Abstract: A skid steer loader comprises: a main frame assembly (1); a boom assembly (2); a pair of right and left travel assemblies (3); a cabin (4) mounted so as to be capable of being tilted; an engine (5) located so as to be oriented in a longitudinal direction and at a location closer to a rear; a hydrostatic transmission (8) and an oil pump (9) connected to a front portion of the engine (5). A utility space is defined between the oil pump (9) and a bottom (1a) of the main frame assembly (1). A fuel tank (6) and a hydraulic tank (7) are located on the bottom of the main frame assembly (1) and to one lateral side and to the other lateral side respectively of the engine (5) and forwardly of the engine (5) in a vicinity of the oil pump (9). At least one of the fuel tank (6) and the hydraulic tank (7) has a laterally extending portion that projects into the utility space.

Abstract: A bucket position indication mechanism is provided for a material handling machine. The material handling machine includes a bucket and an operator's control station. The bucket position indication mechanism includes at least one position indicating element attached to the bucket at a position that is viewable by an operator at the operator's control station when a bottom plate of the bucket is aligned with a ground surface and at least a portion of the position indicating element extending in a direction parallel to the bottom plate of the bucket.

Abstract: A robotic arm compensator includes a housing, a lock mandrel, a first lock slide, a second lock slide and an instrument attached to the lock mandrel. A method of using the robotic arm compensator includes moving the first and second lock slides in a direction toward each other to engage the lock mandrel in a first state and moving the lock slides apart from each other to disengage the lock mandrel in a second state for providing exceptional radial movement, large lateral travel relative to overall size, zero force to utilize the compensation travel and no axial compressibility.

Abstract: In the present invention, through a provision of a relay stand including a first relaying point, a second relaying point and a plurality of work mounting bases, a discharge/feed process of works between the relay stand and the work feed container and the work accommodation container is performed at the first relaying point and a load/unload process of works between the relay stand and the plurality of work inspection machines is performed at the second relaying point.

Abstract: Methods and apparatus are provided for the use of a dual Selective Compliant Assembly Robot Arm (SCARA) robot. In some embodiments two SCARAs are provided, each including an elbow joint, wherein the two SCARAs are vertically stacked such that one SCARA is a first arm and the other SCARA is a second arm, and wherein the second arm is adapted to support a first substrate, and the first arm is adapted to extend to a full length when the second arm supports the first substrate, and wherein the first substrate supported by the second arm is coplanar with the elbow joint of the first arm, and the second arm is further adapted to move concurrently in parallel (and/or in a coordinated fashion) with the first arm a sufficient amount to avoid interference between the first substrate and the elbow joint of the first arm. Numerous other embodiments are provided.

Abstract: A system is provided for sensing, orienting, and transporting wafers in an automated wafer handling process that reduces the generation of particles and contamination so that the wafer yield is increased. The system includes a robotic arm for moving a wafer from one station to a destination station, and an end-effector connected to an end of the robotic arm for receiving the wafer. The end-effector includes a mechanism for gripping the wafer, a direct drive motor for rotating the wafer gripping mechanism, and at least one sensor for sensing the location and orientation of the wafer. A control processor is provided for calculating the location of the center and the notch of the wafer based on measurements by the sensor(s). Then, the control processor generates an alignment signal for rotating the wafer gripping mechanism so that the wafer is oriented at a predetermined position on the end-effector while the robotic arm is moving to another station.

Abstract: A pivoted coupling member of a two-piece boom can be shared with standard booms. The boom comprises a first boom having, on the base end side, a pivoted coupling member that is pivotably coupled to a boom support section, and a second boom in which the base end side is pivotably coupled to the distal end side of the first boom and in which an arm is pivotably coupled to the distal end side. In the boom, the lateral width of the main body portion 51 of the second boom (18B) is designed to be smaller in the second region (Y) of the base end side than the first region (X) of the distal end side, the base end side of the second region (Y) of the second boom (18B) in inserted between the left and right side walls (29) of the distal end side of the first boom (18A), and the second boom (18B) is pivotably coupled to the first boom so as to be capable of rotating about the lateral axis.

Abstract: A transfer apparatus includes a stationary base, a lift base, a lifting mechanism for vertically moving the lift base, a rotary base mounted to the lift base, a rotating mechanism for rotating the rotary base about a vertical rotation axis, a linear moving mechanism supported by the rotary base, and a work hand supported by the linear moving mechanism. The lifting mechanism includes a slide guide mechanism for vertical movement of the lift base, and first and second screw-feeding mechanisms. Each screw-feeding mechanism includes a rotatable vertical screw shaft, and a nut member provided on the lift base and screwed onto the screw shaft. The first and the second screw-feeding mechanisms are spaced from each other, with the rotation axis of the rotary base being located between the first and the second screw-feeding mechanisms.

Abstract: A retrofittable lifting apparatus for use on an articulated robotically controlled device is disclosed. The lifting apparatus includes a structure for mating the apparatus to the robotic device and a mechanism for the remotely controlled lifting of an ordnance or other object. Actuation of the lifting mechanism may be provided by existing sources of motion on the robotic device, or by additional sources of motion attached to the robotic device.

Abstract: A variable counterweight system includes a counterweight and at least one linear transfer device. The counterweight preferably includes a plurality of individual counterweight members. Each linear transfer device preferably includes a moving track and a drive device. The moving track could be a chain or a belt. The drive device is preferably a hydraulic, electric or pneumatic motor. The moving track is preferably retained in a guide track. A control unit receives input from at least one vertical sensor. If an attachment or a boom is in an elevated position, then the control unit powers the at least one drive device to move the counterweight to a rear of the skid steer. If the attachment or boom is in a lowered position, then the control unit powers the at least one drive device to move the counterweight to a front of the skid steer.

Abstract: Bosses extending in the boom width direction are provided in a front end part of a main boom body rotated upward, and hooks opening downward are provided in a base end part of a front boom body rotated downward. In a state that the bosses and the hooks are engaged with each other, a scooping action is performed so as to match pin holes thereof. The above hooks and the bosses are arranged so as to satisfy a condition that in a state that an angle between both boom bodies is a maximum angle at the time of work, the hooks and the bosses are moved away from each other and a distance between the hooks and the bosses is increased as the angle is reduced from the maximum angle.

Abstract: In a wheel loader 3, an angle formed by a first line segment L1 connecting a pivot position Y on a boom 10 of a bell crank 11 and a pivot position X on a connecting link 13 and a second line segment L2 connecting the pivot position Y on the boom 10 of the bell crank 11 and a pivot position W on a tilt cylinder 12 is set in a range from 0 degree to 180 degrees on the attachment 20, 30 side, the attachment can be selected from a plurality of types such as a bucket 20 and a fork 30 for use, and each of the attachment 20, 30 that is different from each other has a different pivot position on the connecting link 13 relative to the pivot position on the boom 10 as a reference point.

Abstract: A vehicle supported mine item positioning apparatus for placing, for example, heavy mining conveyor belt items such as roller assemblies, conveyor frame side rails, frame sections or the like in precise positions for attachment to other conveyor structure, wherein the vehicle can get into cramped quarters in the mine alongside the conveyor and extend, retract, rotate and further manipulate an item pick-up crane mounted on the vehicle, whereby the crane with item pick-up means mounted on an end thereof can pick up and place, e.g., a roller assembly in a precise position and posture on a conveyor frame for making said attachment, and further in a preferred embodiment, the apparatus is provided with second crane means for lifting a moving conveyor belt off of a roller assembly for replacement of said assembly with or without stopping the belt, whereby worker lifting and manipulation of heavy roller assemblies or other heavy mining structures is eliminated.

Abstract: A work handling apparatus includes a pair of traveling guides (20, 20?) provided so as to extend in a front-and-rear direction X at right and left sides, and a pair of direct-acting arms (30, 30?) provided so as to travel independently on the pair of traveling guides. The direct-acting arms are extendable from contracted positions, at which the arms oppose each other and avoid mutual interference in a right-and-left direction Y, to extended positions at which the arms overlap with each other. An operation spot (41) is arranged in an operation area (40) sandwiched between the pair of traveling guides for performing a predetermined operation to a work. Also, work tools (60, 60?) are attached to the pair of direct-acting arms (30, 30?), respectively, for transferring the work between a work storage area (50) and the operation spot (41) or performing an operation after transfer.

Abstract: An apparatus for transferring and securing a substrate is shown. A pressure source is provided that is adapted to provide positive and negative pressure. A vacuum chuck is provided having a top side with a plurality of vacuum chuck portals formed therein. Each vacuum chuck portal is in fluid communication with the pressure source. The substrate is secured to the top side of the vacuum chuck when the pressure source provides negative pressure to the vacuum chuck portals. An intermediate member that selectively cooperates with the vacuum chuck to support and transfer the substrate between the vacuum chuck and the intermediate member is provided. The intermediate member has a plurality of receiving spaces and a plurality of transfer members. The receiving spaces and transfer members are adjacent to one another in an alternating pattern, and each transfer member has a top side with a plurality of transfer member portals formed therein.

Abstract: In a work machine 1, an angle ? formed by a first line segment L1 connecting a pivot position Y of a bell crank 11 on a boom 10 and a pivot position X of the bell crank 11 on a connecting link 13, and a second line segment L2 connecting the pivot position Y of the bell crank 11 on the boom 10 and a pivot position W of the bell crank 11 on the tilt cylinder 12 on a bucket 20 side is 176 (deg) or less, an angle ? formed by the second line segment L2 and a line segment L3 connecting the pivot position W of the bell crank 11 on the tilt cylinder 12 and a pivot position Z of the tilt cylinder 12 on a working structure is 72.3 (deg) or less, and, in a case where the bucket 20 is set at a top position, a lowering angle ? of a front end of a lower surface of the bucket 20 is 4.5 (deg) or less.

Abstract: A system includes an end effector, a robotic wrist for orienting the end effector; and a robotic arm for positioning the end effector. The robotic arm is foldable into a stack. The robotic wrist is mounted to a last link of the robotic arm.

Abstract: A material handling system for engaging and transporting material. The material handling system includes a mouth and a hydraulic actuator for pivoting a tooth within the mouth. Once a material has been positioned within the mouth, the hydraulic piston actuates the tooth to secure the material within the mouth. The tooth is preferably configured and oriented to move into tighter engagement with the material as gravity or other forces attempt to remove the material from the mouth. The hydraulic piston allows an operator to release the tooth whenever desired. The material handling system includes a vehicle mounted boom coupled to the mouth so that material engaged by the mouth may be transported to another desired location.

Abstract: In a robotic assembly, a body adapted for mounting on an arm is provided. A connection is adapted to couple the body and an end effector to allow deflection of the end effector with respect to the body between an open position and a closed position. A conduit allows fluid flow between the body and the end effector. A seal is adapted to engage the conduit to provide a fluid seal when the end effector is in the closed position and allow fluid flow when the end effector is in the open position. Further, end effector deflection can be detected based on the fluid flow and utilized to regulate movement of the robotic assembly.

Abstract: A manipulator includes an end effector, a support member that supports the end effector, and a fixing member provided to the support member and made of a tube-shaped flexible film with a space therein. In the manipulator, a fluid is supplied to the space of the fixing member to inflate the fixing member so that a flexible cover for covering the end effector is fixed to the support member. Accordingly, cleanness of the end effector is restored.