A system for manufacturing radionuclide generators includes an enclosure defining a radioactive environment. The enclosure includes radiation shielding to prevent radiation within the radioactive environment from moving to an exterior of the enclosure. The system also includes a conveyance system having a forward track and first carriages positioned on and movable along the forward track for conveying racks in a first direction. The conveyance system also includes a first walking beam mechanism magnetically coupled to the first carriages to move the first carriages. The conveyance system further includes a return track and second carriages positioned on and movable along the return track for conveying racks in a second direction opposite the first direction. The forward track and the return track form a loop.

A system for manufacturing radionuclide generators includes an enclosure defining a radioactive environment. The enclosure includes radiation shielding to prevent radiation within the radioactive environment from moving to an exterior of the enclosure. The system also includes a conveyance system having a forward track and first carriages positioned on and movable along the forward track for conveying racks in a first direction. The conveyance system also includes a first walking beam mechanism magnetically coupled to the first carriages to move the first carriages. The conveyance system further includes a return track and second carriages positioned on and movable along the return track for conveying racks in a second direction opposite the first direction. The forward track and the return track form a loop.

A rear suspension member (RSM) transfer assembly for transferring an RSM from a sub-assembly line to a main assembly line includes a first RSM lifter, an RSM buffer, and a second RSM lifter. The first RSM lifter is configured to travel laterally between the sub-assembly line and the main assembly line. The first RSM lifter includes a lifting body and a rotatable arm configured to retrieve the RSM from the sub-assembly line and transport the RSM to the main assembly line. The RSM buffer is configured to receive the RSM from the first RSM lifter and transport the RSM through a plurality of resting positions. The second RSM lifter is configured to receive the RSM from the RSM buffer and raise the RSM into position for installation on a vehicle.

An apparatus (1) for the clocked longitudinal transport of workpieces (11) between processing stations in a transfer press. The apparatus has, at least on one side, a first (2) and a second (3) longitudinally movable control element as a control group (2, 3), wherein two control elements (2, 3) are mounted to be movable relative to each other solely in the longitudinal direction, and the control elements (2, 3) are driven via a common shaft (58). The first control element is a gripper rod (2) for the longitudinal transport of workpieces (11) between the processing stations, and gripper elements (4), offset in the longitudinal direction by the distance between the processing stations, are mounted in the gripper rod (2) and can be moved solely in the transversal direction. The second control element is a thrust rod (3) which forcibly controls the transversal movement of the at least two gripper elements (4).

An apparatus (1) for the clocked longitudinal transport of workpieces (11) between processing stations in a transfer press. The apparatus has, at least on one side, a first (2) and a second (3) longitudinally movable control element as a control group (2, 3), wherein two control elements (2, 3) are mounted to be movable relative to each other solely in the longitudinal direction, and the control elements (2, 3) are driven via a common shaft (58). The first control element is a gripper rod (2) for the longitudinal transport of workpieces (11) between the processing stations, and gripper elements (4), offset in the longitudinal direction by the distance between the processing stations, are mounted in the gripper rod (2) and can be moved solely in the transversal direction. The second control element is a thrust rod (3) which forcibly controls the transversal movement of the at least two gripper elements (4).

A packaging apparatus (1) and method is provided. The packaging apparatus comprises: a support platform (100) for supporting packaging containers (10) positioned thereon, the support platform comprising a support portion moveable between a first position and a second position; and a belt transport arrangement (800) for transporting packaging containers away from the support platform (100) in a first transport direction (52); the belt transport arrangement (800) comprising a belt arrangement comprising a pair of belts (802a, 802b), the pair of belts defining opposing contacting surfaces for contacting packaging containers. The apparatus is operable between: a first configuration wherein the support portion is in the first position to support one or more packaging containers positioned thereon; and a second configuration wherein the support portion is in the second position and contacting surfaces of the belts engage the one or more packaging containers.

A method and a feeding apparatus for feeding spacers for cigarette packs are disclosed, in which each spacer comprises a substantially rectangular flat body, the spacers being insertable in cartons for cigarette packs to space out packs with dimensions smaller than the standard dimensions; the spacers are stacked on a pallet that is positioned in a withdrawal station; the stacks of spacers are withdrawn from the withdrawal station and transferred to a respective hopper by passing each stack of spacers through an upper opening of the hopper, to then unload the spacers one by one through a lower opening of the hopper.

A method and a feeding apparatus for feeding spacers for cigarette packs are disclosed, in which each spacer comprises a substantially rectangular flat body, the spacers being insertable in cartons for cigarette packs to space out packs with dimensions smaller than the standard dimensions; the spacers are stacked on a pallet that is positioned in a withdrawal station; the stacks of spacers are withdrawn from the withdrawal station and transferred to a respective hopper by passing each stack of spacers through an upper opening of the hopper, to then unload the spacers one by one through a lower opening of the hopper.

A plant for packaging capsules comprising a main frame (20) on which is positioned a system for moving capsules (30) to make one or more capsules (12) advance along a first predetermined axial direction (A-A) from an inlet (22) to an outlet (24). The plant comprises a plurality of operating stations (200, 201, 203) for packaging a substance into a plurality of capsules (12), wherein the system for moving capsules (30) comprises a movement device that comprises a pair of sliding profiles (36) that extend along said first predetermined axial direction (A-A) and are connected to the main frame (20), a first movable frame (87, 88, 89) movable in transverse direction with respect to the first predetermined axial direction (A-A), a driving member mounted slidable on an upper movable beam (88) of the first movable frame (87, 88, 89) along said predetermined axial direction (A-A) and positioned between the pair of sliding profiles (36). Said driving member comprises a plurality of drive pins (212) particularly suited to drive a capsule transport support (100) containing said one or more capsules (12).

A plant for packaging capsules comprising a main frame (20) on which is positioned a system for moving capsules (30) to make one or more capsules (12) advance along a first predetermined axial direction (A-A) from an inlet (22) to an outlet (24). The plant comprises a plurality of operating stations (200, 201, 203) for packaging a substance into a plurality of capsules (12), wherein the system for moving capsules (30) comprises a movement device that comprises a pair of sliding profiles (36) that extend along said first predetermined axial direction (A-A) and are connected to the main frame (20), a first movable frame (87, 88, 89) movable in transverse direction with respect to the first predetermined axial direction (A-A), a driving member mounted slidable on an upper movable beam (88) of the first movable frame (87, 88, 89) along said predetermined axial direction (A-A) and positioned between the pair of sliding profiles (36). Said driving member comprises a plurality of drive pins (212) particularly suited to drive a capsule transport support (100) containing said one or more capsules (12).