The invention relates to a vertical diverter for a conveyor system having a lower conveyor track and an upper conveyor track, wherein the vertical diverter is provided and designed for vertically connecting the two conveyor tracks, and the vertical diverter has a lower diverter track and an upper diverter track. The vertical diverter is characterized in that the lower diverter track is shorter than the upper diverter track, that the lower diverter track is provided and designed to be lowered at least at one end in order to make room for the connection of the end of the upper diverter track to be lowered, and that the upper diverter track is provided and designed to be lowered at least at one end, and that the lowered end of the upper diverter track rests where the unlowered end of the lower diverter track previously rested.

Apparatus for automatically unstacking a pallet on which at least two stacks of blanks are arranged. The apparatus comprises an unstacking station which is configured for receiving a pallet on which are arranged at least two stacks of blanks in collapsed condition. The unstacking station is further configured for taking off one by one individual blanks from the at least two stacks of blanks which are on a pallet received in the unstacking station. The apparatus further includes a feed track for conveying pallets. The feed track links up by a discharge end with the unstacking station for the purpose of feeding a pallet with stacks of blanks to be unstacked to the unstacking station. Further, the apparatus includes a blank main discharge assembly for discharging individual blanks to a further processing station.

Apparatus for automatically unstacking a pallet on which at least two stacks of blanks are arranged. The apparatus comprises an unstacking station which is configured for receiving a pallet on which are arranged at least two stacks of blanks in collapsed condition. The unstacking station is further configured for taking off one by one individual blanks from the at least two stacks of blanks which are on a pallet received in the unstacking station. The apparatus further includes a feed track for conveying pallets. The feed track links up by a discharge end with the unstacking station for the purpose of feeding a pallet with stacks of blanks to be unstacked to the unstacking station. Further, the apparatus includes a blank main discharge assembly for discharging individual blanks to a further processing station.

An article conveying device 4 includes a movable conveyer 12 for conveying a culture vessel 3 (article) and longitudinal mover 13b for moving the movable conveyer 21, and a conveyer driving motor 14 is provided separately from the movable conveyer 12, and a driving magnet MA rotated by a driving shaft 32 driven by the conveyer driving motor 14 and a driven magnet MB provided on the movable conveyer 12 and connected to the driving magnet MA by a magnetic force in a non-contact manner are provided. A plurality of the driven magnets MB is provided along a moving direction of the movable conveyer 12 by the longitudinal mover 13b, and an interval between the plurality of the driven magnets MB is matched with a moving distance of the movable conveyer 12 by the longitudinal mover 13b.

The invention relates to a switch (1) of a transport system for a movable transport element (T), where the switch (1) comprises a main track (3) and a secondary track (4) branching off. where the movable transport element (T) can be guided from a transition region (2), in which the secondary track (4) branches off from the main track (3), optionally along the main track (3) or transferred into the secondary track (4), where one or more linear motor sections (5a, 5b, 5c, 5d) are respectively provided at the main track (3) and the secondary track (4) for moving the movable transport element (T), where a normal force is present between the movable transport element (T) and the adjacent linear motor section or the adjacent linear motor sections (5a, 5b, 5c, 5d), characterized in that devices for altering the normal force are provided in the transition region. The invention also relates to a transport system comprising such a switch and a transport element for such a transport system.

The lifting and lowering apparatus includes a plurality of shelf members 6 and 7 and a lifting and lowering mechanism 8. The shelf members 6 and 7 respectively include placing tables A and B positioned on different heights, and each placing table is provided with a conveying unit 10. The shelf members 6 and 7 are lifted and lowered by the lifting and lowering mechanism 8, whereby the placing table A (B) of the shelf member 6 (7) which is one of the shelf members 6 and 7 is adjusted to be on the same height as the placing table B (A) of the other shelf member 7 (6), and with this state, an object is transferred from the placing table of one of the shelf members to the placing table of the other shelf member. The shelf members 6 and 7 are again lifted and lowered to adjust the placing table B (A) of the other shelf member 7 (6) to be on the same height as the placing table A (B) which belongs to the shelf member 6 (7) and which is positioned on a different height, returns the object to the shelf member 6 (7), and transfers the object to the placing table A (B) which is positioned on a different height from the previous placing table A (B).

According to various embodiments, the transporting arrangement may have the following: a multi-level transporting section, which has a first transporting level and a second transporting level (102b) arranged above it; a feeding conveyor for feeding a container in the direction of the multi-level transporting section; a distributing conveyor between the feeding conveyor and the multi-level transporting section, the distributing conveyor (106) being mounted at the multi-level transporting section pivotably between the first transporting level and the second transporting level and intended for distributing the container to the first transporting level or the second transporting level; a sensor arrangement, which is configured to sense at least one physical property of the container; a pivoting control device, which is configured to pivot the distributing conveyor between the first transporting level and the second transporting level if the at least one property satisfies a predetermined criterion.

Present embodiments include a linear drive transport system. The system includes a plurality of fixed tracks and a junction track disposed on a conveyor configured to align the junction track with each of the plurality of fixed tracks. The plurality of fixed tracks and the junction track include one of electromagnetic coils or permanent magnets arranged in series along the respective plurality of fixed tracks and the junction track. Further, present embodiments include a plurality of movers configured to move along the fixed tracks and configured to transition between each of the plurality of fixed tracks and the junction track when aligned, wherein the movers comprise the other of the electromagnetic coils or the permanent magnets.

A conveyor device for a transport container for spectacle lenses includes a linear conveyor unit for conveying the transport container in a rectilinear direction, a rotary unit for rotating the linear conveyor unit, and a first housing element for the rotary unit. The first housing element includes a plate and rotates conjointly with the linear conveyor unit in the direction of rotation. The first housing element that conjointly rotates in the rotation of the linear conveyor unit has a first opening through which the linear conveyor unit penetrates the plate and wherein the linear conveyor unit is spaced apart from the plane by an assigned gap dimension, which is smaller than or equal to 5 mm.

A conveyor device for a transport container for spectacle lenses includes a linear conveyor unit for conveying the transport container in a rectilinear direction, a rotary unit for rotating the linear conveyor unit, and a first housing element for the rotary unit. The first housing element includes a plate and rotates conjointly with the linear conveyor unit in the direction of rotation. The first housing element that conjointly rotates in the rotation of the linear conveyor unit has a first opening through which the linear conveyor unit penetrates the plate and wherein the linear conveyor unit is spaced apart from the plane by an assigned gap dimension, which is smaller than or equal to 5 mm.