Abstract: A digital position and velocity feedback system is provided for a multiaxis robot control and it employs an LSI chip to process incremental position signals for position change and velocity computations. At low speeds, velocity is computed from the reciprocal of elasped time. At higher speeds, velocity is computed from the rate at which incremental position signals are generated.

Abstract: Circuitry is provided for applying a pulse width modulation (PWM) scheme to a brushless DC motor that operates as a robot axis drive. A pulse width modulation (PWM) scheme provides for digital implementation of robot control commands. For this purpose, it provides time stabilized current sampling synchronized to the sampling frequency of the position and velocity loops in the robot control. The brushless drive application circuitry provides for application of the PWM control outputs to commutate the motor energization from winding pair to winding pair.

Abstract: The invention relates to a manipulator comprising an end effector (27) displaceable by means of a rod mechanism comprising four arms (11,13,15,17). By means of simultaneously activated individual drives (29,35) for two of the arms (11,15) which are of equal length, which individual drives are integrated in a differential drive, a displacement of the rod mechanism is obtained in a plane at right angles to a main axis (3) about which the two arms (11,15) are rotatable. At the same and oppositely directed angular velocities of the arms (11,15) about the main axis (3), a radial (R) positioning of the end effector (27) takes place, while at the same angular velocities of the arms (11,15) in the same direction an angular (.theta.) displacement of the end effector (27) about the main axis is obtained. The manipulator is particularly suitable for use as assembling robot.

Abstract: A driving mechanism having a spindle which is provided with a first helical threaded portion having a lefthand direction of rotation and with a second helical threaded portion having a righthand direction of rotation. A pair of spindle guides each engage a respective spindle threaded portion for rotating the spindle and translating the spindle in an axial direction. Each spindle guide has three pairs of runner rollers on a sleeve for centering and supporting the spindle within the sleeves. The three pairs of runner rollers on each sleeve kinematically constrain the six degrees of freedom of the spindle without overconstraint to reduce friction and binding of the spindle in the spindle guides.

Abstract: A three-dimensional positioning apparatus comprising a base (180), a first element (182) and a second element (186) is constructed in the form of a sawhorse bracket. The first element (180) is pivotable about a first pivot axis (184) only, and the second element (186) is pivotable about two axes, one substantially parallel to and one substantially perpendicular to the first pivot axis (184). The first element is positioned by a first axially elongatable cylinder (188), lying at an angle to a first plane extending through the first element and through the first pivot axis. The second element is positioned by a pair of second axially elongatable cylinders (194), arranged in a plane generally parallel to the first plane, and angled with respect to each other and converging towards each other from the base to the second element.

Abstract: A digital robot control is provided with position/velocity and torque control loops with microprocessor servo controllers in each. The position/velocity servo controller includes two microprocessors that operate as a servo engine in providing position/velocity control for six robot axes. One microprocessor operates as a manager to perform data processing and coordination tasks supportive to position/velocity control. The other microprocessor performs position and velocity servo calculation tasks and operates as a slave processor to the position/velocity control manager. The programming for the position/velocity control sends manager position and other commands and position and velocity feedback from other control levels to the position/velocity calculator and sends torque commands received from the calculator to the next lower control level. The calculator employs position/velocity control algorithms in making torque command calculations.

Abstract: An articulated robot joint includes a coupling member 13 having a hollow cylinder 13a rigidly mounted to a lower arm 2 and rotatably journaled to an upper arm 1. An offset crank 13c extends from one end of the cylinder, and has a mounting hub 13d at the end of a radial arm thereof coupled to an axially disposed output shaft of a motor and harmonic drive unit 5, 6. A power/control cable 3 is threaded through the hollow interiors of the arms, and traverses the joint via the hollow cylinder.

Abstract: A digital robot control includes a position/velocity microprocessor control and a torque microprocessor control for each of multiple robot axes. Digital position, velocity and motor current feedback signals are generated from motor sensor signals for use in making microprocessor control calculations. Another motor sensor generates an overlimit signal when motor temperature rises above a limit value to indicate excessive motor current. The torque microprocessor makes a backup motor energy calculation from the feedback motor current signal from each joint motor and compares the result to a stored motor energy limit. The robot is shut down if either limit is exceeded.

Abstract: A digital robot control is provided with cascaded position/velocity and torque control loops with microprocessor servo controllers in each. The servo controller includes two microprocessors that operate as a servo engine in providing motion control for six robot axes. One microprocessor is structured to perform data processing and coordination tasks. The other one performs calculation tasks and operates as a slave processor to the first.

Abstract: A robot is provided with an arm having a plurality of motor driven joints. A power amplifier supplies drive current to each joint motor. Respective digital feedback control loop arrangements generate voltage commands from which signals are generated to operate the power amplifiers.Digital motor current, position and velocity feedback signals are generated for position, velocity and torque control loops in the digital feedback control loop arrangement. System resource facilities provide general support for the operation of the digital feedback control loops and include three separate communications controllers, a dual port microprocessor interfacing memory, a time stamp clock, a program memory and a nonvolatile data memory.A system level microprocessor based system or a microprocessor based position/velocity control system executes motion software from the program memory means according to whether the user desires an expanded performance robot control or a basic robot control.

Abstract: A multidigit arm contains a plurality of sections, each of which is positionable angularly and spatially to a predetermined degree with respect to an adjacent section. Control means are provided for selectively individually positioning each section within said arm with respect to an adjacent section, such control means including actuator means positioned within and carried by and between the arm sections. The arm may be formed into a variety of curves and position the arm end at a variety of positions.

Abstract: In articulation drive apparatus of an industrial robot which includes a first member (5) of the robot, a second member (12) of the robot freely rotatably supported on the first member and a reduction gear apparatus for reducing rotation of an electric motor integrally connected to the first member and transmitting the reduced rotation to the second member, the improvement wherein the reduction gear apparatus (3) comprises a primary reduction gear (20) for reducing the number of rotations of the electric motor (1) and a secondary planetary reduction gear (21) for further reducing the number of rotations of output of the primary reduction gear (20). Resonance phenomenon of the drive system is prevented by modifying the construction of the reduction gear apparatus used in the robot drive system, and furthermore, by using bar-shaped members (60), the robot is made small and light in weight and stands a relatively larger torsional rigidity.

Abstract: A robotic arm positionable within a nuclear vessel by access through a small diameter opening and having a mounting tube supported within the vessel and mounting a plurality of arm sections for movement lengthwise of the mounting tube as well as for movement out of a window provided in the wall of the mounting tube. An end effector, such as a grinding head or welding element, at an operating end of the robotic arm, can be located and operated within the nuclear vessel through movement derived from six different axes of motion provided by mounting and drive connections between arm sections of the robotic arm. The movements are achieved by operation of remotely-controllable servo motors, all of which are mounted at a control end of the robotic arm to be outside the nuclear vessel.

Abstract: A six degree of freedom micromanipulator is disclosed which may be interposed between the fingers and the remainder of a robotic arm's structure for increasing the accuracy with which an arm's fingers may be positioned independently of the accuracy achievable through motions originating at or near the arm's shoulder. Included in the structure are a base plate and yokes; drive rods and trunnions; drive rod ends; and a manipulator plate and yokes. Motor driven push-pull assemblies may be used in place of the elongated drive rods and their associated trunnions to electrically control the position of the manipulator plate.

Abstract: An expandable and contractable arm is constituted by a plurality of expandable and contractable units and connecting devices including universal joints for serially interconnecting the units into the arm. Each unit includes at least three expandable and contractable operating members in the form of link mechanisms or double thread type expandable and contractable rods, and actuating devices for equally or unequally expanding and contracting the operating members so as to increase or decrease distances between the connecting members while maintaining them in parallel or inclined with respect to each other.

Abstract: An inserter for vacuum installations has a two-part arm provided with a driving and, a single joint and an end for holding an object. The arm can turn in at least one horizontal plane about a vertical main axis disposed in the area of the driving end, and has at least one motor for moving the arm about the main axis and changing the angle between the parts of the arm at the joint.

Abstract: An electrical robot comprises motors for driving a wrist mechanism mounted on a tip end of an arm. The motors are provided at an intermediate portion of a support beam which is provided on a rotary base and supports the arm.

Abstract: A robotic manipulator for supporting a tool or workpiece, the manipulator including at least one rotary linear actuator adapted to be supported by a base and providing for controlled movement of a manipulator link with two degrees of freedom. The robotic manipulator includes a link assembly having one end spherically joined to a movable member for supporting the movable member, the movable member being adapted to support a tool or workpiece. The link assembly is articulated, and the opposite end of the link assembly is supported by a rotary linear actuator for linear movement in a direction transverse to a longitudinal axis of the opposite end of the link assembly and for rotational movement about the axis defined by that linear movement.

Abstract: A digital robot control includes a position/velocity microprocessor control and a torque microprocessor control for each of multiple robot axes. Digital position, velocity and motor current feedback signals are generated from motor sensor signals for use in making microprocessor control calculations. A backup velocity determination is made for each joint motor by the torque microprocessor from the motor current feedback, the motor command terminal voltage and the motor resistance and inductance. The robot is shut down if the difference between the feedback and backup velocity values exceeds a predetermined limit.

Abstract: A multi-jointed robot of high-speed and high-precision motion with reduced stress is disclosed. This robot has a first arm which is pivotal on a base, and a second arm which is pivotal on the first arm. The first arm is directly moved by a first motor on the base, while the second arm is moved by a double parallel link mechanism driven by a second motor which has two shafts at its both ends and which is supported on the base.

Abstract: The invention relates to a robot arm with a work arm connected to it, a connector moved by motors for tools, workpieces, workpiece grippers or gripper change systems, whereby the motors are located at the end of the work arm opposite the connector, and are connected by output connections with gear wheels mounted in a swiveling axis of a swiveling head of the connector. To make such a robot arm flexible, and moreover to guarantee that the work arm is rigid, it is proposed that the axes (D,E,P) of rotation of the elements (work arm 2, swiveling head 23, connector 3) intersect at a common intersection point (A).

Abstract: A manipulator comprises three arms 1 which can pivot at different points on a supporting structure 6 and which can be driven longitudinally to adjust their effective lengths. The longitudinal axes of the three arms intersect at a common point but their lower ends are offset from this point and are pivoted about respective axes which also intersect at the aforementioned common point. They are pivotted to an end effector mounting flange 8 which optionally comprises a fourth arm 11 which slides and pivots on the supporting structure. The fourth arm serves to ensure that the flange 8 always faces at a known orientation. It can also be used in co-operation with suitable sensors to produce signals on lines 15, 16 and 18 to a control unit which drives the arms 1 in their linear directions.

Abstract: The invention relates to an industrial robot of a so-called agile type which has a lower arm (16) with double-sided journalling in a stand (12) consisting of two separated, upright parts (12a, 12b), the arm (16) being pivotable in the space between the stand parts. A pivot shaft (24) for pivoting the upper arm of the robot via a crank and a parallel link rod from one of the stand parts (12a) and through a lead-in opening (28) in the lower arm (16). From the other stand part (12b) there extends a drive shaft (30), which is substantially coaxially opposite to the pivot shaft (24) of the crank (22) and which is connected to the lower arm (16).

Abstract: The foregoing and other objects of the invention are achieved by a drive system which includes a base and a support assembly for rotatably supporting one end of the first arm from said base and for raising and lowering the arm with respect to the base. A second arm has one end rotatably supported at the other end of the first arm and an effector mount is rotatably supported at the other end of the second arm. Drive structure mounted on said base rotate said support assembly. Drive structure mounted at the lower end of said support assembly raise and lower the arm. Drive structure for rotating said second arm and drive structure for rotating said effector are mounted at the upper end of said support. All of said drive structure are mounted within an enclosed housing.

Abstract: An apparatus for automatically extracting objects individually from containers comprises a stand, beneath which a container having the objects that are to be extracted can be erected; an extractor arm movably disposed on the stand in the area above the container; a device for axially extending and retracting the extractor arm; and a device for guiding the grasping element of the extractor arm to various areas in the container interior. In order to attain reliable emptying of the container, especially in the rim areas and corners, a holding device for the extractor arm is provided, which is connected to the stand via a cardan joint suspension system. A drive mechanism is provided for the longitudinal displacement of the extractor arm relative to the holding device, as are further drive mechanisms for pivoting the holding device in two vertical planes at right angles to one another.

Abstract: The present invention relates to the wrist device of a robot which has a speed reducers built in a wrist portion and which attains three degrees of rotating freedom orthogonal to one another, and is characterized in that three transmission shafts penetrating through the interior of an arm are arranged in parallel with one another as power transmission means within the arm.

Abstract: A completely digital robot control operates at a predetermined sampling rate. The robot arm has a plurality of joints with each driven by an electric brushless or brush-type DC motor which is in turn supplied with drive current by a power amplifier bridge circuit having power switches connected therein to supply motor winding current in the forward or reverse direction.Incremental or absolute encoders and tachometers provide for generating digital position and velocity feedback signals generated synchronously with the sampling rate. Digital motor current feedback signals are also generated synchronously with the sampling rate.Paired position/velocity microprocessors generate torque commands for each of the robot axes at the sampling rate in response to the position commands and the position and velocity feedback signals. Paired torque microprocessors generate motor voltage commands for each of the robot axes at the sampling rate in response to the torque commands and the current feedback signals.

Abstract: An electric robot having a base unit which is rotatable about a vertical first axis is provided with a horizontal second axis to which is pivotally mounted a vertical arm. At the other end of the vertical arm, a horizontal arm is mounted which has at the end thereof a wrist for carrying a tool such as a spray gun. Motors for operation of the wrist are placed coaxially with the second axis and are placed inside the shafts for the horizontal and vertical arms. The counterbalancing mechanisms have an axis of motion which is parallel to the second axis, pulleys being used to change the direction of the tensioning cables from tangential to the second axis to parallel to the second axis.

Abstract: A hybrid robotic joint actuator utilizing both the quick response time of an electric motor and the high torque capacity of a pneumatic motor. In one preferred embodiment, the hybrid motor includes a pneumatic rotor coupled to an electric rotor in a common stator housing.

Abstract: An advanced servo manipulator has modular parts. Modular motor members drive individual input gears to control shoulder roll, shoulder pitch, elbow pitch, wrist yaw, wrist pitch, wrist roll, and tong spacing. The modules include a support member, a shoulder module for controlling shoulder roll, and a sleeve module attached to the shoulder module in fixed relation thereto. The shoulder roll sleeve module has an inner cylindrical member rotatable relative to the outer cylindrical member, and upon which a gear pod assembly is mounted. A plurality of shafts are driven by the gears, which are in turn driven by individual motor modules to transmit rotary power to control elbow pitch as well as to provide four different rotary shafts across the bendable elbow joint to supply rotary motive power to a wrist member and tong member.

Abstract: A robotic positioning device has a support structure and a tool implement holding member which is positional within the three dimensional space of the support structure. The tool implement holding member is connected to the support structure utilizing five positioning members. Each of these positioning members is connected to the tool implement holding member. Three of the positioning members are connected to the holding member at a first common center of rotation and the other two positioning members are connected to the holding member at a second common center of rotation. Each of the positioning members is attached to the support structure utilizing a connecting member which allows for the positioning member to freely pivot with respect to the support structure and additionally allows the member to move with respect to the support structure axially along an axis of the member. This is accomplished by moving the members axially toward or away from the support structure.

Abstract: An industrial robot comprises a robot body having an operating portion (13), a driving motor (19) for driving the operating portion (13) and the a handle (29). A casing (21) of the driving motor (19) is secured to an outer wall of the robot body by bolts (25), and an output shaft (26) of the driving motor (19) is connected to the operating portion (13). An inner brake device of the driving motor (19) secures the output shaft (26) to the casing (21) when the driving motor (19) is stopped. If the driving motor (19) is stopped by a malfunction or the like, the bolts (25) are taken out and the handle (29) is attached to the casing (21) of the driving motor (19). By operating the handle (29), the output shaft (26) of the driving motor (19) is rotated together with the casing (21) and the operating portion (13) of the robot is moved.

Abstract: A digital control for a robot having a plurality of arm joints includes an electric motor for driving each of the robot arm joints and a power amplifier operable to supply drive current to each motor. Pulse width modulators generate digital control signals for the power amplifiers.Feedback control loop means for each joint motor includes at least position, velocity and torque control loops operable to control the associated power amplifier. Motor position, velocity and drive current feedback signals are generated for the control loop means for all of the robot axes.A position/velocity microprocessor control executes a planning program to generate a time profile including acceleration, slew and deceleration time segments for implementing each commanded robot program move.

Abstract: A sample transfer device (10) for manipulating a sample (S) in a pair of sealed vacuum chambers (18, 102) comprises a tubular housing (12) made from a magnetically permeable material. The housing has one closed end (14) and another flanged open end (16) for attachment to the vacuum chamber. Located inside the housing is shaft (40) of a square cross section. One end of the shaft is rotatingly connected to an inner permanent magnet (66) which can rotate with respect to the shaft but moves axially together therewith. The other end of the shaft protrudes from the housing into the vacuum chamber (110). The shaft is supported inside the housing by a bevel gear (32) which rotates in a bearing (20) in the housing. The bevel gear (32) has a square opening (38) which guides the above-mentioned square shaft during its axial movements. The gear (32) engages another gear (98) which is attached to an output shaft of a rotary drive unit (80) having its drive element outside the housing.

Abstract: A modular robotic remote manipulator is disclosed. The manipulator utilizes a base module, any number of generally identical but appropriately sized articulating modules, extender modules as may be needed, and an end effector module to accommodate the task assigned to the manipulator. The articulating modules are constructed to afford three different motions about three different axes which intersect at a common point lying between the input end and the output end of the module to effect a range of possible motion for the module output which defines an imaginary sphere. This module is also constructed to provide a separate rotary torque through the output coupling to the next module. The couplers for interconnecting the modules utilize toggle operated spool shaped locks. An end effector or gripper employs a rotating shaft and follower connected through a cable and pulley arrangement to operate the gripper jaws.

Abstract: A remote manipulator for radiation cells and the like. This device is an all electric manipulator for hazardous environments to follow the basic movements of the operator but to provide features to provide extended use of the manipulator beyond the capabilities of the operator when necessary or desired. Identical arm units are removably positioned on opposite sides of a torso to make up the slave unit. Joints in the arms are enclosed in rotable boots. By being identical, the arms may be attached to either side of the torso as well as necessitating fewer replacement parts. The motion of each of the arms is sufficient such that essentially any position of one arm relative to the other arm can be achieved. Many components are interchangeable. Electrically controlled pan/tilt heads mounted on the torso support video cameras to permit remote viewing.

Abstract: The invention is directed to a remotely-operable positioning and carrier aratus for remote-handling equipment for use in large-area cells containing process components. The apparatus is mounted on a lifting device of an overhead bridge crane. The apparatus achieves good positioning of the particular remote-handling equipment even at locations which are poorly accessible. The apparatus includes a horizontal beam which is fixed at an eccentric position thereon to the bottom sheave unit of the lifting device so that the horizontal beam defines a long lever arm and a short lever arm. A receiving lever is pivotally connected to the end of the longer lever arm. The receiving lever has an equipment receiving device at its free end. A displaceable counterweight is arranged on the short lever arm for altering the position of the center of gravity of the apparatus. This apparatus makes it possible also to operate in spaces beneath components present in a rack.

Abstract: A first rotatable arm and a second arm rotatably are connected together at a forward end of the first rotatable arm. A hollow hole portion is formed at a rear end portion of the second arm and has a hollow projecting shaft provided at one side coaxial with it. A supporting plate and a second shaft are provided at the forward end of the first arm for rotatably supporting the hollow projecting shaft and the hollow hole portion, respectively, the supporting plate and the second shaft being separated so as to be on opposite sides of the hole portion. A rotary shaft rotatably is supported by the hollow projecting shaft at a center of the latter and a motor is provided in a position separated from the rotary shaft and connected to it. A decelerator is provided between the rotary shaft and the second arm within the hollow hole portion.

Abstract: A robot joint includes an electric drive motor and step-down transmission ilt into the robot joint housing. The output of the transmission drives a gear to which a mounting flange is coupled. A first part of the robot is coupled to the housing and a second robot part is coupled to the mounting flange. The mounting flange is supported axially and radially in the housing by bearings. The bearings preferably include a conical-roller bearing for providing radial and axial support and a needle bearing for providing axial support. Both bearings are maintained under pretension by a spring, thereby providing a robot joint which is free of play.

Abstract: A multi-axial industrial robot having a compact modular design for the drive system, which can be varied in numerous ways. The robot consists of a column or stand (1), with a rocker arm (7) swingably supported thereon and an outrigger (9) swingably supported on the rocker arm. The modular construction system is achieved by locating in the rocker arm (7) the oscillatory drive (26) for the outrigger (9), as well as the oscillatory drive (16) for the arm itself. Preferably, in the rocker arm are housed the complete drives (16, 26) with only the off-drive members (21, 31) protruding outwardly. Off-drive members (21, 31) are centered and connected non-rotatably with the stand (1) and the outrigger (9). As a result, the rocker arm (7) rotates about the fixed off-drive member (21) with respect to the housing. Drives (16, 26) consist each of a motor (11, 13) and a two-step timing-belt drive (17, 20 and 27, 30), whose second step can be a gear transmission.

Abstract: An electric industrial robot comprises a movable robot assembly (10) forming therein an airtight chamber, and an electric drive unit for driving the robot assembly. The electric drive unit comprises a plurality of motors (36-41). The respective casings (36a-41a) of the motors are disposed within the airtight chamber (30) of the robot assembly. Electric cables (57-62) connected to the motors, respectively, are led through the airtight chamber into a fixed pipe (67) connected to the robot assembly. The interior of the motors and the interior of the airtight chamber are kept at a pressure higher than an atmospheric pressure outside the robot assembly.

Abstract: A workpiece transfer apparatus includes a drive assembly and a transfer arm assembly. The transfer arm assembly is articulated, including a linking arm enclosure pivotally attached to a transfer arm. The linking arm enclosure is mounted on a rotatable sleeve, which in turn is mounted in a bearing assembly which is mountable in a housing. A shaft runs axially through the sleeve and terminates with a pulley within the linking arm enclosure. The transfer arm is coupled to the shaft so that rotation of the sleeve relative to the shaft causes articulation of the transfer arm assembly. A first motor causes rotation of the sleeve and the shaft simultaneously, which effects rotation of the transfer arm relative to the housing. A second motor rotates the sleeve relative to the shaft, causing translation of the transfer arm relative to the housing.

Abstract: An industrial robot assembly comprises a support body including a station portion and a vertically translatable portion. A tapered arm member is mounted to the translatable portion of the support for rotation about a first vertically oriented axis, and an angle lever is mounted to the tapered arm member at a point spaced from the first axis for rotation about a second axis parallel to and spaced from the first axis. A first electric motor is operatively connected to the arm member for rotating that member about the first axis, while a second electric motor is operatively connected to the angle lever for rotating that lever about the second axis. A translatable and rotatably component for carrying grippers or another workpiece-manipulating element is mounted to the angle lever at a point spaced from the second axis. A third electric motor and a lifting drive are operatively coupled to the holder component for translating the component and for rotating that component about a third axis, respectively.

Abstract: An industrial robot assembly comprises a support body including a station portion and a vertically translatable portion. A tapered arm member is mounted to the translatable portion of the support for rotation about a first vertically oriented axis, and an angle lever is mounted to the tapered arm member at a point spaced from the first axis for rotation about a second axis parallel to and spaced from the first axis. A first electric motor is operatively connected to the arm member for rotating that member about the first axis, while a second electric motor is operatively connected to the angle lever for rotating that lever about the second axis. A translatable and rotatable component for carrying grippers or another workpiece manipulating element is mounted to the angle lever at a point spaced from the second axis. A third electric motor and a lifting drive are operatively coupled to the holder component for translating the component and for rotating that component about a third axis, respectively.

Abstract: A playback industrial robot comprises at least one driving device provided with an electric motor having a motor shaft. The driving device comprises a reduction gear mechanism for reducing a rotational speed of the motor shaft of the motor, an output shaft for operating the robot, a clutch mechanism which is in a disengaged state when the output shaft rotates in a teaching mode so that the reduction gear mechanism does not act as a load, a mechanism for putting the clutch mechanism in an engaged state depending on supply and cutting off of the supply of compressed fluid when the teaching mode is started, and a case for accommodating the motor, the output shaft and the above mechanisms. The clutch mechanism comprises a movable clutch member applied with a rotary force depending on forward and backward rotations of the motor and guide members arranged in parallel to the output shaft at positions separated from a center of the output shaft toward an outer peripheral direction thereof.

Abstract: A robotic control arm apparatus or control arm for controlling the position of a control point associated with a controlled element within a reference plane and with respect to two reference points in a work space. The control arm assembly includes at least four link members mutually coupled in series to form a closed loop linkage, each of the link members being coupled about a pivot axis at each end. The apparatus may include a set of roller assemblies affixed to the control arm assembly, each roller assembly including a roller element and an endless belt disposed about the roller elements for driving the controlled element.

Abstract: An expandable and contractable arm is constituted by a plurality of expandable and contractable units and connecting devices including universal joints for serially interconnecting the units into the arm. Each unit includes at least three expandable and contractable operating members in the form of link mechanisms or double thread type expandable and contractable rods, and actuating devices for equally or unequally expanding and contracting the operating members so as to increase or decrease distances between the connecting members while maintaining them in parallel or inclined with respect to each other.

Abstract: The wrist includes a first frameless permanent magnet AC powered motor 22 in a first housing 12 with this motor providing movement of a rack 34 along a translational axis A1 with a second frameless permanent magnet motor 42 carried in a second housing 18 connected to the carriage 16 of which the rack 34 is a part so that the housing 18 is movable along an insertion or translation axis A1 with the second motor 42 providing a rotary output. Both of the motors are AC powered and the rotors thereof are each supported solely by a single X type bearing 28 and 48.

Abstract: An interface receives a high and low voltage signal from a single contact or pin of an output port of a multipurpose microcomputer and uses such signal to control the electrically-powered movement or action of a robot as determined by the programming of the microcomputer. The robot has a sensor connected to the interface and detecting whether or not a preselected condition exists at the robot. The interface sends a high and low voltage input signal to a second single contact or pin of the microcomputer port to communicate the condition of the robot sensed by the sensor. The robot is designed and constructed by the user from interchangeable parts, and the user writes essentially all of the computer programming in a simplified language. By a series of experiments, the student learns computer terminology and programming and robotic technology.

Abstract: A direct drive robot which includes a pedestal having two motors which rotate around a common axis to directly drive rotation of first and of second linking arms which are rotating in a plane perpendicular to this pedestal. The first, inner link is preferably driven through a column directly driven by a first motor rotor, the column supporting the inner end of the link. The second, outer link is driven by the second coaxial direct drive motor through a simple, highly-tensioned belt and pulley arrangement. As a result of this direct drive arrangement, movement is provided about two separate parallel axes by two arms arranged perpendicular to the first axis which mounts the two major driving motors of the robot. These two arms are linked together between this major pedestal and the end effector of the robot, centralizing the driving motors at the main stabilizing pedestal, while providing rapid rotational movement around each of the two axes.