A process for safeguarding a product during transportation comprises forming a package by surrounding a product with packaging material and accommodating the package in an external packaging that comprises a carrier element and a bag element. The carrier element includes an upper side including a border and a lower side opposite the upper side, wherein the lower side comprises a base. Further, the bag element comprises a base and a bag opening with a border opposite the base of the bag element. The package is accommodated in the external packaging by loading the package onto the carrier element such that the package is carried by the carrier element and loading the carrier element via the bag opening into the bag element such that the bag element surrounds the carrier element and the bag element extends on the upper side of the carrier element beyond the border of the carrier element.

An external packaging for safeguarding at least one package during transportation is provided. The external packaging includes at least one carrier element with an upper side and a lower side, wherein the carrier element includes at least one base part directed toward the lower side and at least one border directed toward the upper side, and wherein the carrier element is at least partially open toward the upper side and is configured to carry the package. The external packaging furthermore has at least one bag element which is configured to surround the package carried by the carrier element. The bag element is arranged relative to the carrier element in such a manner that the bag element, at least in a maximum filling state, extends on the upper side of the carrier element beyond the border of the carrier element.

A compressed hollow coreless roll of absorbent paper sheet produced by way of providing a roll of absorbent paper sheet by winding the sheet about a forming core member having a diameter in the range of 30 mm to 50 mm; removing the forming core member such that there is provided a hollow coreless roll of absorbent paper sheet with an axial cavity having a diameter in the range of 30 mm to 50 mm and compressing the hollow coreless roll such that the axial cavity is substantially collapsed. The compressed hollow coreless rolls are readily re-formed into cylindrical shape. Space-saving packages of the rolls are overwrapped with tubular polymer film to provide a flexible reconfigurable package of a series of individually encased rolls. Volume reductions of about 10 to about 20%, about 14% to about 20%, 30%, 40% and more as compared with conventional products are realized.

A packaging piece is disclosed. The packaging piece includes a first side that includes a first module frame interlocking structure configured to snap fit to a drainage hole of a module frame in a first orientation and to extend toward a glass surface of a module in a second orientation. The packaging piece also includes a second side that includes: a second module frame interlocking structure configured to extend toward the glass surface of the module in the first orientation and to snap fit to the drainage hole of the module frame in the second orientation.

A modular packaging and shipping assembly for a bundled channel product includes a plurality of mounting adapters, each of the plurality of mounting adapters having a flat surface configured to abut the bundled channel product, a plurality of straps designed to wrap both the bundled channel product and the plurality of mounting adapters, and a plurality of mounting platforms, each of the plurality of mounting platforms having a mounting platform recess, which is configured to insertedly accommodate the mounting adapter.

A system is provided for robotically placing dunnage strips for receiving wallboard panels, including providing a robot with a robot arm with a tool having at least one suction cup and a glue dispenser; presetting in the robot a plurality of dunnage location programs, each associated with a particular wallboard panel size or thickness; and providing a dunnage cube with a plurality of stacked dunnage strips. Upon the selection of a preset wallboard panel dunnage location, the robot arm uses the suction cup to select and lift a strip from dunnage cube. Then, the robot arm places the strip upon the warehouse floor in a predesignated location per the preset program, and the glue dispenser on the robot deposits glue upon the strip. The robot repeats the dunnage strip selection, lifting, placement and deposition of glue to multiple dunnage strips until the preset arrangement is completed per the program.

A bundle of tubular and/or rod-shaped glass articles is provided that includes a longest dimension, a plurality of layers (N.sub.L) of the glass articles, and a thread-like element. The longest dimension extends in a first direction. The glass articles in each layer are arranged side by side in a second direction. The plurality of layers are arranged side by side in a third direction. The first, second, and third directions being perpendicular to one another. The thread-like element is around two of the glass articles in at least one layer so that the two glass articles are spaced apart.