Abstract: An elastic-powered shrink laminate includes a shrinkable layer and an elastic layer bonded together while the elastic layer is in a dimensionally unstable, stretched state. The elastic layer remains substantially in the stretched state prior to shrinkage of the shrinkable layer. When the shrinkable layer is activated, the laminate retracts, and the retraction is aided (i.e. powered) by the elastic layer. The elastic-powered shrink laminate is useful in personal care absorbent articles where latent, post-assembly retraction of a waistband region is desired.

Abstract: A stretch activated disposable article, such as a wipe or mitt, includes an upper material layer, and a lower material layer joined to the upper material layer such that a space is defined between the material layers. A functional element, for example a fluid composition, is stored in the space between the upper and lower material layers and becomes functional upon being exposed through the upper material layer with use of the article. The upper material layer includes a plurality of materially weakened positions along the surface thereof that are configured to part or separate upon stretching of the upper material layer to expose the functional element through the upper material layer.

Abstract: Disclosed herein are color change laminate materials suitable for a variety of uses. The color change laminate materials include at least two layers of extensible materials having visually distinct coloration, and indicate a stretched or extended state by exposing the previously covered coloration of a lower layer. The color change laminate materials may also indicate the amount of stretching or extension is applied to the laminate. When the laminate includes elastic materials capable of stretch and recovery, the color change laminate materials may further be reversible color change laminate materials that can display color change upon extension and then recover the extension and return to the original coloration. Such color change laminate materials and reversible color change laminate materials are highly useful for use in garments or other textile type applications, in or on personal care products, protective wear products, health care and medical care products, bandages and the like.

Abstract: An efficient, in-line method for forming an elastic laminate is provided. To form the laminate, a polymer composition containing an elastomeric polymer is extruded as a film. In one embodiment, the film is uniaxially oriented in the machine direction (“MD”), or optionally, biaxially oriented in the machine direction and the cross-machine direction (“CD”). Regardless, the elastic film is then laminated to a nonwoven web material. Prior to lamination, the percent stretch of the nonwoven web material is generally no more than 25% when 500 grams-force is applied per 3 inches of the material in either the cross-machine or machine direction. Such a relatively inextensible nonwoven web material may restrict the overall extensibility of the laminate. Thus, to improve extensibility, the resulting laminate is mechanically stretched in the cross-machine and/or machine directions.

Abstract: A method of producing a laminate material includes the steps of providing a first flexible sheet material; providing a second flexible sheet material having a first surface and a second surface, and also having a first width of 1X; stretching the second flexible sheet material in a cross-machine direction to a second width of between about 1.2X and 3 X when in a flattened state; necking the second flexible sheet material to produce an accordion shape, thereby reducing the second width of the sheet material to a third width, less than the width of the first width, such that the third width is between 0.65 X to 0.975 X when in an accordion shape; applying adhesive to the first surface of the second flexible sheet material with a slot coat adhesive process; and joining the first flexible sheet material to the first surface of the second flexible sheet material.

Abstract: We have determined that strength characteristics of elastic strand improve when the strand is heated. Thus, the present invention is directed to improving strength characteristics of an elastic strand by heating the strand. The strand may be heated by thermal conduction and/or convection, by irradiative methods using, for example, infrared or microwave radiation, or some combination of these. If the elastic strand is made at a location different from the location where the strand is used as a raw material, the strand may be heated at either location, or both locations. Furthermore, the strand may be heated in-line, i.e. as part of the process that makes the strand or the process that uses the strand as a raw material, or off-line, i.e. in a step separate from either of the aforementioned processes. Finally, in addition to heat treating the strand, the strand's exposure to water or water vapor may be regulated to reduce or eliminate strength degradation.

Abstract: Disclosed herein is an efficient, in-line process for forming elastic laminates comprising an elastic blown film sheet and one or more fibrous nonwoven webs. The process is capable of making elastic laminates having the properties of stretch and recovery in the machine direction, in the cross machine direction, or in both the machine direction and cross machine direction. The elastic laminates produced may be bilayer or trilayer laminates. Such elastic laminates are highly useful for use in personal care products, protective wear garments, medical care products, mortuary and veterinary products and the like.

Abstract: An elastic laminate capable of being rolled for storage and unwound from a roll when needed for use, includes an elastic layer of an array of continuous filament strands with meltblown deposited on the continuous filament strands, and a facing layer bonded to only one side of the elastic layer. The meltblown layer may include an elastic polyolefin-based meltblown polymer having a degree of crystallinity between about 3% and about 40%. The laminate suitably has an inter-layer peel strength of less than about 70 grams per 3 inches cross-directional width at a strain rate of 300 mm/min. Alternatively or additionally, the continuous filament strands and/or the facing layer may include an elastic polyolefin-based meltblown polymer having a degree of crystallinity between about 3% and about 40%.

Abstract: An elastic laminate capable of being rolled for storage and unwound from a roll when needed for use, includes an elastic layer selected from the group consisting of an array of continuous filament strands, an array of continuous filament strands with meltblown deposited on the continuous filament strands, and a film; a gatherable facing layer bonded to only one side of the elastic layer; and either an adhesive that demonstrates a relatively short open time deposited between the elastic layer and facing layer, or such adhesive and a postbonding adhesive or nonblocking agent, or a nonblocking agent layer deposited on the elastic layer on a side opposite to the facing layer.

Abstract: A method of producing a laminate material by joining an incrementally stretched first flexible sheet material to a second flexible sheet material. A series of nips formed by intermeshing grooves provides the first flexible sheet material with a high degree of stretch and provides the resulting laminate has a high degree of extensibility. The width of the first flexible sheet material is maintained through the incremental stretching to result in high efficiency of utilization of the first flexible sheet material in production of the laminate.

Abstract: The present invention is directed to regulating agglomeration of elastic material (e.g., elastic strand) by regulating exposure of the material to water or water vapor. In some versions of the invention, regulating agglomeration in this way decreases, minimizes, or eliminates strand breaks on a production machine using the strand as raw material. Representative embodiments encompass regulating the material's exposure to water or water vapor by regulating temperature, humidity, or both around the elastic material, or containers containing the elastic material, so that the elastic material remains substantially unagglomerated. Other representative embodiments encompass packaging the elastic material in a way that regulates the material's exposure to water or water vapor so that the material remains substantially unagglomerated.

Abstract: We have determined that strength characteristics of elastic strand improve when the strand is heated. Thus, the present invention is directed to improving strength characteristics of an elastic strand by heating the strand. The strand may be heated by thermal conduction and/or convection, by irradiative methods using, for example, infrared or microwave radiation, or some combination of these. If the elastic strand is made at a location different from the location where the strand is used as a raw material, the strand may be heated at either location, or both locations. Furthermore, the strand may be heated in-line, i.e. as part of the process that makes the strand or the process that uses the strand as a raw material, or off-line, i.e. in a step separate from either of the aforementioned processes. Finally, in addition to heat treating the strand, the strand's exposure to water or water vapor may be regulated to reduce or eliminate strength degradation.

Abstract: The present invention is directed to regulating agglomeration of elastic material (e.g., elastic strand) by regulating exposure of the material to water or water vapor. In some versions of the invention, regulating agglomeration in this way decreases, minimizes, or eliminates strand breaks on a production machine using the strand as raw material. Representative embodiments encompass regulating the material's exposure to water or water vapor by regulating temperature, humidity, or both around the elastic material, or containers containing the elastic material, so that the elastic material remains substantially unagglomerated. Other representative embodiments encompass packaging the elastic material in a way that regulates the material's exposure to water or water vapor so that the material remains substantially unagglomerated.

Abstract: We have determined that strength characteristics of elastic strand improve when the strand is heated. Thus, the present invention is directed to improving strength characteristics of an elastic strand by heating the strand. The strand may be heated by thermal conduction and/or convection, by irradiative methods using, for example, infrared or microwave radiation, or some combination of these. If the elastic strand is made at a location different from the location where the strand is used as a raw material, the strand may be heated at either location, or both locations. Furthermore, the strand may be heated in-line, i.e. as part of the process that makes the strand or the process that uses the strand as a raw material, or off-line, i.e. in a step separate from either of the aforementioned processes. Finally, in addition to heat treating the strand, the strand's exposure to water or water vapor may be regulated to reduce or eliminate strength degradation.