The present disclosure relates to a system comprising at least one primary package accommodating at least one article, and a secondary package accommodating the primary package, wherein the secondary package comprises a second package material having a water vapor transmission rate lower than about 100 g/m.sup.2/day, as measured according to Water Vapor Transmission Rate Test, and a resistance to compression higher than about 150N.

The disclosure pertains to a wrapper (22) for an absorbent article (10) comprising a release paper (51,51′) comprising a layer of cellulosic fibers (33), a layer of peeling agent (32) arranged onto the layer of cellulosic fibers (33). According to the disclosure, the layer of cellulosic fibers (33) comprises a basis weight comprised between 10 gsm and 40 gsm. The disclosure also relates to an assembly comprising an absorbent article (10) and such wrapper (22) and a process to manufacture such assembly (10).

A sealing patch for a polymeric bag includes a carrier, a pressure sensitive adhesive on the carrier and a heat-activated material on the pressure sensitive adhesive. A high-strength polymeric bag is formed from woven tapes and is coated with a polymer material. The sealing patch is positioned on the bag for sealing the bag. A method for sealing a high-strength polymeric bag with a sealing patch and a device for sealing a polymeric bag with a sealing patch are disclosed.

A system and method for packaging pine straw and a packaged mass of pine straw made therefrom, the method including providing an electronically-controlled system configured for packaging pine straw, the system including system logic that controls conveying, fluffing, cleaning, compressing and packaging of the pine straw, and using the system to compress a mass of pine straw into a rectangular mass of pine straw and enclosing the rectangular mass of pine straw within a flexible plastic sheet thereby forming a substantially rectangular packaged mass of compressed pine straw.

A system and method for packaging pine straw and a packaged mass of pine straw made therefrom, the method including providing an electronically-controlled system configured for packaging pine straw, the system including system logic that controls conveying, fluffing, cleaning, compressing and packaging of the pine straw, and using the system to compress a mass of pine straw into a rectangular mass of pine straw and enclosing the rectangular mass of pine straw within a flexible plastic sheet thereby forming a substantially rectangular packaged mass of compressed pine straw.

The method includes making a blank from a single web of material, the making including first configuring a first side panel and a second side panel to extend from first opposing ends of a bottom panel, second configuring a ramp panel to extend from a first edge of the first side panel, and third configuring a top panel and a lid panel to extend from second opposing ends of the bottom panel.

A package containing a stack of folded disposable absorbent articles, the package being formed of flexible polymeric film, and having a path of perforations or scoring defining a serpentine-shape, is disclosed. The serpentine-shaped path may be located proximate the fold noses of the articles in the stack for easy tactile identification, grasping and withdrawal of individual ones thereof, and may be configured so as to cause opening flaps defined by the path to effectively draw to a closed position following access to the contents within, whereby the package may be used to store the unused supply of articles following opening. The package, and printed commercial artwork and product information on the package surfaces, may be configured such that the fold noses are disposed at the apparent bottom of the package, for improved standing stability when the package is shelved.

An array of absorbent article packages is described. The array includes first and second packages having first and second package materials that include natural fibers, respectively. The first and second packages include a plurality of panels and a plurality of seals enclosing one or more absorbent articles therein. A portion of the first package material exhibits a water vapor transmission rate under stress conditions “SCWVTR” in accordance with ASTM F1249, as modified herein, which is about 300 g/(m.sup.2*day) or less. Each of the one or more absorbent articles in the second package comprises an absorbent core having less superabsorbent polymer than the absorbent cores of the one or more absorbent articles in the first package, and the one or more absorbent articles in the first and second packages are made by or on behalf of the same manufacturer.

An absorbent article such as a diaper extending in a longitudinal direction parallel to a longitudinal axis (80′) and a transversal direction (90′) perpendicular to the longitudinal direction and comprising a distribution layer (54) between a topsheet (24) and an absorbent core (28). The distribution layer comprises a fibrous material and a first and second longitudinally-extending channels (86a,b) substantially free of fibrous material. The fibrous material is profiled in the transversal direction so that average basis weight between the channels differs from the average basis weight in the lateral areas outward of the channels by at least 50 g/m.sup.2 and/or wherein the distribution layer comprises a first region having a first basis weight (bw1) and a second region having a second basis weight (bw2), wherein the first basis weight and the second basis weight differ by at least 20 g/m.sup.2, preferably by at least 50 g/m.sup.2, and these regions are present in different areas of the distribution layer but in the same longitudinally extending transversal section. The absorbent core may comprise channel-forming areas (26a,b). The article further comprises a backsheet (25).

A flat-packing machine for producing a package of compressed innerspring units comprises a press device having a first pressing tool and a second pressing tool. The press device is configured to compress an innerspring unit between the first pressing tool and the second pressing tool while one of the first pressing tool and the second pressing tool holds one or more further previously compressed innerspring units in a compressed state.