annular groove in an inner wall of a housing component of one of the two adjacent connecting links.

Abstract: In accordance with various exemplary embodiments of the present teachings, a surgical device can include a first pair of articulably coupled links, a second pair of articulably coupled links, and a tension member coupled to the first pair of links and the second pair of links such that altering tension in the tension member exerts a force tending to articulate the first pair of links and the second pair of links so as to bend the first pair of links and the second pair of links. The surgical device can be configured such that the first pair of links has a lower resistance to bending than the second pair of links upon altering the tension in the tension member.

Abstract: A compliant mechanism includes a first unit, a second unit, at least one elastic member and a driver for driving the elastic member to rotate through a predetermined angle. The first and second units collectively define a passage about which the second unit is rotatable relative to the first unit. The elastic member has a plate and first and second shafts which are coaxially connected to two opposite ends of the plate respectively and rotatably connected with the first and second units respectively. The elastic member is rotatable about a co-axis of the first and second shafts and elastically deformable when the second unit rotates relative to the first unit. The elastic member can change its resistance to the rotation of the second unit by rotating; therefore the compliant mechanism has a great safety upon receiving load and is widely applicable in many fields.

Abstract: A substrate transport apparatus having a frame, a drive section and an articulated arm. The drive section has at least one motor module that is selectable for placement in the drive section from a number of different interchangeable motor modules. Each having a different predetermined characteristic. The articulated arm has articulated joints. The arm is connected to the drive section for articulation. The arm has a selectable configuration selectable from a number of different arm configurations each having a predetermined configuration characteristic. The selection of the arm configuration is effected by selection of the at least one motor module for placement in the drive section.

Abstract: An articulated mechanical arm includes a passive device designed to compensate for the effects of gravity on at least a first pivot connection which articulates a first member of the arm on a second member of the arm, and constitutes a first degree of freedom of the arm. The passive device includes a drive mechanism and at least one magnetic device. The drive mechanism is designed to transmit to the magnetic device any rotation of the second member relative to the first pivot connection. The magnetic device is designed to produce torque further to the rotation of the second member. The drive mechanism and the magnetic device are also designed such that the torque is retransmitted by the drive mechanism to the first pivot connection, such that the retransmitted torque cancels the moment of force caused by gravity exerted on the articulated mechanical arm, relative to the first pivot connection.

Abstract: A robotic hand includes a finger with first, second, and third phalanges. A first joint rotatably connects the first phalange to a base structure. A second joint rotatably connects the first phalange to the second phalange. A third joint rotatably connects the third phalange to the second phalange. The second joint and the third joint are kinematically linked such that the position of the third phalange with respect to the second phalange is determined by the position of the second phalange with respect to the first phalange.

Abstract: A joint structure includes a sleeve, a connecting shaft, a plurality of elastic pieces and a cross-limiting stopper. The sleeve defines a receiving shaft hole and a first cross slot communicating with the receiving shaft hole. The connecting shaft is partially assembled and received within the receiving shaft hole of the sleeve, the connecting shaft defines a second cross slot corresponding to the first cross slot. The plurality of elastic pieces is elastically received within a space formed between the sleeve and connecting shaft. The cross-limiting stopper is mounted to and partially received within the second cross slot, and partially received in the first cross slot, to enable the connecting shaft to be radially and adjustably installed within the sleeve and prevent the connecting shaft from rotating relative to the sleeve.

Abstract: A steerable multi-linked device may include a first multi-linked mechanism and a second multi-linked mechanism. At least one of the first multi-linked mechanism and the second multi-linked mechanism may include a first link, a plurality of intermediate links, a second link movably coupled to a second one of the intermediate links and a reinforcing member. A first one of the intermediate links may be movably coupled to the first link, and the reinforcing member may extend from a first end of a third one of the intermediate links toward a second end of the third one of the intermediate links.

Abstract: A joint mechanism is for a robot. The joint mechanism includes a base; a first drive device mounted on the base including a first drive shaft; a second drive device including a second drive shaft; a joint body defining a plurality of toothed grooves and a guiding groove. A sliding board mounted on first drive shaft, the sliding board slidably located in the guiding groove to guide the joint body to swing relative to the base. A gear mounted on the second drive shaft, the gear meshes with the toothed grooves; a limiting assembly for rotatably mounting the joint body on the base. When the first drive device is started, the first drive shaft is rotated to drive the joint body rotating around the first drive shaft; when the second drive device is started, the second drive shaft is rotated to drive the gear rotating so the joint body swings relative to the base.

Abstract: A power supply unit for robots and a robot having the same. The power supply unit for robots supplies power to actuators installed within an arm, and includes a housing provided with at least two lines of bus bars in an inner reception space; and at least one power unit to branch off power transmitted to the bus bars through power supply lines.

Abstract: A robot includes an arm , a wrist and a rotation support mechanism The rotation support mechanism has a shaft section provided in the wrist and an outer shape of which is a column shape; a bearing which is disposed on an outer periphery section of the shaft section and rotatably supports the shaft section around a center axis thereof; an annular-shaped ring member provided in the wrist and is concentrically disposed with the bearing by separating on the outer periphery side of the bearing; and an annular-shaped oil seal provided in the arm and slides with respect to the ring member by abutting the outer periphery section of the ring member and holding airtightness with the ring member according to the rotation of the center shaft of the shaft section.

Abstract: A clamp replacing apparatus includes a robot arm, a clamp and a connecting assembly configured for detachably connecting the clamp to the robot arm. The connecting assembly includes a first rotator and a second rotator. The first rotator is fixed to the robot arm and comprises a number of first locking portions each defining a receiving groove. The second rotator is fixed to the clamp and comprises a number of second locking portions corresponding to the first locking portions and each defining a bolt portion. The bolt portion can be received in the corresponding receiving groove or escaped from the receiving groove.

Abstract: A robot arm assembly includes a support arm, and the support arm includes a mounting base and a connecting portion defining a hollow portion. The robot arm assembly further includes a first arm, a second arm, a first input shaft, a second input shaft coaxial with and rotatable relative to the first input shaft, a first gear transmission mechanism coupled to the first input shaft to rotate the first arm, a second gear transmission mechanism coupled to the second input shaft to rotate the second arm, and a first backlash adjust mechanism to adjust the positions of the connecting portion, of the first and second input shafts relative to the mounting base, and providing the adjustment of the backlash between the first input gear pair and the second input gear pair.

Abstract: A rotational hydraulic joint may include an extension chamber and a retraction chamber. Each chamber may include an end cap and a piston that moves relative to the end cap. One or more ports may add and remove fluid from the chamber. The rotational hydraulic joint may rotate in a cyclical direction when fluid is added to the extension chamber and in a countercyclical direction when fluid is added to the retraction chamber. The chambers may each include a torus-shaped cavity. Bladders may prevent fluid from leaking out of the rotational hydraulic joint. Stationary and movable electrodes may be coupled to the end cap and piston respectively. A plurality of rotational hydraulic joints may be combined to create a compound joint.

Abstract: A ball bearing having external surfaces coated with ceramic materials is provided. The raceways of the ball bearing may advantageously be formed of metal such as stainless steel. The ceramic coating acts as an insulator increasing the resistance of the ball bearing to heat within the ball bearing environment. The balls within the raceway of the ball bearing may advantageously be coated with a lubricant to decrease friction in the ball bearing because the insulating ceramic coating prevents the environmental heat from causing the degradation of the lubricant.

Abstract: The invention relates to a manipulator (1) comprising a plurality of members (12, 14) connected to each other by joints (A1-A6) that can be adjusted by drives (M1-M6), and a counterweight device (15) associated with one of the joints (A1-A6) and comprising a rod (19) coupled to a first member (12) connected to the joint (A1-A6) on one side and connected to a spring device (26) supported on a seat (25) on the other side, said seat being coupled to a second member (14) connected to the joint (A1-A6) by means of at least one bearing arrangement (18), comprising a first bearing component (17) and a second bearing component (16) connected to the second member (14). The seat (25) is connected to the first bearing component (17) by means of at least one cantilevered arm (23, 24).

Abstract: A biomimetic mechanical joint for generating a variable torque between support members of a biomimetic robotic device, including a base support member, a rotary support member rotatably coupled to the base support member, and a variable-radius pulley operably coupled between the base support member and rotary support member. The variable-radius pulley comprises a sheave body having a variable radius and one or more tendon grooves formed in the circumferential outer surface. The mechanical joint further includes one or more flexible tendons and antagonistic actuator pairs, with each actuator pair being coupled to one or more tendons and configured to operate the tendon around the variable-radius pulley in either direction to create a variable torque between the base and rotary support members.

Abstract: A wrist housing, a wrist rotatably connected to the wrist housing, a first driver, a first transmission mechanism, a rotary member, a second driver, and a second transmission mechanism makes a robot arm assembly. The wrist housing is hollow. The first driver is assembled within the wrist housing for driving the wrist to rotate relative to the wrist housing along a first rotary axis. The first transmission mechanism is also assembled within the wrist housing and is positioned between the wrist and the first driver. The rotary member is rotatably assembled to a distal end of the wrist along a second rotary axis. The second driver is assembled within the wrist housing for driving the rotary member to rotate. The second transmission mechanism is assembled within the wrist housing, and is positioned between the second driver and the rotary member.

Abstract: A remote controlled actuator includes a spindle guide section of an elongated configuration, a distal end member fitted to a tip end of the spindle guide section for alteration in attitude, and a drive unit housing to which a base end of the spindle guide section is connected. The distal end member rotatably supports a spindle then holding a tool. The spindle guide section includes a hollow outer shell pipe, a rotary shaft and a guide pipe, and an attitude altering member for altering an attitude of the distal end member is inserted within the guide pipe. A hollow of the outer shell pipe includes a round hole portion at a center and a grooved portion depressed radially outwardly from the round hole portion. The rotary shaft is arranged within the round hole portion whereas the guide pipe is arranged within the grooved portion.

Abstract: A manipulator, such as for use in medical procedures, is provided. The manipulator includes a body and a first actuator system connected to the body at a first attachment point and capable of moving the first attachment point with at least three degrees of freedom. A second actuator system is connected to the body at a second attachment point and capable of moving the second attachment point with at least three degrees of freedom. A third actuator system is integrated with the body and is capable of moving at least a portion of the body with at least one degree of freedom.

Abstract: A robotic hand assembly comprising: a hand section comprising: at least one digit provided with at least one actuatable joint; and a control section comprising: at least one actuation device, the at least one actuation device comprising: a sensing module configured to sense a force applied to a tendon coupled at a first end to the at least one actuatable joint; and an actuation module configured to actuate the at least one actuatable joint.