A material handling system for handling, placing packages onto pallets destined for an order store, the material handling system comprising, a storage array with storage spaces for holding packages therein, an automated package transport system communicably connected to the storage array for storing packages within the storage spaces of the storage array and retrieving packages from the storage spaces of the storage array, an automated palletizer for placing mixed packages onto a pallet to form a pallet load of mixed packages, the automated palletizer is communicably connected to the automated package transport system which provides individual packages from the storage array to the automated palletizer for forming the pallet load of mixed packages, the pallet load of mixed packages including more than one composite layers of mixed packages, a controller operably connected to the automated palletizer, the controller being programmed with a pallet load generator with an initial pallet load.

A packaging system for high flexibility and speed box-last packaging comprises one or more dimensional scanning sensors that are configured to scan a group of one or more target products that are to be boxed and gather dimension information describing physical dimensions of the group of one or more target products. The system also comprises one or more packaging-production machines that are configured to generate custom-made packaging templates that conform to a pre-determined set of packaging template types. Additionally, the system comprises a packaging template buffer that comprises physically divided sections that contain multiple packaging templates selected from the pre-determined set of packaging template types that are generated by the one or more packaging-production machines. Each of the packaging templates are organized within the physically divided section based upon packaging template type.

A recharge tube stocker for storing and managing a recharge tube used for a single crystal pulling apparatus, including an inlet-outlet section for taking the recharge tube in the recharge tube stocker and taking the recharge tube out of the recharge tube stocker, a storage for storing the recharge tube, a raw-material charging device for charging the recharge tube with a raw material, a weighing device for weighing a weight of the raw material charged into the recharge tube, a transferring device for enabling a transfer of the recharge tube, being taken in through the inlet-outlet section, among the inlet-outlet section, the raw-material charging device, and the storage, and a managing device for collectively managing storage information on the recharge tube stored in the storage. This recharge tube stocker stores and manages tubes in a space saving manner without taking time for searching and without causing mix-up of recharge tubes.

A recharge tube stocker for storing and managing a recharge tube used for a single crystal pulling apparatus, including an inlet-outlet section for taking the recharge tube in the recharge tube stocker and taking the recharge tube out of the recharge tube stocker, a storage for storing the recharge tube, a raw-material charging device for charging the recharge tube with a raw material, a weighing device for weighing a weight of the raw material charged into the recharge tube, a transferring device for enabling a transfer of the recharge tube, being taken in through the inlet-outlet section, among the inlet-outlet section, the raw-material charging device, and the storage, and a managing device for collectively managing storage information on the recharge tube stored in the storage. This recharge tube stocker stores and manages tubes in a space saving manner without taking time for searching and without causing mix-up of recharge tubes.

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).

Described herein are exemplary systems and methods for the optimization of shipping cartons relative to the contents of orders to be placed therein. An exemplary carton optimization method evaluates a sample size of orders received at a given location and then determines an optimal carton set that includes at least one feasible carton for each order, while also minimizing shipping costs based on dimensional weighing-based pricing by reducing the dimensional weight, thereby minimizing void space and increasing the carton space utilization percentage. An exemplary carton optimization method may be further customized to optimize a carton set for an order, based on the cartons already available at a given warehouse or other site. As a result, cartons are utilized and designed more efficiently at the site.

The present disclosure relates to a centering apparatus for the orderly insertion of objects into a storage container comprising: a plate-like base body, a plurality of first indentations adjacent to one another in an outer edge of the base body, a cut-out in the base body, and a plurality of mutually adjacent second indentations in an edge of the cut-out, wherein the first indentations and the second orientations have the same orientation.

The present disclosure relates to a centering apparatus for the orderly insertion of objects into a storage container comprising: a plate-like base body, a plurality of first indentations adjacent to one another in an outer edge of the base body, a cut-out in the base body, and a plurality of mutually adjacent second indentations in an edge of the cut-out, wherein the first indentations and the second orientations have the same orientation.

A device for storing and transporting large-volume foam blocks includes a mobile, stackable storage box for receiving a foam block at a loading position and a transport device for transporting the storage box from the loading position to a floor storage. The device is suitable to store and transport large-volume, soft, viscoelastic foam blocks in a safe, simple, inexpensive and space-saving manner.

A storage system (10) for storing an elongated object (26) in a substantially vertical orientation relative to a ground surface (13), the storage system including a rack (11), the rack (11) including a supporting structure (30), a first member (14) supported by the supporting structure (30) above the ground surface (13) and a second member (12) supported by the supporting structure (30) above the ground surface (13) higher than the first member (14); a first mounting element (22) securable to both the elongated object (26) and to the first member (14) together to mount the elongated object (26) to the first member (12); and a second mounting element (20) securable to both the first mounting element (22) and to the second member (12) together.