Abstract: The present invention relates to a method and apparatus for limiting the contact force between a moving device and another object, using a parallel mechanism and torque limiters where the threshold force to activate the force limiting mechanism is not related to the configuration of the moving device or the location of the contact force relative to the activation point of the force limiting mechanism, and where the mechanism may be configured for one, two or three degrees of freedom. A counterbalance mechanism is also provided to counteract gravity load when the force limiting mechanism is configured for three degrees of freedom and responsive to contact forces including a vertical element. In particular, the invention relates to a method and apparatus for limiting the contact force between a moving robotic device and a contactable object.

Abstract: A controlled relative motion system includes a base support and a manipulable support. A plurality of lower link members are pivotally coupled to the base support, and each includes a spherical section capture opening. A plurality of upper link members are rotatably coupled to the lower link members via spherical joints at the spherical section capture openings. The manipulable support is pivotally coupled to the plurality of upper link members.

Abstract: A bidirectional pivoting joint comprises pivoting elements which are rotatable relative to one another, specifically in a coaxial arrangement, a cylindrical outer body and a cylindrical inner body and a locking device optionally locking and releasing the rotational movement. The locking device has an annular space between the outer body and the inner body. Provided between annular space surfaces, specifically an inner surface of the outer body and an outer surface of the inner body are radially narrowing and, on the other hand, radially wider, peripheral regions in alternating arrangement. Arranged in the annular space are at least two clamping members which are each adjustable in cross-section in the peripheral direction (u) of the annular space. In a holding state, each clamping member has a first said cross-section and lies in the narrowing peripheral regions against the outer body and the inner body.

Abstract: The various robotic medical devices include robotic devices that are disposed within a body cavity and positioned using a support component disposed through an orifice or opening in the body cavity. Additional embodiments relate to devices having arms coupled to a device body wherein the device has a minimal profile such that the device can be easily inserted through smaller incisions in comparison to other devices without such a small profile. Further embodiments relate to methods of operating the above devices.

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 mechanism includes at least one module (M1) having a tubular structure with at least three faces, each of said faces comprising: two parallel longitudinal fibers (1, 4), rigid and inextensible, whose ends are connected through respective ball or elastic joints (0-1; 4-0) to the ends of the fibers of contiguous modules, or to a base (0); a transverse link (2) connecting said two longitudinal fibers, having a first end rigidly connected to said first fiber and a second end slidably connected to said second fiber, said transverse link being inextensible and having two rotational degrees of freedom; a longitudinal link (32) connecting said transverse link to a homologous transverse link of an adjacent module or to a base via a ball or elastic joint (32-0) and an universal joint (3-32); and an actuator (A) for changing the length of said longitudinal link.

Abstract: A parallel kinematic structure comprises at least two kinematic chains being functionally arranged in parallel. Each of the two kinematic chains has, at a moveable end thereof, at least one degree of freedom, and comprising a passive anti-planar joint arrangement having a translational degree of freedom and two rotational degrees of freedom. Each anti-planar joint arrangement has an input section and an output section. At least one of the kinematic chains comprises a planar joint arrangement having at least one of at least one translational degree of freedom and a rotational degree of freedom, the planar joint arrangement having an output section. Further, the planar joint arrangement is adapted for active movements in at least one of its degrees of freedom. The input section of the anti-planar joint arrangement and the output section of the respective planar joint arrangement are coupled.

Abstract: A serpentine robotic crawler having multiple dexterous manipulators supported about multiple frame units. The frame units are connected via an articulating linkage at proximal ends wherein the articulating linkage is capable of positioning the frames into various configurations. Dexterous manipulators are coupled to distal ends of the frame units and are positionable via the articulating linkage and articulating joints therein into various positions about the frame ends. The configurations and positioning of the dexterous manipulators allows the robotic crawler to perform coordinated dexterous operations.

Abstract: A robot arm assembly includes a main base, a joint and at least one arm. The main base includes a main body, and the main body includes a mounting portion and a limiting post on a side of the mounting portion. The joint is rotatably mounted on the mounting portion and includes a limit piece corresponding to the limiting post. The at least one arm is fixed to the joint, when the arm rotates relative to the main base to a predetermined extent of rotation, the limit piece abuts against the limiting post to stop the rotation of the arm.

Abstract: In a robot arm, a plurality of arm sections including a first arm section and a second arm section are turnably connected. Each of the arm sections includes a plurality of links and an actuator section that turns the plurality of links with respect to each other. In the first arm section, a small body section with reduced length of a body circumference is provided on an outer circumferential surface between the plurality of links in a center axis direction.

Abstract: The primary object of the present invention is a jointed and instrumented limb for robot or haptic interface comprising at least first (2) and second (4) rigid segments and a joint (6), said joint (6) comprising fibers and at least one measurement element (101, 102) and being fixed in each of the rigid segments (2, 4). The present invention also has for object a robot or a haptic interface comprising at least one such jointed limb.

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 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: Provided is an articulation for surgical equipment using a ball joint fastened by the ball joint. The present invention has been made in an effort to provide an articulation for surgical equipment using a ball joint of which the shaft of pitching or yawing is not changed even though the pitching or the yawing is repeated. The articulation for surgical equipment using a ball joint is configured to include a plurality of disks; a ball joint to allow the plurality of disks to be pitched or yawed between the plurality of disks based on a longitudinal direction of the articulation for surgical equipment; and a driving wire applying a driving force to pitch, yaw, or roll the plurality of disks.

Abstract: Tyre-retreading system constituted by a robotized arm with angular interpolation movements with the aim of providing a modular machine capable of allowing greater amplitude of movements on the part of the scraping tool (5) and/or rubber-applying tool (11), which is installed at the end of a robotized arm (1) controlled via a control panel and provided with at least three articulations (2, 3, 4); the tools (5, 11) act on a tyre (7) supported by a mandrel system (6, 10).

Abstract: A robotic link mechanism comprising a pair of base elements connected by a passive flexible joint, such that flexure of the joint changes the mutual orientation of the base elements. A pair of obliquely truncated cylinders are confined between the base elements such that the obliquely formed end surfaces of the cylinders can rotate in sliding contact with each other, and the other end of each cylinder can rotate in sliding contact with its associated base element. Driving motors are attached to the base elements, each one controlled to rotate the cylinder associated with that base element, such that rotation of at least one of the cylinders causes the base elements to undergo change in their mutual orientation. The mechanism thus has a backbone composed of the passive flexible joint, which is supported and actuated by the oblique truncated cylindrical structure that serves as an active exoskeleton.

Abstract: A combination component handling and connecting device connectable to a multi-axis robot for use in moving and connecting components and subassemblies includes a housing and an actuator fixedly connected to the housing. The actuator includes an actuating link movable from a first position to a second position. Connected to the actuating link is an end effector for concurrent movement with the actuating link. The component handling and connecting device includes a clamp having a first jaw and a second jaw. The second jaw is connected to the actuating link for selectively moving the second jaw toward the first jaw operative to engage a component.

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 surgical instrument stabilizer system that includes an articulating boom that is releasably connectable to a surgical table side rail. The articulating boom includes an actuator, a multi-directional flexible arm having a first end region attached to the actuator, and a cable extending through the flexible arm. The cable has one end region connected to the actuator and another end region connected to a preload tensioning mechanism. The actuator is operable to tighten and loosen the cable, and the preload tensioning mechanism maintains an amount of tension in the cable when the actuator loosens the cable. The system further includes a surgical instrument-supporting member that is attached to a second end region of the flexible arm and is configured to releasably retain a surgical instrument.

Abstract: A robot includes a body, a first arm, and a second arm. The first arm includes one joint, an adjacent joint that is adjacent to the one joint, and another adjacent joint that is adjacent to the adjacent joint. When the first arm is extended in a vertical orientation relative to the body, the one joint of the first arm has a rotation axis that is offset by a first distance in a first horizontal direction from a rotation axis of the adjacent joint of the first arm, and the another adjacent joint of the first arm has a rotation axis that is offset by a second distance in a second horizontal direction from the rotation axis of the adjacent joint of the first arm. The first horizontal direction is opposite to the second horizontal direction.

Abstract: A transfer apparatus includes a base, a first holder, a second holder offset from the first holder in a first direction, and a movement mechanism for moving the first holder and the second holder relative to the base in a plane parallel to the first direction. The movement mechanism includes a swing member, a first link arm and a second link arm. The swing member is pivotally supported on the base. The first link arm is pivotally connected to the first holder. The first link arm is also connected to the swing member for pivoting about a first intermediate axis extending in a second direction perpendicular to the first direction. The second link arm is pivotally connected to the second holder. The second link arm is also connected to the swing member for pivoting about a second intermediate axis extending in the second direction. The first intermediate axis is offset from the second intermediate axis in the first direction.

Abstract: A method for planning the robot path includes forming a shape space that includes a start point, a goal point, and obstacle information so as to generate a moving path of the robot, generating one or more moving paths of the robot within the shape space, and storing the generated moving paths in a database, selecting a specific path that has a minimum operation range of the robot and a minimum constraint caused by the obstacle from among the stored moving paths, and planning the selected path, enabling the robot to perform motion along the planned path, and pre-planning a path for a next motion of the robot while the robot performs the motion. The apparatus or method for planning the robot path can reduce a time from an end time of one motion to the start time of the next motion, thereby performing a smooth motion.

Abstract: A manipulator includes a control unit (1), with handle (4) and control buttons (4a-4d), and a connecting arm (2) which, at its proximal end (2a), carries the control unit (1) and, at its distal end (2b), carries a work unit (3). The control buttons (4a-4d) control at least a first inclination motor, which causes a movement of inclination of a tool support (5) of the work unit (3) about a transverse inclination axis (11), and they control the actual rotation of the tool support (5) about its direction of inclination (II) and control the orientation of the direction of inclination (II) about the longitudinal axis (I-I) of the connecting arm (2). A particularly ergonomic manipulator is thus obtained which is easy to learn to use and which efficiently separates the stresses arising from movements of the tool support (5) and the stresses arising from holding and moving the manipulator itself.

Abstract: In one example, an arm assembly with an arm locking system is described that can include a base to position the arm on a support structure, an extension arm having first and second ends, the first end of the extension arm connected to the support structure or base at a first joint proximate the first end. The system can include a lift arm having third and fourth ends, the third end connected to the extension arm at a second joint proximate the third end, the fourth end being height adjustable relative to the base. The system can include a first lock engageable to selectively prevent movement about the first joint, a second lock engageable to selectively prevent movement about the second joint, and a third lock engageable to selectively prevent a height of the fourth end from being adjusted relative to the base or extension arm.

Abstract: A jointed limb comprising at least first (2) and second (4) rigid segments and a joint (6) providing rotation of the first and second segments with respect to each other about an axis of rotation (Y), said joint (6) comprising fibres, wherein each of the segments (2, 4) comprises a body (8.1, 8.2) and an end element (10.1, 10.2) provided at an end of said body, both end elements (10.1, 10.2) being held facing each other by said joint (6), said end elements (10.1, 10.2) comprising tapered profiles having vertices facing each other, each of said end elements (10.1, 10.2) being made prior to being secured it to the corresponding body (8.1, 8.2).

Abstract: Disclosed herein is a robot, which is capable of communicating according to a gesture. The robot includes a plurality of link members, and an outer cover member surrounding the plurality of link members. The shape of the outer cover member is varied into a curved shape, when the outer cover member is adhered closely to the plurality of link members, according to the variation of the shapes of the plurality of link members.

Abstract: A robot includes a base seat, a first arm fixed to the base seat, a second arm rotatably connected to the first arm, an output shaft rotatably connected to a distal end of the second arm, a first driving member, and a first transmission mechanism. The first transmission mechanism includes a first transmission belt and a reducer. The first driving member is located at one end of the first arm adjacent to the base seat, the reducer is located at the other end of the first arm away from the base seat, and connected to the second arm, the first driving member is capable of driving the reducer via the first transmission belt.

Abstract: A robot according to an embodiment includes a base, a first structure, a second structure, and a third structure. The first structure is connected to the base to be rotatable about a first axis. The second structure is connected to the first structure to be rotatable about a second axis orthogonal to the first axis. The third structure is connected to the second structure to be rotatable about a third axis parallel to the second axis. The first structure and the third structure are formed by using cast materials having a same shape.

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: A working device and a working method wherein an articulated robot controls vertical movement of a balancer arm by commanding vertical movement for a balancer, and moves the balancer arm horizontally by applying an external force to the balancer arm in the horizontal direction by means of a robot arm.

Abstract: An industrial robot includes a support body, a moving platform, a pivot shaft, a plurality of driving devices, a plurality of transfer branch joints, and a base. The support body includes a main body, and an installing portion opposite to the main body; the pivot shaft is rotatably connected with the main body and the moving platform; the driving devices are positioned at a bottom of the main body; each transfer branch joint is movably connected with the moving platform and one corresponding driving device; the installing base includes a bottom base, and two supporting arms extending from opposite sides of the bottom base; the bottom base and the two supporting arms cooperatively forming a receiving space; the bottom base and the two supporting arms are detachable in relation to the installing portion and the main body; the main body is received in the receiving space.

Abstract: A mechanical arm assembly comprises an arm rotatable about a pivot, a first force generating device for maintaining the arm at a datum, and a second force generating device for compensating for the first generating device to maintain the arm in positions other than the datum.

Abstract: A robot according to the present disclosure includes a support structure and at least three main arms mounted to be movable relative to the support structure, wherein the outer ends facing away from the support structure are movable to different spatial positions relative to the support structure and relative to each other. The robot further comprises connecting elements having the same lengths by means of which the outer end of each main arm can be connected at a defined distance from the outer end of the two adjacent main arms. The present disclosure also provides a method of calibrating a robot.

Abstract: An instrument wrist uses members having epicycloidal and hypocycloidal surfaces to bear loads and preserve a separation of reference points in the same manner as circles rolling on each other. The cycloidal surfaces can be uniform, stepped, or blended and can be arranged to ensure geared motion of members without addition of additional gearing structures. A hypocycloidal surface provides a concave contact that improves resistance to deformations under load. The wrist mechanism is tendon stayed, which keeps members in contact, and optionally gear structures can be integrated into the members to ensure geared motion and support roll toques.

Abstract: A humanoid robot includes a spherical joint with three degrees of freedom in rotation about three axes, the spherical joint connecting a first element and a second element of the robot, and three actuators for moving the spherical joint. The three actuators include a first actuator coupled to the first element, a second actuator coupled to the second element and the first actuator, and a third actuator coupled to the second element and the first actuator. The second actuator and the third actuator act in parallel and coupled together. The first actuator acts in series with the second actuator and the third actuator about a first axis of the three axes. An angular range of movement about the first axis is greater than an angular range of movement about either a second axis or a third axis of the three axes.

Abstract: A robot, such as a painting robot for painting components such as motor vehicle body components, is disclosed having a plurality of robot elements that are pivotable relative to each other. At least one flexible supply line may run from a proximal robot element to a distal robot element. The supply line may be axially displaceable in the proximal robot element relative to the longitudinal axis of the supply line, so that the supply line can perform an axial compensating motion during a pivot motion of the robot.

Abstract: An industrial robot may include a main body part; a plurality of levers having base end sides turnably connected with the main body part; a plurality of arm parts having respective base end sides turnably connected with respective tip end sides of the plurality of the levers; a movable part which is turnably connected with the respective tip end sides of the plurality of the arm parts; and a plurality of turning drive mechanisms for respectively turning the plurality of the levers. The plurality of the levers may radially extend to an outer peripheral side of the main body part at a substantially equal pitch.

Abstract: An articulated robot wrist includes 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.

Abstract: In one aspect, a translational parallel manipulator is provided and includes a fixed platform including three guide members. The three guide members include first ends and second ends, and the first ends of the three guide members are all coupled to each other and the second ends of the three guide members are all spaced-apart from each other. The manipulator also includes a movable platform spaced-apart from the fixed platform and three serial subchains coupled between the three guide members and the movable platform. In one aspect, a translational parallel manipulator is provided and includes a fixed platform, a movable platform spaced-apart from the fixed platform, and a plurality of subchains coupled between the fixed platform and the movable platform. At least one of the plurality of subchains includes no more than four one degree-of-freedom joints.

Abstract: The present invention relates to a vibration-type driving apparatus including a vibrator including an electro-mechanical transducer; a driven body disposed in pressure-contact with the vibrator; a supporting portion extending from the vibrator; a base to which the vibrator is fixed with the supporting portion interposed therebetween; a vibration absorber disposed between the supporting portion and the base; and a compressive-force adjusting device capable of adjusting a compressive force to be applied to the vibration absorber between the supporting portion and the base.

Abstract: A robot includes a base, a first arm rotatably connected to the base around a first rotating axis, a second arm rotatably connected to the first arm around a second rotating axis, a third arm rotatably connected to the second arm around a third rotating axis, a first angular velocity sensor provided in the first arm and having a first angular velocity detection axis parallel to the first rotating axis, a second angular velocity sensor provided in the second arm and having a second angular velocity detection axis parallel to the second rotating axis, and a third angular velocity sensor provided in the third arm and having a third angular velocity detection axis parallel to the third rotating axis.

Abstract: The present application provides an industrial robot that can control the abrasion and damage of a bearing unit, and also control the deformation of an arm, even in the case of transferring a high-temperature transfer object in a vacuum. The industrial robot includes a bearing unit for supporting an arm at a joint section as a connection section between the arm and the main body. At the joint section, the arm has a first protrusion section protruding toward the main body, and meanwhile the main body has a first housing section in which a first hollow section for housing the first protrusion section is formed. The first protrusion section and the first housing section are formed of a material having higher thermal conductivity than the bearing unit has, and a semisolid thermally-conductive substance, having higher thermal conductivity than the bearing unit has, is placed in the first hollow section.

Abstract: A robot includes a base, a first arm rotatably connected to the base around a first rotating axis, a second arm rotatably connected to the first arm around a second rotating axis orthogonal to the first rotating axis, a third arm rotatably connected to the second arm around a third rotating axis parallel to the second rotating axis, an angular velocity sensor provided in the first arm, and an acceleration sensor provided in the third arm.

Abstract: A robot includes a base, a first arm rotatably connected to the base around a first rotating axis, a second arm rotatably connected to the first arm around a second rotating axis orthogonal to the first rotating axis, a third arm rotatably connected to the second arm around a third rotating axis parallel to the second rotating axis, and a three-axis inertial sensor provided in the third arm and including a first detection axis, a second detection axis, and a third detection axis orthogonal to each other, the first detection axis and the third rotating axis being parallel to each other.

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 robot includes a link having a longitudinal base end rotatably connected to a member so as to rotate about a rotation axis perpendicular to a longitudinal direction of the link. The link is formed into a tubular shape such that a cross section of the link perpendicular to the longitudinal direction has an elliptical shape or a substantially rectangular shape with at least one curvilinear corner portion.

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 has a robot arm, a support structure, and a movable platform. The platform includes a cantilevered member coupled to a guide of the support structure such that motion of the platform is directed along a first direction. The robot further includes first and second timing belts having portions that extend along the first direction and that are disposed on opposite sides of the cantilevered member, and first and second shafts movable with the movable platform. The shafts are coupled to the respective timing belts, to the robot arm such that rotation of the first shaft imparts angular motion to the robot arm and rotation of the second shaft imparts radial motion. The robot also includes a third timing belt to which the platform is coupled and by which it is moved. Motors are provided that impart movement to the timing belts.

Abstract: The manipulator comprises a supporting device (11) having an assembly (13) rotatable about a vertical axis and an articulated parallelogram (21) with a swing arm (24). A pneumatic linear actuator (22), acts between the rotatable assembly (13) and the articulated parallelogram (21), for causing the arm (24) to rotate about a horizontal axis of oscillation. A slide (23) is connected to the actuator (22) and slidably mounted on the rotatable assembly (13) by means of a first vertical guide (30). The slide has a second horizontal guide (31) in which is engaged an element (32, 33) mounted on the swing arm (24).

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.