A loading system (e.g., in a warehouse or other item-fulfillment environment) can include a rotary hub that supports one or more chambers. In a first orientation of the rotary hub, one of the chambers may be in a first position aligned for item receipt (e.g., through an open top of the chamber by feeding from a conveyor belt or other feeding system). The rotary hub can rotate to a second orientation in which the chamber is in a second position aligned for item discharge (e.g., through an open end of the chamber and into a receiving zone of a packaging machine or other system).

A separating element operates a transport device, which is configured to pile a plurality of partial book blocks for forming a book block along a book channel associated with the transport device, the finished piled book block being feedible to a processing machine. The book channel includes at least one transfer portion. At least one first separating element is arranged within the transport device as a link between an upstream transfer portion and a downstream transfer portion. The first separating element is configured to be operated by at least one drive and is configured to: receive a partial book block fed horizontally from the upstream transfer portion, horizontally transport the partial book block onward via the conveying portion formed by the first separating element, and then horizontally hand the partial book block over to the downstream transfer portion in keeping with a cycle.

A system for transferring units to/from a rail-guided suspended conveyor system includes a transfer conveying device with one or more first conveying units and a conveyor system with a plurality of second conveying units. The first and second conveying units each have a rack with tines and form a receptacle for bearing a unit. The system is configured such that in a transfer zone a rack of a first conveying unit of the transfer device and a rack of a second conveying unit of the conveyor system penetrate by meshing so with movement of the first and the second conveying unit relative to another either a unit initially on the rack of the first conveying unit remains on the rack of the second conveying unit, or a unit initially on the rack of the second conveying unit remains on the rack of the first conveying unit.

A system for transferring units to/from conveying units of a rail-guided suspended conveyor system includes at least one transfer conveying device with one or more first conveying units with a rack with tines which form a receptacle for bearing an individual unit; and a suspended conveyor system with a plurality of second conveying units with a rack with tines which form a receptacle for bearing an individual unit. The system is configured such that in a transfer zone a rack of a first conveying unit of the transfer conveying device and a rack of a second conveying unit of the suspended conveyor system penetrate by meshing so with movement of the first and the second conveying unit relative to another either an individual unit initially on the rack of the first conveying unit remains on the rack of the second conveying unit, or an individual unit initially on the rack of the second conveying unit remains on the rack of the first conveying unit.

A separating element operates a transport device, which is configured to pile a plurality of partial book blocks for forming a book block along a book channel associated with the transport device, the finished piled book block being feedible to a processing machine. The book channel includes at least one transfer portion. At least one first separating element is arranged within the transport device as a link between an upstream transfer portion and a downstream transfer portion. The first separating element is configured to be operated by at least one drive and is configured to: receive a partial book block fed horizontally from the upstream transfer portion, horizontally transport the partial book block onward via the conveying portion formed by the first separating element, and then horizontally hand the partial book block over to the downstream transfer portion in keeping with a cycle.

In one arrangement, a storage system for storing items includes an enclosure enclosing a hypoxic environment, and a pallet shuttle system comprising rows of racks disposed within the hypoxic environment. The pallet shuttle system also includes at least one transfer car and at least one shuttle for carrying storage modules into and out of the racks. The system further includes a loading station outside the hypoxic environment, and an enclosure door to the hypoxic environment. The enclosure door is operable to admit the transfer car of the pallet shuttle system into and out of the hypoxic environment, and to close the hypoxic environment upon passage of the transfer car through the door. Optionally, the system includes paneling separating the enclosure into at least two separately climate-controlled zones such that at least one of the racks is in each of the at least two separately climate-controlled zones.

Disclosed is a device for loading a bound product, the device holding a product without the product sagging, which has been completed by punching various objects to be bound and then binding same by means of a coil spring, reversing the moving direction to a loading location and thereby enabling neat and stable stacking in a zigzag state without having the coil springs come in contact with one another. A device for loading a bound product, according to the present invention, comprises: a supporting frame unit for providing a distance for the movement of a bound product from a binding location to a loading location; a transfer unit having upper and lower gears, which are axially mounted on one side of the frame unit, a driven gear, which is axially mounted on the other end, a moving belt, for connecting the lower gear and the driven gear, a power belt, which is connected to the upper gear, and a first driving motor, for transmitting power to the power belt; an LM guide having a rail, which is mounted on the frame unit in the length direction, and a block; a reversing unit having a supporting plate, which is fixed on the block of the LM guide and the moving belt, a pinion, of which the upper end is rotatably and axially mounted on the supporting plate, a first cylinder, for operating a rack gear that interlocks with the pinion, and a rotating plate which is fixed on the lower end of the pinion; and a holding unit having a support and a second cylinder which is mounted on the rotating plate of the reversing unit and has a pressure member coupled to the front end thereof so as to hold a bound product.

Disclosed is a device for loading a bound product, the device holding a product without the product sagging, which has been completed by punching various objects to be bound and then binding same by means of a coil spring, reversing the moving direction to a loading location and thereby enabling neat and stable stacking in a zigzag state without having the coil springs come in contact with one another. A device for loading a bound product, according to the present invention, comprises: a supporting frame unit for providing a distance for the movement of a bound product from a binding location to a loading location; a transfer unit having upper and lower gears, which are axially mounted on one side of the frame unit, a driven gear, which is axially mounted on the other end, a moving belt, for connecting the lower gear and the driven gear, a power belt, which is connected to the upper gear, and a first driving motor, for transmitting power to the power belt; an LM guide having a rail, which is mounted on the frame unit in the length direction, and a block; a reversing unit having a supporting plate, which is fixed on the block of the LM guide and the moving belt, a pinion, of which the upper end is rotatably and axially mounted on the supporting plate, a first cylinder, for operating a rack gear that interlocks with the pinion, and a rotating plate which is fixed on the lower end of the pinion; and a holding unit having a support and a second cylinder which is mounted on the rotating plate of the reversing unit and has a pressure member coupled to the front end thereof so as to hold a bound product.

A sheet medium stacking conveying device and method, wherein the method comprises a medium conveying step, the medium conveying step comprises: moving a stacking mechanism for clamping media from a medium inlet to a medium outlet along a moving path, and discharging the media clamped by the stacking mechanism towards the medium outlet relative to the stacking mechanism in a process of moving the stacking mechanism towards the medium outlet. The stacking mechanism of the conveying device can reciprocally move between a collection position and discharge position of the media under the driving of a driving mechanism, and the media can be discharged under the condition of no additional power source.

An apparatus separates printed products that have been assembled into a stack. The apparatus includes a conveyor for transporting the stack, which is connected to an advanceable element, which implements separation of the printed products in the stack. The printed products in a receiving support are transferred into a skewed position, which leads to a reduction of the load on the printed products that are to be de-stacked. A retainer, which is part of the receiving support, and a support are set with a clearance with respect to the predefined printed product thickness.