The present disclosure relates to a recyclable polyethylene-based laminated packaging material with openability and a method of manufacturing the same including a multi-layered polyethylene film C in which a surface layer A and a sealant layer B are bonded to each other. The sealant layer B is a layer in which a polyolefin plastomer layer b1, a mixed resin layer b2 obtained by mixing a high-density polyethylene resin and a low-density polyethylene resin, and a composition layer b3 containing a resin composition obtained by mixing medium-density polyethylene and low-density polyethylene are sequentially laminated. Also disclosed is a method of manufacturing the same.

Methods include at least one sequential stretching step between circular or spiralized grooved rollers and the sequential stretching is performed according to at least one of six aspects of the invention.

An object to be achieved is to provide a product conveyance film, the generation of powder or other foreign matter from which is suppressed under vibration during transport. As a means for achieving the object, a product conveyance film is provided which is placed between a product and a packing material in which the product is enclosed, wherein such product conveyance film is characterized in that the maximum static friction force on its face on the product side is greater than the dynamic friction force on its face on the packing-material side and the difference between the two forces is 0.30 N or more, and that the dynamic friction force on the face on the packing-material side is 0.80 N or less.

A method for printing ink on a substrate comprising the steps of coating a glass substrate with an adhesion promoter, depositing one or more layers of ink on the coated substrate, and laminating the imaged substrate. The substrate can be a glass substrate, and the adhesion promoter can include a silane material, powder coating, organophosphate primer suspended in isopropanol.

A fluid distribution material for use in an absorbent article includes a formed film layer having first and second sides and a basis weight of between about 10 gsm and about 25 gsm, and a nonwoven layer having a basis weight of between about 10 gsm and about 15 gsm and laminated to the formed film layer. The formed film layer includes a plurality of apertured protuberances arranged in a pattern having 10 to 40 protuberances per linear inch. Each of the protuberances includes a continuous sidewall extending from the first side, and the second side has a plurality of apertures aligned with the plurality of protuberances, and land areas in between the apertures. The nonwoven layer includes a plurality of fibers attached to the formed film layer at the land areas. The material has a rewet value of less than 0.075 grams in accordance with the Rewet Test Method.

A method and apparatus for making pouches is disclosed. It includes using one or more of the following features: using two servo motors to drive a platen, providing a calibration routine is run at start-up and/or after the machine has been operating; controlling in response to feed back from the servo motor(s) such as feedback indicative of the distance the platen travels; the feedback is not of force exerted by the platen; and/or the platen is controlled to prevent unacceptable fracturing of the film laminate.

A composite panel includes a thermoplastic base of ultra high molecular weight polyethylene, a composite layer including basalt fibers, with the composite layer bonded to the thermoplastic base, and the composite layer including at least two sub-layers of basalt material. Each sub-layer of basalt material is bonded to adjacent sub-layers of basalt material, where each sub-layer of basalt material comprises basalt fabric, and where the composite layer provides a protective fire barrier configured to prevent flame and smoke generation upon application of a 3400 F. flame to the composite layer.

A film having an A/B/A structure comprising an layer A and a layer B. The layer A is present in an amount ranging from 25 to 65 wt. %, based upon the total weight of the A/B/A structure, and the layer A comprises a first A layer and a second A layer each independently comprise linear low density polyethylene. The layer B is present in an amount ranging from 35 to 75 wt. %, based upon the total weight of the A/B/A structure, and the layer B, which comprises high density polyethylene, is positioned between the first A layer and the second A layer.

An insole, outsole, shoe sole or a shoe formed with the disclosed layered sole includes a small layered sheet including a specific layered sheet. The shoe sole may be formed to include a small layered sheet provided at any one or two or more places of a front foot portion, a middle foot portion or a rear foot portion of the shoe sole, or is provided across two or more positions of the front foot portion, the middle foot portion or the rear foot portion of the shoe sole, the small layered sheet formed of a layered sheet of a plurality of cloths wherein; the cloths formed of a strand of an oriented thermoplastic resin; and the plurality of cloths are integrated by heating and compressing.

A multilayer film includes: an inner layer system having a first surface and a second surface; and a first skin layer and a second skin layer bound to the inner layer system at the first and second surfaces respectively. The inner layer system consists of a polymer formulation (A) containing: ?60.0 and ?90.0 wt % of a linear low-density polyethylene A; and ?10.0 and ?40.0 wt % of a high-density polyethylene having a density of ?940 and ?970 kg/m.sup.3; and at least one of the first or the second skin layer(s) is a sealing layer comprising a linear low-density polyethylene B comprising polymeric moieties derived from ethylene and 1-octene/1-hexene, having a density of ?890 and ?915 kg/m.sup.3.