Abstract: A leg mechanism of a humanoid robot includes: an upper leg, a lower leg rotatably coupled to the upper leg, a knee module actuator mounted to the upper leg, a foot rotatably connected to the lower leg, a knee transmission mechanism connected to the knee module actuator and the lower leg and configured to transmit rotary motion from the knee module actuator to the lower leg, at least one ankle module actuator mounted to the upper leg, at least one ankle transmission mechanism connected to the at least one ankle module actuator and the foot and configured to transmit rotary motion from the at least one ankle module actuator to the foot.

Abstract: A constant velocity (CV) joint system include a CV joint assembly with a first elongated ring pivotally attached to a second elongated ring via a first rotating housing and a second rotating housing, the first rotating housing and the second rotating housing being configured to rotate along a first axis; a third elongated ring pivotally attached to a fourth elongated ring via a third rotating housing and a fourth rotating housing, the third rotating housing and the fourth rotating housing being configured to rotate along a second axis; a first sliding support; and a second sliding support. The first sliding support includes a first elongated opening; and a second elongated opening, the first elongated opening extending in a direction relatively perpendicular to the second elongated opening. The second sliding support includes a third elongated opening and a fourth elongated opening, the third elongated opening extending in a direction relatively perpendicular to the fourth elongated opening.

Abstract: The invention is concerning a robotic arm that features several consecutive mobile links and motors associated with axes relative to one another for the moving of the links. At least one of the links is selectively mountable in at least two configurations relative to its adjacent links.

Abstract: Provided is an in-pipe inspection robot which moves along a path in a pipe to inspect suspected areas such as cracks in the pipe. An in-pipe inspection robot in accordance with an exemplary embodiment of the present invention has a configuration in which two or more operating units having a plurality of arms, which move forward and backward in a radial direction of a pipe, are connected to each other to move in a straight direction or to be bent relative to each other by means of a flexible link mechanism.

Abstract: A head structure of a robot according to the invention includes a first motor and a second motor so supported side by side within a head of the robot that output shafts are positioned coaxially with each other; a left elastic frame that is so driven by the first motor and one end of which is so fitted as to be rotatable around the output shaft and the other end of which extending in a perpendicular direction from the output shaft is supported by a trunk of the robot; and a right elastic frame that is so driven by the second motor and one end of which is so fitted as to be rotatable around the output shaft and the other end of which extending side by side with the left elastic frame from the output shaft is supported by the trunk.

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 parallel robot includes a movable-section drive mechanism, and a wrist-section drive mechanism. The wrist section includes a first rotary member supported on the movable section and rotatable about a fourth rotation axis different from axes of the three-axis translational motion of the movable section, a second rotary member connected to the first rotary member and rotatable about a fifth rotation axis orthogonal to the fourth rotation axis, and a third rotary member connected to the second rotary member and rotatable about a sixth rotation axis orthogonal to the fifth rotation axis. The third rotary member is provided with an attachment surface to which a tool is attached. The attachment surface is inclined with respect to the sixth rotation axis at a predetermined angle.

Abstract: A robot arm assembly includes a first robot arm, a second robot arm, and a third robot arm. The first robot arm includes a first body and a backlash adjusting assembly received in the first body. The backlash adjusting assembly includes a base plate, a protruding shaft perpendicularly coupled to the base plate, and an adjusting member. The base plate defines a slotted hole. The adjusting member is detachably inserted into the slotted hole and is detachably coupled to first body. The second robot arm includes a second body and a first transmission assembly rotatably coupled to the second body. The first transmission assembly includes a first adjusting gear, a first intermediate gear, and a second adjusting gear. The first intermediate gear meshes the first and second adjusting gear. The second adjusting gear is coupled to the second body. The first intermediate gear is sleeved on the protruding shaft.

Abstract: A parallel mechanism with three-dimensional translation and one-dimensional rotation include a fixing rack, a mobile platform and four chains of the same structure which are symmetrically set between the fixing rack and the mobile platform. Each chain has a near rack rod and two parallel far rack rods. The mobile platform includes a main platform and an assistant platform connected by a revolute joint and perpendicular to each other. Each end of the main platform and the assistant platform is connected with a corresponding lower connecting shaft separately.

Abstract: A robot includes a base, an arm portion, and a wrist portion with a multi-joint structure. The wrist portion includes a first wrist element, a second wrist element, a third wrist element, a first bevel gear set, and a second bevel gear set. The first wrist element is supported around a first axis line orthogonal to a longitudinal direction of the wrist portion. The second wrist element is supported swingably around a second axis line orthogonal to the longitudinal direction of the wrist portion. The third wrist element is supported rotatably around a third axis line along the longitudinal direction of the wrist portion. The first bevel gear set is configured to reduce a rotation speed of a first driving motor driving the first wrist element. The second bevel gear set is configured to reduce a rotation speed of a second driving motor for driving the second wrist element.

Abstract: This disclosure discloses a multijoint robot. The multijoint robot has a plurality of link members and a plurality of joints. At least one of the plurality of joints includes a double joint structure comprising a first link member, an intermediate link member connected to the first link member rotatably around a first joint axis, and a second link member which is connected to the intermediate link member rotatably around a second joint axis and in which two small link members are connected capable of relative rotation around a rotating axis along a longitudinal direction of the link member.

Abstract: A robot arm assembly with tubes or pipes carrying fluids or electrical cables which do not get bent and are relatively straight, and are not disrupted by, the moving parts of the robot arm includes a first robot arm, a second robot arm, a third robot arm, and a flexible carrying tube. The second robot arm includes a first axle base, a first input shaft, a first bevel gear, and a second bevel gear. The flexible tube is inserted into the first bevel gear and the second bevel gear along a first axis, and fixed to the output shaft.

Abstract: A workpiece turning-over device includes a support base and two moving arm assemblies oppositely positioned on the support base. Each moving arm assembly includes a rotation member on the support base, a moving arm connected to the rotation member, a spur gear pair, and a bevel gear pair. The spur gear pair includes a first spur gear fixedly sleeved on the moving arm, and a second spur gear rotatably connected with the rotation member and meshing with the first spur gear. The bevel gear pair includes a first bevel gear non-rotatably connected with the rotation member, and a second bevel gear non-rotatably connected with the second spur gear and meshing with the first bevel gear. The two rotation members are rotated in opposite directions.

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: A robotic arm assembly includes a first segment, a second segment, a first driving device, a first transmission mechanism, a second driving device, and a second transmission mechanism. The second segment is rotatably connected to the first segment. The first driving device drives the second segment to rotate about a first axis relative to the first segment via the first transmission mechanism. The second transmission mechanism includes a first bevel gear and a second bevel gear meshed with the first bevel gear. An output shaft is fixed to the second bevel gear, and the output shaft is capable of rotating about a second axis. Each of the second segment, the output shaft, and the second bevel gear defines a guiding hole, and the guiding holes are aligned in the second axis.

Abstract: A robot arm assembly includes a first, a second, and a third hollow arm, a fourth arm, and a first, a second, and a third transmission. The second arm is rotatably connected to the first arm, the third arm is rotatably connected to the second arm, the fourth arm is rotatably connected to the third arm. The first transmission sub-assembly is rotatably received in the first arm. The second transmission sub-assembly is rotatably received in the first arm and the second arm. The third transmission sub-assembly is rotatably received in the first arm, the second arm, and the third arm, and fixedly connected to the fourth arm. The first arm, the second arm, the third arm, and the fourth arm are capable of rotating around a first axis, a second axis, a third axis, and a fourth axis respectively.

Abstract: A robot arm assembly includes a base, a first arm rotatably connected to the base, a second arm rotatably connected to the first arm, a third arm rotatably connected to the second arm, a first driving mechanism, a second driving mechanism, and a third driving mechanism. The first driving mechanism includes a first driving member mounted on the base for driving the first arm. The second driving mechanism includes a second driving member mounted on the base and a first transmission shaft securely connected to the second driving member for driving the second arm. The third driving mechanism includes a third driving member mounted on the base and a second transmission shaft securely connected to the third driving member for driving the third arm. The first and second transmission shafts are placed inside the first arm substantially symmetrically with each other about an axis of the first arm.

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 first mechanical arm, a second mechanical arm, a third mechanical arm, a first transmission assembly and a second transmission assembly. The first mechanical arm, the second mechanical arm and the third mechanical arm are rotatably connected together in that order, and are respectively configured to rotate along a first axis A, a second axis B and a third axis C. The first transmission assembly is assembled within the first mechanical arm and the second mechanical arm, and is further coupled with the third mechanical arm. The second transmission assembly is assembled within the first mechanical arm and sleeved on the first transmission assembly, the second transmission assembly is further coupled with the second mechanical arm.

Abstract: A robot arm assembly includes a first robot arm and a second robot arm rotatably connected to the first robot arm. The first robot arm includes a first sleeve, a first input shaft, and a second input shaft. The first input shaft and the second input shaft are seated in the first sleeve. The second robot arm includes a second sleeve and an output shaft received in the second sleeve. The first input shaft is connected to the second sleeve via a pair of bevel gears, and drives the second sleeve to rotate relative to the first sleeve. The second input shaft is connected to the output shaft via at least two pairs of bevel gears, and drives the output shaft to rotate relative to the second sleeve.

Abstract: A robot arm assembly includes a first arm, a second arm and a third arm. The first arm includes a main body, a pivotal portion perpendicularly connected to the main body, a first transmission mechanism and a first reducer. The second arm includes a fixing portion, a second transmission mechanism, a first connecting portion and a second connecting portion extending from opposite ends of the fixing portion. The first connecting portion and the second connecting portion are connected to opposite ends of the pivotal portion, the second transmission mechanism is connected to the first transmission mechanism. The third arm includes an output flange, a second reducer connected to the output flange and a transmission bevel gear. The transmission bevel gear is fixed to the input end and engages with the second transmission mechanism.

Abstract: A robot arm mechanism includes a drive arm, a support arm, a transmission assembly and three tool portions. The support arm is rotatably connected to the drive arm. The three tool portions are rotatably mounted on the support arm. The transmission assembly includes a first bevel gear, a second bevel gear and a transmission belt. The first bevel gear is mounted on the drive arm, the second bevel gear is mounted on the support arm and engages with the first bevel gear. The transmission belt is driven by the second bevel gear and imparts rotary motion to the plurality of tool portions simultaneously.

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 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: 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: A robot arm includes a support, a wrist joint rotatably connected to the support, a distal joint rotatably connected to the wrist joint, a first driving mechanism driving the wrist joint, and a second driving mechanism driving the distal joint. The first driving mechanism comprises a first input shaft connected to the wrist joint via two bevel gears, and the first driving mechanism drives the wrist joint to rotate relative to the support. The second driving mechanism comprises a second input shaft connected to the distal joint via at least four bevel gears, and the second driving mechanism drives the distal joint to rotate relative to the wrist joint. The robot arm is sealed and defines a conduit for allowing a plurality of pipes and cables to pass through.

Abstract: A robot arm assembly includes a hollow 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. 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 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 robotic arm assembly includes a support body, a first segment, a second segment, a first driving device, a second driving device, a first bevel gear, a second bevel gear, a third bevel gear, a first transmission mechanism, and a second transmission mechanism. The first segment is rotatably connected to an end of the support body. The second segment is rotatably connected to the first segment. The first driving device and the second driving device are received in the support body. The first bevel gear and the second bevel gear are rotatably sleeved on opposite ends of the first segment, and mesh with the third bevel gear fixed to the second segment. The first transmission mechanism transmits the power of the first driving member to the first bevel gear, and the second transmission mechanism transmits the power of the second driving member to the second bevel gear.

Abstract: A parallel robot including a movable-section drive mechanism having a parallel mechanism configuration and operating to allow a movable section to perform a three-axis translational motion with respect to a base section, and a wrist-section drive mechanism operating to allow a wrist section to perform a three-axis orientation-changing motion with respect to the movable section. The wrist section includes a first rotary member supported on the movable section and rotatable about a fourth rotation axis different from axes of the three-axis translational motion of the movable section, a second rotary member connected to the first rotary member and rotatable about a fifth rotation axis orthogonal to the fourth rotation axis, and a third rotary member connected to the second rotary member and rotatable about a sixth rotation axis orthogonal to the fifth rotation axis. The third rotary member is provided with an attachment surface to which a tool is attached.

Abstract: A robot includes an articulation mechanism that includes a pair of opposing bevel gears, a pair of motors that rotate the pair of opposing bevel gears independently of each other, an output bevel gear that is engaged with each of the pair of opposing bevel gears and is supported so as to be rotatable and so as to be swingable in rotational directions of the pair of opposing bevel gears, and an output body that is secured to the output bevel gear, a cover-and-support structure that is a supporting member and functions as a cover covering the outside of the entirety of the articulation mechanism, and a swing mechanism that supports the cover-and-support structure such that the cover-and-support structure is swingable in the rotational directions of the pair of opposing bevel gears.

Abstract: A self-propelled programmable steerable robot (10) useful for cleaning a submerged surface of a swimming pool or tank, said robot comprising, a body member (11), a drive (40) included in the body member for rotatably driving a first shaft (53). A transmission (50) is also included in the body member, said transmission including said first shaft and said first shaft having fixed thereon in a spaced-apart opposed manner first and second beveled gears (55a, 55b). A second shaft (31) is positioned in orthogonal relationship to said first shaft, said second shaft having fixed thereon a third beveled gear (56) at a point on said second shaft so as to be able to alternately mesh with a selected one of said first and second beveled gears of said first shaft depending on the physical position of said second shaft.

Abstract: A robot arm assembly includes a first robot arm and a second robot arm; the second robot arm is rotatably connected to the first robot arm. The first robot arm includes a first sleeve, a first input shaft, and a second input shaft. The first input shaft and the second input shaft are seated in the first sleeve. The second robot arm includes a second sleeve and an output shaft; the output shaft is received in the second sleeve. The first input shaft is connected to the second sleeve via a pair of bevel gears, and drives the second sleeve to swing relative to the first sleeve. The second input shaft is connected to the output shaft via a plurality of bevel gears meshing with each other, and drives the output shaft to rotate relative to the second sleeve.

Abstract: A robot arm assembly includes a support member, a first rotating member rotatably connected to the support member, a second rotating member rotatably connected to the first rotating member, and a driving mechanism to drive the first rotating member. The driving mechanism includes a gear transmission mechanism directly coupled to the first rotating member, a driver mounted on the support member and provided with an output shaft coupled to the gear transmission mechanism, and a support mechanism supporting the gear transmission mechanism.

Abstract: A device for adjusting the backlash in bevel gears in an industrial robot which includes a first conical gear wheel with a first axis of rotation and a second conical gear wheel. The device includes a displaceably arranged holder member adapted to fix and rotatably journal the first gear wheel for rotation about the first axis of rotation.

Abstract: A robot with a body, at least one leg on each side of the body, and a hip connecting the leg to the body. The hip is configured to abduct and adduct the leg. A linkage is configured to rotate the leg along a predetermined path.

Abstract: A robotic joint configured as a 3-axis joint configured with a shoulder or other human joint form factor. The joint includes a first link made up of a block attaching to a torso and a stationary electric actuator assembly mounted to the block. A second link is connected to the first link to rotate about a first axis and be driven by the actuator assembly. A third link is attached to the second link to rotate about a second axis orthogonal to the first axis when the third link is driven by the actuator assembly. A fourth link is connected to the third link to rotate about a third axis orthogonal to the second axis when the fourth link is driven by the actuator assembly. The actuator assembly includes three electric motors with threaded drive capstans driving pulleys in the links while being spaced apart from the rotating links.

Abstract: A device for adjusting the backlash in bevel gears in an industrial robot which includes a first conical gear wheel with a first axis of rotation and a second conical gear wheel. The device includes a displaceably arranged holder member adapted to fix and rotatably journal the first gear wheel for rotation about the first axis of rotation.

Abstract: A robot mechanism adopts a dry cleaning method to clean the surface of live-line insulators without: using water and can perform cleaning and inspection of the surface of the live-line insulators while automatically moving along an insulator string. The robot mechanism includes a main unit having upper and lower wing frames connected with each other by a connecting bracket to surround the insulator string, a cleaning unit disposed between the upper and lower wing frames and including a base frame to perform dry cleaning with a rotational brush and a CM guide, a lift unit including a clamp and a ball-bearing screw to move the main unit up or down, and an inspection unit to electrically inspect the insulators; and a coupling unit to couple a pair of the main units to allow the pair of main units to move along a tension insulator string or a suspension insulator string.

Abstract: A robotic joint configured as a 3-axis joint configured with a shoulder or other human joint form factor. The joint includes a first link made up of a block attaching to a torso and a stationary electric actuator assembly mounted to the block. A second link is connected to the first link to rotate about a first axis and be driven by the actuator assembly. A third link is attached to the second link to rotate about a second axis orthogonal to the first axis when the third link is driven by the actuator assembly. A fourth link is connected to the third link to rotate about a third axis orthogonal to the second axis when the fourth link is driven by the actuator assembly. The actuator assembly includes three electric motors with threaded drive capstans driving pulleys in the links while being spaced apart from the rotating links.

Abstract: A wrist driving structure for an industrial robot having: a first wrist element supported in cantilever fashion rotatably about a first axis; a second wrist element pivotally supported in cantilever fashion at a distal end side of the first wrist element with a proximal end as a supporting point about a second axis intersecting the first axis; a third wrist element supported in cantilever fashion at a distal end side of the second wrist element rotatably about a third axis intersecting the second axis; two driving motors provided in the first wrist element for driving the second wrist element and the third wrist element, respectively; and two gear sets for reducing a rotational speed of the two driving motors in predetermined reduction ratios. Each of the gear sets has a driving gear driven by one of the two driving motors and a driven ring gear which meshes with the driving gear. Two driven ring gears of the two gear sets are disposed coaxially with the second axis.

Abstract: A manipulator is provided that includes a foot part and a number of members connected to the foot part and to each other respectively, and at least a gripper part, such that the members, the gripper and the foot part form an arm. One or more motors are provided in the foot part for moving at least a one of the members and the gripper.

Abstract: An orientation preserving angular swivel joint suitable for mechanical robotic arms and in particular snake robots, the joint comprising two members and an angular bevel gear train that connects the two members of the joint. The gear train allows an actuator to be positioned along the axis of the joint while transferring forces to the periphery of the mechanism, thus creating a high mechanical advantage proportional to the radius of the robot. The gear train is capable of transferring rotational motion between the two members with a constant ratio. Relative rotation between two bays of the joint does not take place, thereby preventing electrical wires running through the body of the snake from being twisted, and thus avoiding failure.

Abstract: An industrial robot including a manipulator having a control system. The manipulator includes a common gear housing having first and second inner compartments connected with a passage channel. First and second gears are arranged in the first and second inner compartments and are adapted to move the manipulator. A cooling and lubricant medium is disposed in the common gear housing and circulates between the first and second inner compartments through the passage channel.

Abstract: A controlled relative motion system having first and second support structures with a controlled output position joint connecting them, and with similar joints on these support structures. One joint is coupled to another controlled relative motion system having an output carrier rotatable in two perpendicular directions through the use of gears therein. This output carrier supports two articulated manipulating systems of which one has a single axis rotatable subbase supporting a rotatable gripping extension, and the other has a shackle connected to a base effector which shackle is supported on a fixed pedestal and another shackle connected to a base effector which shackle is supported on a moveable pedestal.

Abstract: An article transfer apparatus suitable for an operation requiring a large vertical working distance. The apparatus includes a first link driven by a motor, at least one second link coupled to the first link, and a mounting member coupled to the last one of the second link and loaded with an article to transfer. The individual links are pivotally moved using a combination of a supporting shaft, a rotating shaft and a swiveling shaft which are provided on the previous link, and the mounting member is moved upward by the shafts provided on the last link. Bevel gears are provided on the ends of the supporting shaft and the swiveling shaft and on both ends of the rotating shaft, and engaged with one another. The gear ratio between the bevel gear of the rotating shaft and that of the swiveling shaft is 2:1 on the first link and 1:2 on the last link. The other bevel gears are engaged with each other at a gear ratio of 1:1.

Abstract: The linking component between two parts that contributes to maintaining them at a distance that is determined but adjustable comprises a jack with a screw and a nut. The movement of the jack is controlled by a motor. Universal joints are disposed between the two parts and the screw and the nut respectively, and the axes of rotation of one of the universal joints passes through the center of the nut. If play present in the assembly causes the screw to become skewed relative to the nut, the nut tilts freely until its axis is in line with that of the screw, thereby eliminating the flexion stresses caused by the cantilever on the screw. The component may be used to regulate the angle between two hinged sections of a robot arm.

Abstract: A robot with multi-joint arms, wherein articulated first and second arms 9, 10 are movable in a horizontal plane as well as in a vertical direction, the second arm having a free end to which a supplementary unit A is removably connected, the supplementary unit A including a joint member 17 adjustably connected to the free end of the second arm 10 and a working member 18 removable connected to the joint member 17. The working member 18 has a predetermined length Lx which determines the effective length L2 of the second arm 10, and wherein the data representing the effective length L2 of the second arm is entered to renew the existing effective length of the second arm to produce new data representing the value of the newly entered effective length L2 of the second arm 10, the new data being employed to calculate out the value to control the operations of the first and second arms 9, 10.

Abstract: A robot arm comprises an assembly (6) rotatable relative to a part (2) of the arm about an axis extending at an angle to a longitudinal axis of the arm part, said assembly comprising a drive unit (8) and a member (9) driven by the drive unit. A cable (35, 36) comprising one or more lines for communication of energy for driving and/or control purposes extends between the arm part (2) and the drive unit (8). The assembly (6) comprises an axle pin (13) rotatably supported relative to the arm part (2). The cable extends in a space (48) provided in the assembly and comprising a first part space (49) provided in the axle pin (13), the cable being coiled in screw-line-shape in said first part space, and a second part space (50), in which the cable extends from the first part space (49) to the drive unit.

Abstract: A compact gear system that includes an input shaft (28), an output shaft (1) and gear wheels which drivingly connect the same, wherein the output shaft (1) is journalled in a gear housing (2). The output shaft (1) is hollow and has pins (5a) which project radially outwards in a normal plane and each of which carries a gear wheel (6). Provided on each side of the pins is a respective crown wheel (11, 12) journalled on the output shaft (1) and having a toothed ring (17, 18) in engagement with the gear wheel (6). Each crown wheel also has a cylindrical toothed ring (19, 20) which coacts at different transmission ratios with a respective toothed ring (25, 26) on an eccentric shaft (21) which extends parallel with the output shaft (1) and which is rotatably journalled in the housing (2), wherein the eccentric shaft (21) is driven by the input shaft (28).