The horizontal articulated robot includes a platform, a first arm which is coupled to the platform, which moves along a first linear-motion axis with respect to the platform, and which rotates around a first rotational axis parallel to the first linear-motion axis, a second arm which is coupled to the first arm, which moves along a second linear-motion axis different in direction from the first linear-motion axis with respect to the first arm, and which rotates around a second rotational axis parallel to the first rotational axis, a third arm which is coupled to the second arm, and which rotates around a third rotational axis perpendicular to the first linear-motion axis, and a fourth arm which is coupled to the third arm, and which rotates around a fourth rotational axis perpendicular to the third rotational axis.

A boom working device has a boom, mounted on and extending from a boom support, on which an end effector mounting interface is formed. The boom is equipped with two linear output structures, each in engagement with one of two drive wheels of the boom support. With respect to the boom support, the boom is both pivotable around a main axis and also capable of linear movement at right-angles to the main axis. Through harmonised rotary actuation of the drive wheels an operating movement of the boom may be generated, consisting either of a pivoting movement alone or of a linear movement alone or of the pivoting movement with simultaneously superimposed linear movement.

A fully autonomous mobile robot is provided that transports items from one area to another. The mobile robot includes a variety of mechanisms that capture an item from a first surface and moves the item within the confines of the mobile robot. The item can then be transported to another surface either within the confines of the mobile robot or to another location.

An example test head manipulator includes a tower having a base and a track, where the track is vertical relative to the base, and arms to enable support for the test head. The arms are connected to the track to move the test head vertically relative to the tower, and the arms are configured to control rotation of the test head. Each of the arms includes a cam that is rotatable, and at least one plunger in contact with the cam and that is configured to contact the test head. Rotation of the cam is controllable to move the at least one plunger to offset an uncontrolled rotation the test head.

A welding manipulator for holding a welding head comprised of a base, rotating column and swivel boom is shown. The column includes a novel rotating apparatus comprised of a lockable rotary bearing, rotary housing, clamp shell and brake handle. In the unlocked position, the column rotates smoothly and easily around the base. In the locked position, the clamp shell engages and disengages the rotary bearing, thus locking the column in place.

The present welding manipulator also discloses a boom attached to the column with a swivel mount. This swivel mount allows the boom to be locked into an operating position or a shipping position for more compact shipping or storage. The disclosed welding manipulator also includes tracks on the column and a motorized screw drive to vertically position the boom.

The transport system has a transport vehicle. The transport vehicle includes two racks, each of the two racks being configured to accommodate a plurality of boxes, and a drive arm that is disposed at a position between the two racks and that moves each of the boxes in and out of each of the racks. The transport vehicle moves each of the boxes in and out of each of the two racks by changing an orientation of the drive arm.

A boom working device has a boom, mounted on and extending from a boom support, on which an end effector mounting interface is formed. The boom is equipped with two linear output structures, each in engagement with one of two drive wheels of the boom support. With respect to the boom support, the boom is both pivotable around a main axis and also capable of linear movement at right-angles to the main axis. Through harmonised rotary actuation of the drive wheels an operating movement of the boom may be generated, consisting either of a pivoting movement alone or of a linear movement alone or of the pivoting movement with simultaneously superimposed linear movement.

Disclosed is an invention for dispensing multiple medications to a patient over an extended period of days up to several times a day. The system includes a carousel with storage bins and a delivery bin on its periphery. A vacuum system and a vacuum probe with a vacuum cup at the end of the probe for grasping and holding by an induced vacuum a dosage of medication located in a storage bin and moving it to a dispending or delivery bin. The system includes a programmable computer to control the system and sequence the proper dispensing of the medication at the predesignated times.

The horizontal articulated robot includes a platform, a first arm which is coupled to the platform, which moves along a first linear-motion axis with respect to the platform, and which rotates around a first rotational axis parallel to the first linear-motion axis, a second arm which is coupled to the first arm, which moves along a second linear-motion axis different in direction from the first linear-motion axis with respect to the first arm, and which rotates around a second rotational axis parallel to the first rotational axis, a third arm which is coupled to the second arm, and which rotates around a third rotational axis perpendicular to the first linear-motion axis, and a fourth arm which is coupled to the third arm, and which rotates around a fourth rotational axis perpendicular to the third rotational axis.

The invention relates to a fuel cell membrane handling device comprising a first membrane storage station (A1) and a receiving station (C) as well as a first manipulator (B1) comprising means (68) for gripping a membrane (12) from a free face thereof, the first manipulator (B1) being articulated so as to be capable of moving between a position for taking a membrane (12) from the storage station (A1) and a position for placing a membrane (12) in the receiving station (C). According to the invention, the receiving station (C) comprises a tray for receiving a membrane (12) comprising at least one opening (C2) wherein the gripping means (68) and a portion of the manipulator are capable of fitting into a first position for placing a membrane (12) wherein the membrane (12) is received on the receiving tray (C1).