A more robust packaging structure for maintaining the integrity of compressible biologically active materials during storage and especially during transportation is provided. These containers protect the materials from shock, vibration, deformation, or separation from agitation. The compressible materials may be in the form of synthetic fibers, and may include a composite of fibers and beads or granules. Suitable materials that may benefit from such a robust packaging structure include synthetic materials that comprise a biologically active ceramic or glass.

Examples include a cardboard support element for a cardboard container, the support element comprising a cardboard structure extending away from a base plane, a first flap connected to the cardboard structure and extended in a direction normal to the base plane, a first primary panel and a second primary panel connected by a linear ridge, a first secondary panel connecting the first flap and the first primary panel, whereby a first primary folding region parallel to the linear ridge separates the first secondary panel from the first primary panel, and a first flap folding region parallel to the linear ridge separates the first secondary panel from the first flap. The first flap folding region has a folding factor larger than a first primary folding region folding factor, a ratio of the first flap folding region folding factor to the first primary folding region folding factor being of more than 1:1.

A package including a stack of absorbent tissue paper material and a packaging, wherein, in the stack, the absorbent tissue paper material forms panels having a length, and a width perpendicular to the length, the panels being piled on top of each other to form a height extending between a first end surface and a second end surface of the stack; the absorbent tissue paper material including at least a structured tissue material, the stack, when in the package, having a selected packing density D0 of 0.20 to 0.65 kg/dm.sup.3, and exerting a force along the height of the stack towards the packaging, the packaging encircling the stack so as to maintain the stack in a compressed condition with the selected packing density D0.

A package including a stack of absorbent tissue paper material and a packaging, wherein, in the stack, the absorbent tissue paper material forms panels having a length, and a width perpendicular to the length, the panels being piled on top of each other to form a height extending between a first end surface and a second end surface of the stack; the absorbent tissue paper material including at least a structured tissue material, the stack, when in the package, having a selected packing density D0 of 0.20 to 0.65 kg/dm.sup.3, and exerting a force along the height of the stack towards the packaging, the packaging encircling the stack so as to maintain the stack in a compressed condition with the selected packing density D0.

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 hood opening structure, is disclosed. The hood opening structure may be configured to open proximate the fold noses of the articles for easy tactile identification, grasping and withdrawal of individual ones thereof, and may be configured so as to serve as an effective package reclosure device 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.

A package of one or more absorbent articles is disclosed. The package has a package material including natural fibers. The package has a plurality of panels, including a consumer-facing panel, and wherein the package is sealed such that the one or more absorbent articles are completely enclosed therein. The package material has a basis weight of between 50 gsm to 120 gsm, between 60 gsm to 105 gsm or between 70 gsm to 90 gsm, as determined via ISO 536 as modified herein. The package material is recyclable.

A package of one or more absorbent articles is disclosed. The package has a package material including natural fibers. The package has a plurality of panels, including a consumer-facing panel, and wherein the package is sealed such that the one or more absorbent articles are completely enclosed therein. The package material has a basis weight of between 50 gsm to 120 gsm, between 60 gsm to 105 gsm or between 70 gsm to 90 gsm, as determined via ISO 536 as modified herein. The package material is recyclable.

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.

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.

To provide a film-packaged tissue assembly package that does not reduce fullness of tissue paper contained, has excellent shape retention, and includes a packaging bag that is not easily broken.

The problem is solved by a film-packaged tissue assembly package in which a plurality of film-packaged tissues is arranged and packaged in a gusset packaging bag having a grip portion on a top surface side, in which each of the film-packaged tissues is overlap-packaged and has end surfaces formed of sealed portions of tube openings at both ends in a longitudinal direction, and the overlap-packaged film-packaged tissues are packaged such that each end surface faces the top surface side having the grip portion and a bottom surface side facing the top surface side, and the longitudinal direction is along a top-bottom direction.