97 results about "Parallel kinematics" patented technology

A multi-axis Cartesian guided parallel kinematic machine has a frame, a base platform, a multi-axis Cartesian guiding mechanism assembly, multiple driving strut assemblies and a motion platform. The motion platform is connected to the base platform through the driving strut assemblies and the multi-axis Cartesian guiding mechanism assembly. The multi-axis Cartesian guiding mechanism assembly has multiple linear guiding mechanisms and rotary guiding mechanisms that are in-serial linked and arranged in orthogonal to each other according to the Cartesian coordinate system. The multiple driving strut assemblies are in-parallel connected to the base platform and the motion platform using pivot joints. Each driving strut assembly is a telescoping strut assembly or a sliding strut assembly. When the driving strut assemblies are actuated, the motion platforms can be driven to a desired position in the Cartesian workspace with a controllable platform orientation relative to the frame.

The parallel kinematic machine (PKM) trajectory planning method is operable via a data-driven neuro-fuzzy multistage-based system. Offline planning based on robot kinematic and dynamic models, including actuators, is performed to generate a large dataset of trajectories, covering most of the robot workspace and minimizing time and energy, while avoiding singularities and limits on joint angles, rates, accelerations and torques. The method implements an augmented Lagrangian solver on a decoupled form of the PKM dynamics in order to solve the resulting non-linear constrained optimal control problem. Using outcomes of the offline-planning, the data-driven neuro-fuzzy inference system is built to learn, capture to and optimize the desired dynamic behavior of the PKM. The optimized system is used to achieve near-optimal online planning with a reasonable time complexity. The effectiveness of the method is illustrated through a set of simulation experiments proving the technique on a 2-degrees of freedom planar PKM.

A parallel kinematic positioning system 10 (PKPS 10) that is comprised of a stationary base plate (12) and an upper movable platform (28) to which is attached a workpiece or an instrument. Between the stationary base plate (12) and the upper movable platform (28) are positionally attached six strut assemblies (50). The six strut assemblies operate a hexapod that include in combination, a counterbalance subassembly (111), a servo motor subassembly (134), a bearing and encoder subassembly (156) and an electronics circuit (190). The combination accurately and repeatably positions the upper movable platform (28) within six degrees of freedom relative to the base plate (12).

A calibration device for a parallel kinematic manipulator having a base unit and a manipulator platform movable with respect thereto, the manipulator platform being connected to the base unit via a plurality of joints and a plurality of variable length actuators. The calibration device for measuring n deviations in order to determine m unknowns includes a test workpiece that is mountable in a definite spatial position with respect to the base unit and has I=m / n measuring mandrels. The calibration device also has a probing unit attached to the manipulator platform, and including n probing subsystems, the probing subsystems each including a distance measuring device for measuring the spatial position and spatial orientation of the measuring mandrels on the test workpiece.

A parallel robot or parallel kinematics mechanism is provided for uses such as robotics or machining. The mechanism comprises a fixed base, a main arm, and a first and second support arm to position and orient an object in a cylindrical space with at least three degrees of freedom and retained inclination. The main arm includes an end component for supporting the object and linkage means to retain the inclination of the end component with respect to the base for all positions and orientations of the end component. The mechanism advantageously provides a large cylindrical workspace and a small footprint and is capable of moving an object at high accelerations and speeds. The mechanism can be equipped with an additional motor to orient an object, thereby providing the mobility of a SCARA robot. Alternatively, it can be equipped with passive transmission means that allow for an object to be displaced in parallel to itself.

A parallel robot or parallel kinematics mechanism is provided for uses such as robotics or machining. The mechanism comprises a fixed base, a main arm, and a first and second support arm to position and orient an object in a cylindrical space with at least three degrees of freedom and retained inclination. The main arm includes an end component for supporting the object and linkage means to retain the inclination of the end component with respect to the base for all positions and orientations of the end component. The mechanism advantageously provides a large cylindrical workspace and a small footprint and is capable of moving an object at high accelerations and speeds. The mechanism can be equipped with an additional motor to orient an object, thereby providing the mobility of a SCARA robot. Alternatively, it can be equipped with passive transmission means that allow for an object to be displaced in parallel to itself.

A haptic device comprising a base member (4), an end-effector (6), a parallel kinematics structure arranged between the base plate and the end-effector and providing at least three degrees of freedom including at least three translational degrees of freedom in relation to the end-effector, and at least one passive gravity compensation means being adapted to exert forces and / or torques on the parallel kinematics structure for at least partial compensation of gravity related forces and / or torques acting in at least one of the three translational degrees of freedom.

The invention relates to an industrial robot having parallel kinematics, the industrial robot, comprising a robot base (1, 38), a carrier element (2, 42) for accommodating a gripper or a tool, several movable, elongated actuating units (4,36), which are connected at one end thereof to drive units (6, 39) arranged on the robot base (1, 38), and the other end of which is movably connected to the carrier element (2, 42), an elongated hollow body (20, 43, 54), which has a continuous cavity and which is flexibly connected to the robot base (1, 38), a joint (35, 49, 65), which has a continuous cavity and which has several degrees of freedom, by means of which joint the elongated hollow body (20, 43, 54) is movably connected to the carrier element (2, 42), and at least one supply line (26, 51, 64) for a gripper arranged on the carrier element (2, 42) or a tool arranged on the carrier element (2, 42), the supply line being guided through the cavity of the elongated hollow body (20, 43, 54) and the cavity of the hollow joint (35, 49, 65) from the robot base to the carrier element (2, 42).

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. The parallel kinematic structure further comprises a moveable end-effector section coupled with the output sections of the anti-planar joint arrangements.

An industrial robot including a parallel kinematic manipulator (2) of an object (7a) in space, where the manipulator (2) includes a stationary platform (6), a movable platform (7) for carrying the object (7a), at least three arms (3, 4, 5) connecting the platforms (6,7). Each arm comprises a first arm part ( ) connected to the stationary platform for manipulating the movable platform (7).

A parallel kinematic machine (PKM) with three active kinematic chains and a leg has improved precision and stiffness maps by: providing drive and actuation of each active kinematic chain by devices secured rigidly to a support structure so that only a fixed length leg of the chain is suspended; driving the fixed length leg of the active kinematic chain to move in a direction oblique to a direction of the fixed length leg; and providing a prismatically jointed leg that is rigidly secured to the base structure and coupled by an effectively universal joint to the motion platform.

The invention discloses a space tripod-based parallel kinematic mechanism with remote double bars. Both ends of a first side bar and a second side bar are respectively provided with staining machines, one end of which is rotationally connected with the first side bar and the other is rotationally connected with the second side bar; inner grooves are respectively arranged at the front end and the back end of the first side bar and the second side bar; the junctions of both sides of the ends of the near side bar and the far side bar are respectively rotationally connected with shafts 1, the ends of which are respectively connected with outer grooves which combine and are connected with the front ends of the first side bar and the second side bar; the moving platform and the shaft 1 are correspondingly rotationally connected with shafts 2, the ends of which are respectively provided with outer grooves which combine and are connected with the back ends of the first side bar and the second side bar. With the adoption of open two-degree-of-freedom rotary pair, the mechanism realizes all the functions of the traditional hook joint. However, compared with the traditional hook joint, the mechanism is easier to eliminate the radial clearance and the axial clearance, thus being conducive to enlarging the workspace of the mechanism.

Kinematic parameters of a parallel kinematic machine can be estimated with high precision considering thermal displacement and error of a measuring device, in addition to deformation error caused by self-weight of each component. A DBB device is used when end effectors of a parallel kinematic mechanism machine are positioned at plural positions and in plural postures. In the DBB device, a plurality of support bars are provided with rigid balls on the both ends. One of the balls is fixed on a table and the other ball is provided with an end effector. The position, posture, and distance from a fixed position are measured and based on the measured value kinematic parameters are estimated. In estimating the kinematic parameters, any of deformation error caused by self-weight of each component, thermal displacement of each component, error of a measuring device are added for computation by linear approximation.

The invention relates to a parallel kinematics machine which has the advantage of being easy to calibrate and control. According to he technical scheme, the three-freedom-degree parallel mechanism with two vertical interleaved rotating shafts comprises a movable platform, a rack and three branches, the three-freedom-degree parallel mechanism is characterized in that a first branch and a second branch are connected with a universal hinge, a sliding pair, a connecting rod and a rotating pair in series; a third branch is connected with a rotating pair, a sliding pair, a connecting rod and a universal hinge; axes of outer rotating shafts of the universal hinges of the first hinge and the second hinge are collinear and parallel to the axis of the rotating pair of the third branch; the axis of the inner rotating shaft of the universal hinge of the first branch and the axis of the rotating pair of the first branch are parallel to the axis of the inner rotating shaft of the universal hinge of the second branch and the axis of the rotating pair of the second branch and vertical to the axes of the outer rotating shafts of the universal hinges of the first branch and the second branch; in the third branch, the axis of a first rotating shaft of the universal hinge is parallel to the axis of the rotating pair, and the axis of a second rotating shaft of the universal hinge is parallel to the axes of the rotating pairs of the first branch and the second branch.

An automated machining head with vision and procedure includes a pressure foot provided with side windows with the capacity to open and close, encasing the machining tool, associated with a vertical movement device provided with mechanical locking, vision equipment connected to a computer and a communications module. The main advantage is endowing an anthropomorphic robot, originally designed for the car industry and with relatively low accuracy, with a notably higher machining accuracy, equivalent to equipment of a much greater accuracy or to parallel kinematic-type robots, also compensating, in real-time and in a continuous manner, for off-centring and loss of perpendicularity by the pressure foot, which are common in conventional heads and are a source of errors and inaccuracy.

Support device for positioning an optical element (2), in particular a lens, comprising a first frame unit (1.1) and a plurality of support units (1.2) for supporting said optical element (2), each of said support units (2) having a first end for fixedly engaging a part of said first frame unit (1.1) and a second end for supporting said optical element (2), said support units (1.2) being arranged for positioning said optical element (2) along a first direction, a second direction and a third direction in the manner of parallel kinematics, said first direction, said second direction and said third direction being translatory directions arranged mutually transverse to each other, wherein there are provided three support units (1.2) and wherein each of said support units (1.2) provides for restriction of a first degree of freedom and a second degree of freedom to support said optical element (2) in an isostatic manner.

First of all, in a first step S1, each actuator command value for position command value and posture command value of an end-effector is determined. Next, in a second step S2, rotational resistance values of a first and a second universal joints are obtained, and in a third step S3, the force and the moment exerted to each of the second universal joints are computed using this, and in a fourth step S4, the resultant force and the resultant moment exerted to the end-effector are determined from these. Then, in the fifth step, the elastic deformation amount of a mechanism is computed using these, and a compensation amount of the actuator command value is computed using these values. And then, in the sixth step, the actuator command values determined in the first step are updated with the compensation amount determined in the fifth step taken into account.

A parallel kinematic machine has a parallel kinematic mechanism including an end effecter and a parallel link mechanism. A numerical control device controls a position and orientation of the end effecter based on kinematics of the parallel kinematic mechanism. A posture setter sets an adjustment tool on the end effecter in a known posture in a reference coordinate system defined outside the parallel kinematic mechanism based on a measurement method. A data acquirer acquires data in accordance with a measurement method selecting code for designating the measurement method used by the posture setter in setting the adjustment tool in the known posture, and defines a correlation between kinematic parameters for the parallel kinematic mechanism and the reference coordinate system. A calculator calculates the kinematic parameters based on the acquired data by using a relational expression describing forward kinematics of the parallel kinematic mechanism.

A haptic device comprising a base member (4), an end-effector (6), a parallel kinematics structure arranged between the base plate and the end-effector and providing at least three degrees of freedom including at least three translational degrees of freedom in relation to the end-effector, and at least one passive gravity compensation means being adapted to exert forces and / or torques on the parallel kinematics structure for at least partial compensation of gravity related forces and / or torques acting in at least one of the three translational degrees of freedom.

A parallel kinematic mechanism apparatus includes a frame, a handle and an input joint that connects having at least two independent and functionally parallel paths for transmission of motion coupling the handle to the frame. A first path includes a first intermediate body connected to the frame by a first connector and to the handle by a third connector while the second path that is independent from the first path includes a second intermediate body that is connected to the frame by a second connector and to the handle by a fourth connector. The first connector and the fourth connector both allow rotation in a first rotational direction and restrict rotation in a second rotational direction and the second and third connectors allow rotation in the second rotational direction and restrict rotation in the first rotational direction.

A device for transmitting movements comprising a parallel kinematics transmission structure adapted to provide at least one degree of freedom including three translational degrees of freedom, the parallel kinematics transmission structure further comprising a base member (2), a moveable member (4), and at least one parallel kinematics chain (6) coupling the base member (2) and the moveable member (4), each parallel kinematics chain (6) having a first arm (8) moveable in a movement plane wherein the movement planes are at a distance to a symmetry axis (40), and each parallel kinematics chain (6) comprising a second arm (10) coupled to the moveable member (4), wherein a first end (18) of the second arm (10) is adapted to be coupled to the first arm (8) and a second end (16) of the second arm (10) is adapted to be coupled to the moveable member (4).

An industrial robot including a manipulator for movement of an object in space. The manipulator includes a movable platform arranged for carrying the object, a first arm arranged for influencing the platform in a first direction and including a first inner arm part rotatable about a first axis, a second arm arranged for influencing the platform in a second direction and including a second inner arm part rotatable about a second axis, a third arm arranged for influencing the platform in a third direction and including a third inner arm part rotatable about a third axis.

A parallel kinematic mechanism apparatus includes a frame, a handle and an input joint that connects having at least two independent and functionally parallel paths for transmission of motion coupling the handle to the frame. A first path includes a first intermediate body connected to the frame by a first connector and to the handle by a third connector while the second path that is independent from the first path includes a second intermediate body that is connected to the frame by a second connector and to the handle by a fourth connector. The first connector and the fourth connector both allow rotation in a first rotational direction and restrict rotation in a second rotational direction and the second and third connectors allow rotation in the second rotational direction and restrict rotation in the first rotational direction.

A calibration method is provided for calibrating a parallel kinematic mechanism that has an end effecter. The method includes setting an adjustment tool attached to the end effecter in predetermined postures in a reference coordinate system by taking coordinates of the posture of the adjustment tool each time the adjustment tool is placed in the posture and recording coordinates of driver shafts manipulated by a numerical control device in accordance with the inverse kinematics each time the adjustment tool is placed in the posture. The method continues by calculating kinematic parameters necessary for the kinematics of the parallel kinematic mechanism based on the taken coordinates of the postures of the driver shafts and the recorded coordinates of the driver shafts. Accordingly, it is possible to obtain accurate posture information of the end effecter and relative coordinates of the driver shafts.

A calibration method is provided for calibrating a parallel kinematic mechanism that has an end effecter. The method includes setting an adjustment tool attached to the end effecter in predetermined postures in a reference coordinate system by taking coordinates of the posture of the adjustment tool each time the adjustment tool is placed in the posture and recording coordinates of driver shafts manipulated by a numerical control device in accordance with the inverse kinematics each time the adjustment tool is placed in the posture. The method continues by calculating kinematic parameters necessary for the kinematics of the parallel kinematic mechanism based on the taken coordinates of the postures of the driver shafts and the recorded coordinates of the driver shafts. Accordingly, it is possible to obtain accurate posture information of the end effecter and relative coordinates of the driver shafts.

The invention relates to the kinematic connection of a fixed platform (2) to a mobile platform (3) comprising up to six degrees of freedom in closed kinematic chains, (parallel kinematics), the connecting elements being rods, (actuators) of adjustable length, optionally consisting partially of rods of a constant length, (passive rods) and optionally cables. The invention is characterised in that three connecting elements of this type engage with a common point of one of the platforms (2, 3), forming a triple point (P3). In embodiments of the invention, said triple point can be configured as a pseudo triple point to produce a simple mechanical configuration, without losing the advantages of the invention. The inventive kinematics can be used for lifting tables, tackle for overhead conveyors, lifting robots, articulated arm-type robots, excavators, mills, cutting devices etc..

The invention is directed to a device for transmitting a movement having a parallel kinematics transmission structure (3) providing three translational degrees of freedom, said structure comprising one base member (1), one moveable member (2), at least one rotative actuator (30) arranged on the base member (1), parallel kinematics chains coupling the base member to the moveable member, each chain comprising a pivoting control arm (10), wherein the rotary motion of the at least one rotative actuator (30) is transmitted to a respective pivoting control arm (10) so that any translational movement of the moveable member is transmitted into a rotational movement of the control arms or vice versa, and wherein the at least one rotative actuator (30) is arranged such that its axis (31) is substantially perpendicular to the rotation axis of the control arms (10). The parallel kinematics transmission structure comprises three parallel kinematics chains, each chain comprising a pivoting control arm and a pair of parallel linking bars hingedly mounted by two rotational degrees of freedom joints at one end to an extremity of the control arm and at the other end to moveable member, thus forming a delta type arrangement, wherein each chain is provided with a respective rotative actuator and wherein the rotative actuators are arranged such that their axis are substantially parallel to each other. The movement between the rotative actuators and the control arms are transmitted by cable members (51).