Abstract: A motor control system including an input shaft connected to an output shaft of the motor and an output shaft connected to a load, the system including: a detection unit for detecting a rotation speed of the output shaft; a speed deviation generation unit generating a speed command position and calculates a speed deviation between the speed command and rotation speed of the output shaft; an angular transmission error compensation unit estimated between a rotation angle of the output shaft and of the speed reducer, and corrects the speed command, speed deviation, or rotation speed of the output shaft detected based on the event detected by the detection unit, based on the estimated angular transmission error; a current command generation unit generates a current command based on the speed deviation; and a current control unit controls a current supplied to the motor based on the current command.

Abstract: A locating beam and a robot linear motion unit having the same, wherein the locating beam comprises a first support beam and a second support beam which are parallel to each other, a crossbeam connected between the first support beam and the second support beam and is vertical to the beams, and a joints between the crossbeam and the beams is provided with a right-angle connecting piece. The robot linear motion unit includes a motion track and a transmission mechanism arranged along the extension direction of the motion track, and the motion track is arranged on a surface of the locating beam. Arranging the crossbeam and right-angle connecting pieces between the first support beam and the second support beam in the locating beam, improves the mechanical structure strength, reduces deflection deformation and twist deformation of the locating beam, and improves the impact resistance of the robot linear motion unit.

Abstract: A twin rotation driving apparatus is provided, including a base body, an axle unit pivotally connected to the base body for carrying a workpiece, a first driving unit disposed on the base body and having a first gear set connected to the axle unit and a first motor coaxially connected to the first gear set, and a second driving unit disposed on the base body and having a second gear set connected to the axle unit and a second motor coaxially connected to the second gear set. The twin rotation driving apparatus includes two motors and two gear sets. Therefore, smaller motors can be included in the twin rotation driving apparatus, and the twin rotation driving apparatus is compact and can still generate great enough torques.

Abstract: A gear transmission mechanism includes a housing, a first transmission assembly, a second transmission assembly, and a gear clearance adjustment assembly. The first transmission assembly includes an input shaft, and the second transmission assembly includes an output shaft. The gear clearance adjustment assembly includes an adjustment base mounted on the housing, fasteners, bearings, a washer, a fixing member, and a pair of freely rotatable adjusting gears for the transmission of rotative force. The adjusting gears mesh with the first and second transmission gears.

Abstract: A substrate processing system and substrate transferring method capable of transferring a substrate bi-directionally through the use of substrate transferring device provided between two rows of processing chambers arranged linearly, thereby improving the substrate-transferring efficiency, the substrate processing system includes a transfer chamber having at least one bi-directional substrate transferring device for bi-directionally transferring a substrate; and a plurality of processing chambers for applying a semiconductor-manufacturing process to the substrate, wherein the plurality of processing chambers are linearly arranged along two rows confronting each other, and the transfer chamber is interposed between the two rows of the processing chambers, wherein the bi-directional substrate transferring device have a moving unit inside the transfer chamber, and horizontally moved by a linear motor; and a bi-directional substrate transferring unit in the moving unit, the bi-directional substrate transferring u

Abstract: Devices and methods for providing power to tools when the tools are not attached to a robotic device. The power source may be an energy storage device that is attached to a tool frame of a tool cluster. The power provides for the tools to be maintained in a ready state which expedites and/or eliminates the initiation process when the tools and the tool cluster are subsequently reattached to the robotic device. This reduces the time necessary for the tools to be used in the assembly process thereby increasing the efficiency of the tooling system.

Abstract: The invention concerns a flexible transmission (1 and 1?) intended to be disposed between a motor member imposing a rotation movement and a receiving member receiving the rotation movement via the flexible transmission, the transmission comprising a flexible sheath (2) in which a flexible shaft (3) extends, bearings (4) with rolling elements being regularly interposed between the flexible sheath and the flexible shaft to guide the latter in rotation in the flexible sheath. The invention also concerns robotic arms provided with such a flexible transmission, and a cable actuator having a motor offset using such a flexible transmission.

Abstract: A motorized joint having two degrees of freedom in rotation connecting two elements is provided. The joint includes two pivot connections such that a first one of the pivot connections establishes a first pivot axis, and a second one of the pivot connections establishes a second pivot axis. The first pivot axis is not parallel to the second pivot axis. A first motor is disposed in fixed relation to a first one of the two elements and has a drive shaft aligned with a first drive axis so as to cause by means of a first speed reducer with parallel axes the two elements to rotate about the first pivot axis.

Abstract: A joint driving device includes: a reduction gear output shaft that transmits a torque to a second link; a transmission shaft that transmits reaction of the torque to a first link; a transmission shaft outer cylinder arranged on the outer circumference of the transmission shaft and connected to the transmission shaft; a reduction gear output shaft outer cylinder arranged in the outer circumference of the reduction gear output shaft and connected to the reduction gear output shaft; and a wire body arranged between the first link and the second link and including at least one of a wire and a pipe. The transmission shaft includes the motor frame as at least a part. The wire body is housed in a space between the transmission shaft outer cylinder and the transmission shaft, and a space between the reduction gear output shaft outer cylinder and the reduction gear output shaft.

Abstract: A structure with six degrees of freedom for a robot or haptic interface including a base, two branches in parallel, and a wrist joint. The branches are installed articulated between the base and the wrist joint, the branches including a shoulder, an arm, and a forearm supporting the wrist joint. The wrist joint includes a connecting segment onto which a handle holder is articulated about a first rotation axis. A handle is articulated in rotation on the handle holder about a second rotation axis, the handle capable of being moved in rotation about the first axis, the second axis, and a third axis, and a mechanism gears down the rotation of the handle holder about at least the first rotation axis relative to rotation of the connecting segment.

Abstract: A plurality of interconnected phalanges form robotic fingers configured to grasp an object. The phalanges interact with a resilient compliant element for adjustable resilient cushioning of movement of the phalanges.

Abstract: A robot according to embodiments includes a first link, a second link, an actuator, a scissors gear, and a support part. The second link is rotatably connected to the first link. The actuator drives the second link in a rotatable manner. The scissors gear includes a main gear and a sub gear, and outputs driving force from the actuator to the second link. The support part is attached to the first link and rotatably supports the scissors gear. Furthermore, the scissors gear includes a spring that is arranged adjacent to the support part in the direction of the rotational axis of the scissors gear and applies biasing force to the main gear and the sub gear in rotational directions different from each other.

Abstract: Compact robot with a reduced operational envelope includes a support frame, two robot arm assemblies, and two actuating mechanisms. The support frame includes a top plate and a bottom plate. Each robot arm assembly includes a first arm, a second arm intersecting with the first, and a third arm intersecting with the second. The first arm drives the second arm to move along the first arm, the second arm drives the third arm to move along the second arm. The actuating mechanisms are coupled to the two third arms. Each third arm drives an actuating mechanisms to move along the third arm. A moving direction of each actuating mechanism as driven by the third arm is inclined relative to the driving directions of the first arm and the second arm.

Abstract: A robot according to embodiments includes a speed reducer, a first shaft, a rotary electric machine, a second shaft, and a brake. The speed reducer reduces and outputs rotation to be input into an input unit. The first shaft is connected to the input unit. The rotary electric machine rotates the first shaft. The second shaft is connected to the input unit. The brake regulates the rotation of the second shaft.

Abstract: Designs for modular microsurgical robotic devices and systems are provided, which could include one or multiple master-slave units coupled to a central microscope-based suspension structure. One of the main objectives is to provide robotic assistance during tasks which require long-term user concentration and high precision. The microsurgical robotic devices pay attention to motion scaling and tremor filtration in a 6 Degrees-of-Freedom (DOF) master-slave setup with force feedback. An extra DOF is included to actuate a 1-DOF instrument tip. Embodiments of this invention can be used in the medical environment as well as in other areas such as printed circuit board repair, watch and jewelry making, laboratory tasks, or other areas which require high precision over extended periods of time.

Abstract: Provided herein is a robot using a multi-output differential gear, the robot comprising a driver; a differential gear configured to receive a driving power from the driver, and to drive in an interlocked manner with the driving power to generate at least three outputs differentiated from the driving power; and a motion section configured to drive in an interlocked manner with an output generated from the differential gear, and to apply an external resistance to the differential gear.

Abstract: The present invention provides a locating beam and a robot linear motion unit having the same. The locating beam comprises a first support beam (11) and a second support beam (12) which are parallel to each other, wherein a crossbeam (13) is connected between the first support beam (11) and the second support beam (12) and is vertical to the beams (11, 12), and each of the joints between the crossbeam (13) and the beams (11, 12) is provided with a right-angle connecting piece (15). The robot linear motion unit comprises a motion track and a transmission mechanism arranged along the extension direction of the motion track, wherein the motion track is arranged on a surface of the locating beam.

Abstract: A joint unit pivotably coupled to a tip end part of a main arm member of a Scott Russell mechanism is pivoted in two ways. A Scott Russell mechanism device pivotably couples a main arm member and a sub arm member to each other, as well as it pivotably couples a joint unit to a tip end part of the main arm member. Moreover, by providing a pivot driving unit to the main arm member, as well as providing a fourth motor and a drive transmission mechanism unit to the sub arm member, the Scott Russell mechanism device can switch between pivoting the joint unit associatively a change of a coupling angle of the arm members and and pivoting the joint unit by the drive of the fourth motor.

Abstract: A gear transmission mechanism includes a housing, a first transmission assembly, a second transmission assembly, and a gear clearance adjustment assembly. The first transmission assembly includes an input shaft, and the second transmission assembly includes an output shaft. The gear clearance adjustment assembly includes an adjustment base mounted on the housing, fasteners, bearings, a washer, a fixing member, and a pair of freely rotatable adjusting gears for the transmission of rotative force. The adjusting gears mesh with the first and second transmission gears.

Abstract: A harmonic speed reducer for robots is provided with a frame, an annular circular spline, a cylindrical flexspline, and an elliptical wave generator. The frame has internal threads each tapped parallel to the center axis line, the threads each extending from a circular spline mounting seat to the inside of the frame. The internal thread in the circular spline mounting seat has a peripheral edge portion at an opening thereof with a recess. The recess is formed so as to have a diameter larger than a diameter of the internal thread.

Abstract: A robot arm assembly includes a first arm, a second arm; a first transmission assembly and a second transmission assembly. The first transmission assembly includes a first rotation shaft having a first bevel gear portion, a second rotation shaft having a second bevel gear portion engaging with the first bevel gear portion, and a third rotation shaft non-rotatably connected to the second rotation shaft. The second transmission assembly includes a forth rotation shaft and a fifth rotation shaft. The forth rotation shaft is rotatably sleeved on the first rotation shaft and includes a forth bevel gear potion. The fifth rotation shaft is rotatably sleeved on the second rotation shaft and includes a fifth bevel gear portion engaging with the forth bevel gear portion. An end of the fifth rotation shaft opposite to the fifth bevel gear portion is connected to the second arm.

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 traction drive system for an articulated robotic arm. The traction drive system can include an input drive disk, a spider, an array of traction balls, a traction plate, an output drive shaft, a clamping device to load the traction balls, and an absolute rotation position sensor system. The rotation of the output drive shaft can be coupled to the rotation of the input drive disk while the traction balls are frictionally engaged to the drive disk surface and traction plate surface. The rotational connection can be decoupled when the traction balls are not frictionally engaged to the drive disk surface and traction plate surface. A rotational position sensor located in proximity to the traction drive can provide absolute rotational position feedback of the output drive shaft.

Abstract: An apparatus applies a wear coating on the interior surface of conduits, particularly conduit elbows, in which the weld head applying a weld bead forming the wear coating is supported by a wheel engaging the bottom surface of the conduit and interconnected with a push/pull cart mounted on a linear support frame exteriorly of the conduit by a plurality of linkage elements. Each of the head element and the linkage elements include a centralizing joint having a pair of transversely opposing rollers that engage the lateral sides of the conduit to maintain a consistent positioning of the welding arm at the distal end of the apparatus. The welding arm includes a three-axis adjustment for the welding torch tip for accurate location thereof within the conduit. Positional adjustment of the welding torch tip is provided by independent electric motors associated with each pivot axis in the welding arm.

Abstract: A robot arm system includes a support base, a first robot arm, a first driving mechanism, a second robot arm, a second driving mechanism, and a wrist assembly. The first driving mechanism drives the first robot arm to rotate around the first rotation axis. The second driving mechanism drives the second robot arm to rotate around the second rotation axis. The robot arm system further comprises a first wheel positioned on the support base, a second wheel positioned on the second robot arm, a third wheel positioned on the wrist assembly and rotatably connecting to the second robot arm, a first flexible belt connecting the first wheel with the second wheel, and a second flexible belt connecting the third wheel with the second wheel. The first wheel, the second wheel, and the third wheel have the same radius.

Abstract: A link mechanism arranged between a fixed base and a movable base. The mechanism includes a drive gear reducer, a first arm, a second arm, a connection base, a first link, and a second link. The drive gear reducer includes a body, an input shaft, a first output shaft, and a second output shaft. The first arm is connected to the fixed base and the body of the reducer. The second arm is connected to the second output shaft and the movable base. The connection base is arranged such that the second arm is between the connection base and the reducer, the connection base is connected to the first output shaft. The first link is connected to the fixed base and the connection base. The second link is connected to the connection base and the movable base.

Abstract: A gear backlash adjusting mechanism includes a base, a first gear, a first elastic gear meshing with the first gear, a bearing sleeved on the first gear, and a bearing box over the bearing, and mounted on the base. The first elastic gear includes an outer ring, an inner ring, and an elastic member mounted between the outer ring and the inner ring. The position of the bearing box relative to the base can be adjusted, to push the first elastic gear via the first gear. The elastic member is deformed and provides elastic force to push the first elastic gear to tightly mesh with the first gear.

Abstract: A robot arm assembly includes a supporting arm, first and second mechanical arms, a first driving member, a second driving member, a first transmission mechanism between the first mechanical arm and the first driving member, and a second transmission mechanism between the second mechanical arm and the second driving member. The first driving member drives the first transmission mechanism to rotate the first mechanical arm. The second driving member drives the second transmission mechanism to rotate the second mechanical arm. The first driving member and the second driving member are both carried in the supporting arm and are arranged side by side.

Abstract: A robot arm assembly includes a receiving box, a hollow tube, a first output shaft, and a first driving mechanism. The receiving box defines an assembling hole and a through hole. The hollow tube is assembled within the receiving box with two ends of the hollow tube aligning with the assembling hole and the through hole, respectively. The first output shaft is hollow, and rotatably assembled to the receiving box. The first output shaft is coaxial with the assembling hole of the receiving box and defines a cable passage cooperatively with hollow tube. The first driving mechanism is assembled within the receiving box and is connected with the first output shaft, to drive the first output shaft to rotate relative to the receiving box.

Abstract: A robot arm (50) of the present invention includes, as a direct acting extensible/retractable joint (J3), an arm section (2) constituted by an upper structure group (20) and a lower structure group (21). Groups (20) and (21), having an arrangement in which structures are connected in series, partially engage so as to form a direct rigid combined structure, and are separated so as to release the rigid structure. An arm length can be adjusted arbitrarily. Section (2) can have a plane surface having no gap to prevent entry of a finger/dust. Separation of Groups (20) and (21) allows an upper structure (22) and a lower structure (23) to rotate around their rotational axes, to realize compact storage inside a robot arm supporting member (1). It is thus possible to prevent significantly entry of a finger/dust, and provide a compact direct acting extensible and retractable arm mechanism.

Abstract: A link mechanism arranged between a fixed base and a movable base. The mechanism includes a drive gear reducer, a first arm, a second arm, a connection base, a first link, and a second link. The drive gear reducer includes a body, an input shaft, a first output shaft, and a second output shaft. The first arm is connected to the fixed base and the body of the reducer. The second arm is connected to the second output shaft and the movable base. The connection base is arranged such that the second arm is between the connection base and the reducer, the connection base is connected to the first output shaft. The first link is connected to the fixed base and the connection base. The second link is connected to the connection base and the movable base.

Abstract: A robot according to an aspect of embodiments includes a motor and a hypoid gear. The motor is provided in a robot arm. The hypoid gear transmits the driving force of the motor to a leading-edge arm coupled to the robot arm to swing the leading-edge arm or to rotate an end effector.

Abstract: A robot includes a first shaft housing, a second shaft housing rotatably assembled to the first shaft housing, a driver, a cable assembly, a transmission mechanism and a cable pass-through assembly. The driver is assembled within the first shaft housing for driving the second shaft housing to rotate relative to the first shaft housing. The cable pass-through assembly is assembled within the second shaft housing and defines a cable passage hole coaxial with the second shaft housing. The cable assembly passes through the cable passage hole of the cable pass-through assembly and electronically connects with the driver. The transmission mechanism is sleeved on the cable pass-through assembly for transmitting the driving force generated by the driver to the second shaft housing, thereby driving the second shaft housing to rotate relative to the first shaft housing.

Abstract: An industrial robot with a gear transmission mechanism is disclosed. The industrial robot comprises a base; a robot arm assembly rotatably connected to the base; the robot arm assembly comprising a gear box; a first driving member positioned on the gear box, the first driving member having a first driving shaft; a first transmission mechanism positioned in the gear box, wherein the first transmission mechanism has at least two gears meshing with each other and a fixed shaft fixed to the base, one of the at least two gears is connected to the first driving shaft, and another one of the at least two gears is rotatably sleeved on the fixed shaft, and fixed to the gear box.

Abstract: A robot according to embodiments includes a speed reducer, a first shaft, a rotary electric machine, a second shaft, and a brake. The speed reducer reduces and outputs rotation to be input into an input unit. The first shaft is connected to the input unit. The rotary electric machine rotates the first shaft. The second shaft is connected to the input unit. The brake regulates the rotation of the second shaft.

Abstract: An industrial robot may include a main body section, a first arm, a second arm, a third arm, a first speed reducer which connects the main body section and the first arm a second speed reducer which connects the first arm and the second arm, and a connecting mechanism which connects the input shaft of the first speed reducer and the input shaft of the second speed reducer, and a second drive motor which drives the third arm. The speed reduction ratio of the first and second speed reducer are set such that the movement loci of a third articulation section which connects the second and third arm are rectilinear. The connecting mechanism connects the input shafts predetermined speed ratio. The second drive motor is mounted on the second arm closer to the tip than where a third articulation section is located.

Abstract: A robot for virtual reality experience, in which a settling body for a user is moved in multidirectional according to operation states of first and second moving units and first and second crank motors. The settling body creates various moving directions according to the operation states of the first and second moving units and the first and second crank motors, and each magnitude of forces applied to each moving direction is changed, thereby forming the various waveforms.

Abstract: A robot arm includes a circular rack, an elongated first mounting member attached to the rack, and a second mounting member attached to the first mounting member. The first mounting member extends in a radius direction of the rack and moves in a circular trace along the rack. The second mounting member slides relative to the first mounting member along the radius direction, thereby defining a polar coordinate system in a plane defined by the rack to allow the second mounting member to flexibly locate at any desired positions in the plane.

Abstract: A robot arm for an industrial robot, including a first arm part and a second arm part, where the second arm part is rotatably journalled in the first arm part for rotation about a first axis of rotation, characterized in that the second arm part includes a tubular member, rotatably journalled in the first arm part, so that the tubular member is configured to support the robot arm.

Abstract: A speed reducer includes a ring gear having internal gear teeth, a revolving gear meshing with the ring gear, an eccentric cam relatively rotatably provided in a center of the revolving gear, a first rotating shaft in the eccentric cam, the first rotating shaft driving the revolving gear by rotating the eccentric cam, a through pin inserted into a through hole in the revolving gear, a second rotating shaft connected to the through pin and outputting rotation obtained by the rotation of the revolving gear, and an elastic section between the through hole and the through pin, the elastic section having a greater area of contact with the through pin than with the through hole.

Abstract: A robot arm assembly includes a turret, a lower arm pivotable with respect to the turret, and an upper arm pivotable with respect to the lower arm.

Abstract: A robot arm has a drive gear that has a shaft, a gear frame being capable of turning about the shaft of the drive gear, a first follower gear being capable of turning, in synchronization with the drive gear, about a shaft fixed to the gear frame, in a direction opposite to the turning direction of the drive gear, a transmission control mechanism that is capable of locking the first follower gear to the drive gear, an arm that moves in synchronization with the first follower gear, and a collision detection unit that is capable of detecting a collision between the arm and an obstacle. The transmission control mechanism unlocks the follower gear from the drive gear in response to detection, by the collision detection unit, of a collision between the arm and the obstacle. The robot arm enables quick cushioning of the impact force of the collision.

Abstract: A light-weight, compact, highly dexterous surgical robot system for performing in vivo minimally invasive surgeries that allows precise control of position and orientation of surgical tools. The surgical robot system has three rotational degrees of freedom and one translational degree of freedom and is composed of seven links joined by three gear pairs and six turning pairs. The surgical robot system maintains an open space where a surgical tool element enters the patient to avoid self-collisions within the robot system during surgeries.

Abstract: Through holes are formed in a revolving gear which revolves while being engaged with a ring gear, and penetration pins for extracting rotation of the revolving gear are inserted in the through holes. The inner circumference of each through hole has a shape which becomes narrow toward its one end. A sliding member having a shape which becomes thin toward its one end is engaged with each penetration pin. The sliding member is biased in a tapered direction thereof by a biasing member to be in contact with the inner circumference of the through hole.

Abstract: Through holes are formed in a revolving gear which revolves while being engaged with a ring gear, and penetration pins on which ring members of a circular ring shape are mounted outside are inserted in the through holes. Further, the ring member is mounted to the penetration pin through an elastic member.

Abstract: Through holes are formed in a revolving gear which revolves while being engaged with a ring gear, and penetration pins are inserted in the through holes. An elastic member having a circular ring shape, which is formed so that an inner diameter thereof can move with respect to an outer diameter thereof, is mounted to either an inner circumferential surface of the through hole or an outer circumferential surface of the penetration pin. Thus, the through hole and the penetration pin do not interfere with each other, and thus, it is possible to set a small clearance between the through hole and the penetration pin to such a degree, while preventing a speed reducer from being in a locked state due to interference. As a result, it is possible to suppress a backlash between the through hole and the penetration pin.

Abstract: Through holes are formed in a revolving gear which revolves while being engaged with a ring gear, and penetration pins which are configured to extract rotation of the revolving gear are inserted in the through holes. The ring gear and the revolving gear are divided into halves in the thickness direction. Two sheets of ring gears are biased to rotate in reverse directions.

Abstract: Disclosed herein are embodiments of an articulated robot wrist which can comprise a first body comprising a first and a second end, said first end being intended to be mounted on a robot component that is rotatable around a first axis; a second body comprising a first and a second end, said first end being rotatably mounted on said second end of said first body, around a second axis inclined with respect to said first axis; and a third body comprising a first and a second end, said first end being rotatably mounted on said second end of said second body, around a third axis inclined with respect to said second axis, wherein said first and third axes are both substantially orthogonal to said second axis, and wherein in at least one position of said robot wrist said first and third axes are substantially aligned with each other.

Abstract: Disclosed herein are embodiments of an articulated robot wrist. One embodiment comprises a first body comprising first and second ends, the first end being for mounting on a robot component which is rotatable around a first axis; a second body comprising first and second ends, the first end being rotatably mounted on said second end of said first body around a second axis inclined with respect to said first axis; and a third body comprising a first and a second end, the first end being rotatably mounted on said second end of said second body around a third axis inclined with respect to said second axis. The first and third axes form an angle substantially of 90° with respect to said second axis, and wherein in at least one position of said robot wrist said first and third axes are substantially aligned with each other.

Abstract: Disclosed herein are embodiments of an articulated robot wrist, which can comprise a first body comprising a first and a second end, said first end being intended to be mounted on a robot component that is rotatable around a first axis; a second body comprising a first and a second end, said first end being rotatably mounted on said second end of said first body, around a second axis inclined with respect to said first axis; and a third body comprising a first and a second end, said first end being rotatably mounted on said second end of said second body, around a third axis inclined with respect to said second axis. The first and third axes are both substantially orthogonal to said second axis, and wherein in at least one position of said robot wrist said first and third axes result substantially aligned with one another.