A tool assembly for attaching to two carriages of a carriage guide rail system; wherein the two carriages are movable along the carriage guide rail relative to one another, the tool assembly having a base and a linear actuator movable relative to the base; wherein the base has a first connector for attaching to one of the two carriages; wherein the linear actuator has a second connector for attaching to the other one of the two carriages; wherein the base has a first base portion attaching to the first connector; wherein the first base portion is arranged between at least a part of the linear actuator and the two connectors in a direction perpendicular to the carriage guide rail.

In one aspect, the present disclosure provides a robot gripper with a closing mechanism that while providing a desirable closing speed avoids exerting a force on the rigid object which is greater than the holding force required to hold the rigid object in the gripper. In another aspect, the present invention provides a robot gripper capable of detecting a slip or loss of an object held by the gripper. In an alternative aspect, the present invention provides a robot gripper capable of being hand guided. In another aspect, the invention provides a robot gripper brake drive circuit with faster operation. In one other aspect, the invention provides a connector for connecting a robot end effector to a robot arm with an adjustable cable.

A gripping and positioning assembly for transporting a holding device between different positions includes a coupling arrangement for separably coupling the gripping and positioning assembly to the holding device and holding the holding device securely during transport. The gripping and positioning assembly has an integrated drive for moving the holding device between a hold and a release position to allow the operation of the holding device between a holding and a release position as well as a transporting of the holding device. The coupling arrangement has one or more aligning elements to provide an interlocking connection to the holding device.

An automatic or semi-automatic preparation system process is provided for forming a medicament solution from a vial containing one of a liquid and a non-liquid material.

A telescoping extendable boom and a foldable telescoping extendable boom for transporting an item, are disclosed. The foldable telescoping extendable boom having tubular elements (12) and (14) and (15, 17, 18, 19) and (20) each arranged with a longitudinally extending track (25, 29) inside the tubular element. Each longitudinally extending track (25, 29) supports a single shuttle (26) and (30) respectively, internally inside its tubular element (17) and (15), respectively, for movement therealong. Each shuttle (26) and (30) is equipped with a clamp (27) and (30) to selectively clamp the item (298). The longitudinally extending tracks (25, 29) of immediately connecting telescoping tubular elements (17) and (15) are located opposite each other. The inner tubular elements inside said telescoping extendable boom are arranged at their near ends to allow their shuttles to access shuttles of outer tubular elements to enable the clamps (27) and (31) thereof to transfer a said item (298) therebetween.

A robot hand is designed to open or close fingers using a linear actuator disposed in a housing. The robot hand has linear motion shafts extending from inside to outside the housing through guide holes formed in a wall of the housing. Each of the fingers includes a base portion and a tip portion. The base portions are secured to the linear motion shafts outside the housing. The tip portions are bent inwardly from the base portions in directions in which they approach each other and then extend toward tips of the fingers. A sealing member is disposed between each of the linear motion shafts and a corresponding one of the guide holes to hermetically isolate the inside of the housing from the outside thereof. This structure achieves an increased degree of sealing of the housing and is capable of having an increased opening or closing stroke of the fingers.

An operation tool as a gripping device includes a first arm and a second arm that move in directions opposite to each other, and a third arm for engaging with a workpiece. The operation tool includes a gear and a gear moving cylinder for causing the gear to move to a first position, a second position, and a third position between the first position and the second position. The first arm and the second arm move when the gear is disposed at the first position. The third arm moves when the gear is disposed at the second position. The gear is separated from all of the arms when the gear is disposed at the third position.

A gripper includes at least one first gripper finger adjustably mounted to a gripper main body by a gripping finger mount, at least one second gripper finger cooperating with the first gripper finger, and a motor-drivable transmission configured to adjust the at least one first gripper finger relative to the gripper main body and the at least one second gripper finger such that a clamping force is generated, whereby an article can be held in a clamped manner by the gripper. The transmission includes a first transmission member connected to the first gripper finger, and a second transmission member mounted on the gripper main body by a transmission-member bearing arrangement having a first transmission member bearing configured to absorb the transmission-bearing reaction force that acts in a direction of the clamping force. The transmission-member bearing arrangement includes a sensor configured to sense the transmission-bearing reaction force.

A gripping device (I0) for gripping, translationally moving, and rotating a laboratory vessel (40) for samples, microorganisms or cell cultures. A support unit (12), a bearing body (14), and a gripper (16) that is rotatably mounted in the bearing body (14) are employed. The gripper (16) has a rotating body (34), in which gripping fingers (36, 38) are arranged, at least one of which is pivotably mounted in the rotating body (34). The rotating body (34) interacts with a rotary drive (30) for the rotational movement relative to the bearing body (14). The bearing body (14) is mounted in the support unit (12) in a translationally movable manner and interacts with a movement drive for the translational movement of the bearing body (14) with the rotating body with respect to the support unit (12).

A controller for a commissioning device for storing piece goods such as medicinal packages is provided. The controller includes a delivery table that extends in a first direction, two elongated clamping jaws disposed above the delivery table, the jaws having clamping surfaces that face one another, and a clamping jaw guide apparatus with a frame structure, at least one first and one second guide which are separated from one another in the first direction and extend in a second direction, and at least four clamping jaw carriages which are coupled to the guides and driven in the second direction. Two clamping jaw carriages each are associated with a guide and at least two clamping jaw carriages separated from one another in the first direction are coupled to one clamping jaw, respectively.