An inflatable packaging for storing multiple glass bottles made from a sheet that has a longitudinal axis and a traverse axis. The sheet is folded along six or more traverse fold lines spaced from each other to form a row of two or more pouches. The inflatable packaging can have two or more of such rows separated by a line of weakness. Each pouch has a front wall, a rear wall, a base, and an open-top for storing the glass bottle. Two adjacent pouches are separated by a dividing panel, wherein the dividing panel is corrugated in a biconcave shape.

An inflatable packaging for storing multiple glass bottles made from a sheet that has a longitudinal axis and a traverse axis. The sheet is folded along six or more traverse fold lines spaced from each other to form a row of two or more pouches. The inflatable packaging can have two or more of such rows separated by a line of weakness. Each pouch has a front wall, a rear wall, a base, and an open-top for storing the glass bottle. Two adjacent pouches are separated by a dividing panel, wherein the dividing panel is corrugated in a biconcave shape.

A scanning stage with opposing edges to secure a slide during scanning and guide the slide during unloading. In an embodiment, the system includes a reference edge with a surface facing a first edge of the slide and an opposing edge with a surface facing a second edge of the slide. The opposing edge is controlled by a processor to engage the second edge of the slide and press the first edge of the slide against the reference edge surface. The opposing edge surface is parallel to a side of a slide rack slot into which the slide will be inserted during unloading. The system also includes an assembly having a pull bar configured to pull the glass slide from the scanning stage into the slide rack slot while the first edge of the slide is simultaneously being pressed against the reference edge surface by the opposing edge surface.

The present disclosure describes a method that includes receiving a plurality of packaging units made of glass; coating at least a portion of an outer surface of each packaging unit with low-friction coating; curing the low-friction coating applied to the outer surface of each packaging unit; receiving a container configured to store the plurality of packaging units; and arranging each packaging unit in the container with the outer surface of each packaging unit able to touch the outer surface of one or more adjacent packaging units.

Methods and apparatus for packaging and shipping wine. A shipping container includes: a vacuum molded base component having a plurality of cylindrical concave columns within which respective bottles are received; a substantially planar corrugated separator sheet having a plurality of receptors aligned with the axes of the columns and configured to slidably receive respective bottle necks associated with the bottles; a vacuum molded cap component for receiving the bottle necks therewithin; and an outer corrugated box within which the bottles, base component, separator, cap component components are securely disposed.

Methods and apparatus for packaging and shipping wine. A shipping container includes: a vacuum molded base component having a plurality of cylindrical concave columns within which respective bottles are received; a substantially planar corrugated separator sheet having a plurality of receptors aligned with the axes of the columns and configured to slidably receive respective bottle necks associated with the bottles; a vacuum molded cap component for receiving the bottle necks therewithin; and an outer corrugated box within which the bottles, base component, separator, cap component components are securely disposed.

A package comprising a carton and an arrangement of containers. The carton can comprise a plurality of panels extending at least partially around an interior of the carton. The plurality of panels can comprise at least a first panel and a second panel disposed opposite to one another. The arrangement can comprise a number of rows of containers disposed at least partially in the interior of the carton. The arrangement can include at least a first row and a second row extending along the respective first and second panels. A load width of the arrangement can be less than the number of rows multiplied by a first difference between the diameter of the containers approximately an eighth of an inch, and the load width can be greater than the number of rows multiplied by a second difference between the diameter and approximately a half of an inch.

An impact tool includes a motor, a first hammer, an anvil, and a second hammer. The first hammer is configured to be rotated by driving of the motor. The anvil is configured to be hammered in a rotation direction by the first hammer. The second hammer is configured to be switchable between a state being linked and a state not being linked to the first hammer. The impact tool ensures selections of a first hammering mode in which only the first hammer hammers the anvil and a second hammering mode in which the first hammer and the second hammer hammer the anvil.

Stackable trays for jugs, stacked arrangements and stacking methods are disclosed. A tray has a first surface to support a bottom of one or more jugs, and could include jug receiving cells. A collar could extend downwardly from a second surface opposite the first surface and have at least one notch sized to receive a portion of a handle of a respective jug located beneath each jug receiving cell. Load transfer to the handles of the jugs below the second surface could be provided by load transfer structures, such as the collars in one embodiment, which extend from the second surface to engage the jugs. A stacked arrangement includes multiple layers of jugs with a respective stackable tray between adjacent layers of the multiple layers. The trays could thus be used in stacking or otherwise arranging jugs in multiple layers.

Stackable trays for jugs, stacked arrangements and stacking methods are disclosed. A tray has a first surface to support a bottom of one or more jugs, and could include jug receiving cells. A collar could extend downwardly from a second surface opposite the first surface and have at least one notch sized to receive a portion of a handle of a respective jug located beneath each jug receiving cell. Load transfer to the handles of the jugs below the second surface could be provided by load transfer structures, such as the collars in one embodiment, which extend from the second surface to engage the jugs. A stacked arrangement includes multiple layers of jugs with a respective stackable tray between adjacent layers of the multiple layers. The trays could thus be used in stacking or otherwise arranging jugs in multiple layers.