In a stick delivering apparatus I, a receiving space D capable of receiving a stick receiving part 2 of a cart II in a stick arrangement direction Y is formed at a position in close proximity to a support arm device 63 in a stick longitudinal direction X. The support arm device 63 includes a stationary stick supporting member 64 extending in the stick arrangement direction Y and a raising/lowering stick supporting member 65 extending in parallel with the stationary stick supporting member 64 in the stick longitudinal direction X. The stationary stick supporting member 64 and the raising/lowering stick supporting member 65 have serrated receiving tooth portions 64A and 65A, respectively, and the receiving tooth portions 64A and 65A have stick sliding edges 64A-1 and 65A-1 which are inclined with respect to a horizontal plane. The stationary stick supporting member 64 receives the stick by a trough portion serving as a supporting portion of the receiving tooth portion 64A. The receiving tooth portion 65A of the raising/lowering stick supporting member 65 is at a position offset in the stick arrangement direction from the receiving tooth portion 64A of the stationary stick supporting member 64, and the raising/lowering stick supporting member 65 is reciprocatable between a lower position and an upper position with respect to the stationary stick supporting member 64.

This sample rack conveying apparatus is provided with a pusher unit, a linear motion guide, and a conveyance drive mechanism. The pusher unit has a base portion, a moving member, and a base-side guide. The base portion is supported by the linear motion guide so as to be movable in a first guide direction. The moving member is provided with a pusher that pushes a sample rack. The base-side guide supports the moving member such that the moving member is movable in a second guide direction that crosses the first guide direction.

A hydraulic cylinder for a drive unit assembly for a reciprocating floor slat conveyor system has a single tubular barrel divided into two chambers by a center head or plug. The center head is held in position by shrink fitting it into the barrel.

A tube rack transfer device for transferring racks is presented. A first rail extends in a first horizontal direction and a second rail extends in a second horizontal direction orthogonal to the first direction. The second rail moves along the first rail and comprising a transfer head movable along the second rail. The transfer head comprises a control pin to be coupled with one of: an input pusher, translatable in the second direction, for transferring a rack from a carrier to a sampling area of an analyzer; an output pusher for transferring a rack from the sampling area to a carrier; a rack for transferring the rack between different carriers and/or between different positions of the same carrier. An in-vitro diagnostic instrument comprises an analyzer for carrying out tests on biological samples, a sample unit for inputting/outputting racks, a sampling area for withdrawing samples from tubes, and a transfer device.

An inventory management system can include a tray, a tine, and an actuator. The tray can have a body defining a slot extending along a length of the tray and through a front and a rear of the tray. The tine can be sized to fit through the slot. The actuator can move the tine into a deployed position in which the tine is arranged to pass through the slot and contact an item in the tray to cause the item to fall out of the rear of the tray as tray moves by the tine. The actuator may also be capable of moving the tine into a stowed position in which the tine is arranged to avoid extending through the slot as the tray moves by the tine.

An inventory management system can include a tray, a tine, and an actuator. The tray can have a body defining a slot extending along a length of the tray and through a front and a rear of the tray. The tine can be sized to fit through the slot. The actuator can move the tine into a deployed position in which the tine is arranged to pass through the slot and contact an item in the tray to cause the item to fall out of the rear of the tray as tray moves by the tine. The actuator may also be capable of moving the tine into a stowed position in which the tine is arranged to avoid extending through the slot as the tray moves by the tine.

An automatic load table and related method are provided. The automatic load table utilizes a movable loading arm and a riser assembly with a stepped configuration. The movable loading arm is operable to move billets in a loading direction along the stepped configuration of the riser assembly. The movable loading arm is capable of lifting and separating adjacent billets in a single lifting motion.

Apparatuses, systems, and methods of manufacturing are described that provide a conveying module and conveying table for item transport. An example conveying module include a frame and an item transport plate that supports one or more items received thereon. The conveying module further includes a conveying drive motor supported by the frame and operably coupled to the item transport plate. The conveying drive motor causes rotation of the item transport plate about the conveying drive motor. The conveying module further includes a tilt adjustment mechanism that adjusts a tilt direction of the item transport plate relative to the frame. The conveying module also includes, in some instance, a tilt drive mechanism that controls operation of the tilt adjustment mechanism.

Apparatuses, systems, and methods of manufacturing are described that provide a conveying module and conveying table for item transport. An example conveying module include a frame and an item transport plate that supports one or more items received thereon. The conveying module further includes a conveying drive motor supported by the frame and operably coupled to the item transport plate. The conveying drive motor causes rotation of the item transport plate about the conveying drive motor. The conveying module further includes a tilt adjustment mechanism that adjusts a tilt direction of the item transport plate relative to the frame. The conveying module also includes, in some instance, a tilt drive mechanism that controls operation of the tilt adjustment mechanism.

A device for transferring components includes a transfer assembly and a drive assembly. The transfer assembly has a transfer track transferring a plurality of components therein. The transfer track has an operation position for operating the components. The drive assembly has a first drive mechanism transferring a first set of components of the components at the operation position in the transfer track and a second drive mechanism transferring a second set of components of the components at the operation position in the transfer track. The first drive mechanism and the second drive mechanism in turn drive the first set of components and the second set of components, continuously transferring the components.