Abstract: The present disclosure provides for an apparatus for transferring fluid. The apparatus has a fluid transfer component, a fluid receiving component, a fluid supply, and a fluid motivating component. The fluid transfer component comprises first surface, a second surface, a non-random pattern of distinct pores each defining a pathway between the first and second surfaces, each pathway having a single entry point at the first surface and a single exit point at the second surface. The pores are disposed at preselected locations to provide a desired pattern of permeability. The fluid receiving component comprises a fluid receiving surface. The fluid supply is adapted to provide a fluid in contact with and at a constant fluid pressure with each of said pores. The fluid motivating component is adapted to facilitate transport of the fluid from the first surface through the pores to the second surface.

Abstract: The present disclosure provides for an apparatus for transferring fluid. The apparatus has a fluid transfer component, a fluid receiving component, a fluid supply, and a fluid motivating component. The fluid transfer component has a first surface, a second surface, a non-random pattern of distinct pores each defining a pathway between the first and second surfaces, a single entry point at the first surface, and a single exit point at the second surface. The pores are disposed at preselected locations to provide a desired pattern of permeability. The fluid receiving component comprises a fluid receiving surface. The fluid supply is adapted to provide a fluid in contact with and at a constant fluid pressure with the first surface of the fluid transfer component. The fluid motivating component is adapted to facilitate transport of the fluid from the first surface through the pores to the second surface.

Abstract: The present disclosure provides for an apparatus for transferring fluid. The apparatus has a fluid transfer component, a fluid receiving component, a fluid supply, and a fluid motivating component. The fluid transfer component has a first surface, a second surface, a non-random pattern of distinct pores each defining a pathway between the first and second surfaces, a single entry point at the first surface, and a single exit point at the second surface. The pores are disposed at preselected locations to provide a desired pattern of permeability. The fluid receiving component comprises a fluid receiving surface. The fluid supply is adapted to provide a fluid in contact with and at a constant fluid pressure with the first surface of the fluid transfer component. The fluid motivating component is adapted to facilitate transport of the fluid from the first surface through the pores to the second surface.

Abstract: The present disclosure provides for an apparatus for transferring fluid. The apparatus has a fluid transfer component, a fluid receiving component, a fluid supply, and a fluid motivating component. The fluid transfer component has a first surface, a second surface, a non-random pattern of distinct pores each defining a pathway between the first and second surfaces, a single entry point at the first surface, and a single exit point at the second surface. The pores are disposed at preselected locations to provide a desired pattern of permeability. The fluid receiving component comprises a fluid receiving surface. The fluid supply is adapted to provide a fluid in contact with and at a constant fluid pressure with the first surface of the fluid transfer component. The fluid motivating component is adapted to facilitate transport of the fluid from the first surface through the pores to the second surface.

Abstract: A method for producing a deep-nested embossed product is disclosed. The method comprises the steps of: a) providing an embossing apparatus having mating first and second embossing members; b) providing the first embossing member with a plurality of discrete embossing elements in a non-random pattern; c) providing the second embossing member with at least one linear embossing element; d) coordinating the at least one linear embossing element with the non-random pattern of first embossing elements; e) aligning the first embossing member and the second embossing member so that the non-random pattern of first embossing elements nest with the at least one linear embossing element to an engagement depth of greater than about 0.01 mm; f) providing one or more plies of material to the embossing apparatus; and, g) passing the one or more plies of the material between the first and second embossing members to produce the deep-nested embossed product.

Abstract: An apparatus for producing a deep-nested embossed product including a first embossing member and a second embossing member. The first embossing member has a plurality of discrete embossing elements disposed in a first non-random pattern. The second embossing member has a plurality of second embossing elements including at least one linear embossing element. The second embossing elements are disposed in a second non-random pattern such the first non-random pattern and the second non-random pattern nest together to a depth of greater than about 0.01 mm.

Abstract: The present disclosure provides for a method for transferring fluid. The method provides for the steps of: a) providing a fluid transfer component comprising a first surface, a second surface, a non-random pattern of distinct pores, the pores connecting the first surface and the second surface, the pores being disposed at preselected locations to provide a desired pattern of permeability, b) providing a fluid receiving component comprising a fluid receiving surface, c) motivating a fluid into contact with the first surface and subsequently through the distinct pores to the second surface, d) bringing the second surface and the fluid receiving surface into fluid transfer proximity, e) transferring fluid from the second surface to the fluid receiving surface.

Abstract: An apparatus for producing a deep-nested embossed product including a first embossing member and a second embossing member. The first embossing member has a plurality of discrete embossing elements disposed in a first non-random pattern. The second embossing member has a plurality of second embossing elements including at least one linear embossing element. The second embossing elements are disposed in a second non-random pattern such the first non-random pattern and the second non-random pattern nest together to a depth of greater than about 0.01 mm.

Abstract: An apparatus for producing a deep-nested embossed product including a first embossing member and a second embossing member. The first embossing member has a plurality of discrete embossing elements disposed in a first non-random pattern. The second embossing member has a plurality of second embossing elements including at least one linear embossing element. The second embossing elements are disposed in a second non-random pattern such the first non-random pattern and the second non-random pattern nest together to a depth of greater than about 0.01 mm.

Abstract: A method for processing a web material having a machine direction and a cross-machine direction coplanar and perpendicular thereto is disclosed herein. The method incorporates the step of first directing a web material proximate to an air foil. Steam is then applied to the web material by the air foil. Finally, the web material is processed by any downstream web material processing operation.

Abstract: The present disclosure provides for a method for transferring fluid. The method provides for the steps of: a) providing a fluid transfer component comprising a first surface, a second surface, a non-random pattern of distinct pores, the pores connecting the first surface and the second surface, the pores being disposed at preselected locations to provide a desired pattern of permeability, b) providing a fluid receiving component comprising a fluid receiving surface, c) motivating a fluid into contact with the first surface and subsequently through the distinct pores to the second surface, d) bringing the second surface and the fluid receiving surface into fluid transfer proximity, e) transferring fluid from the second surface to the fluid receiving surface.

Abstract: The present disclosure provides for an apparatus for transferring fluid. The apparatus has a fluid transfer component, a fluid receiving component, a fluid supply, and a fluid motivating component. The fluid transfer component has a first surface, a second surface, a non-random pattern of distinct pores each defining a pathway between the first and second surfaces, a single entry point at the first surface, and a single exit point at the second surface. The pores are disposed at preselected locations to provide a desired pattern of permeability. The fluid receiving component comprises a fluid receiving surface. The fluid supply is adapted to provide a fluid in contact with and at a constant fluid pressure with the first surface of the fluid transfer component. The fluid motivating component is adapted to facilitate transport of the fluid from the first surface through the pores to the second surface.

Abstract: The present disclosure provides for an apparatus for transferring fluid. The apparatus has a fluid transfer component, a fluid receiving component, a fluid supply, and a fluid motivating component. The fluid transfer component comprises first surface, a second surface, a non-random pattern of distinct pores each defining a pathway between the first and second surfaces, each pathway having a single entry point at the first surface and a single exit point at the second surface. The pores are disposed at preselected locations to provide a desired pattern of permeability. The fluid receiving component comprises a fluid receiving surface. The fluid supply is adapted to provide a fluid in contact with and at a constant fluid pressure with each of said pores. The fluid motivating component is adapted to facilitate transport of the fluid from the first surface through the pores to the second surface.

Abstract: An apparatus and method for enabling the transfer of a fluid to a web material, the apparatus comprising a fluid transfer component having a first surface, a second surface, and a non-random pattern of distinct pores. The pores connect the first surface and the second surface and are disposed at preselected locations to provide a desired pattern of permeability. The apparatus also comprises a fluid receiving component comprising a fluid receiving surface, a fluid supply adapted to provide a fluid in contact with the first surface of the fluid transfer component, and a fluid motivating component adapted to facilitate transport of the fluid from the first surface through the pores to the second surface. The method comprises steps of providing the apparatus, motivating a fluid through the pores and bringing the fluid receiving component into contact with the motivated fluid.

Abstract: The present invention relates to free-flowing compositions in a pouch having one or more compartments. The compartment and preferably the pouch as a whole are made from stretchable material, typically an elastic film which is water-soluble. The compositions are preferably cleaning compositions or fabric care compositions, in particular laundry or dish washing compositions.

Abstract: A film-forming composition for use in preparing water-soluble films that are rapidly dissolving under cold water conditions, the composition comprising a water soluble polymer material such as polyvinyl alcohol and a principal solvent, typically diol(s) or derivative of a diol. Films made from the film-forming compositions may be used to encapsulate a variety of compositions for subsequent release into an aqueous medium. Encapsulated compositions can include various laundry detergents and additives, fabric care compositions such as fabric softening compositions and dishwashing detergents among others. When used to encapsulate compositions, the solvent system used in the film-forming composition will have at least one common solvent material as the solvent system used in the encapsulated composition to improve film dissolution and to prevent problems associated with solvent migration.

Abstract: An apparatus for producing an embossed product including a first embossing member having a plurality of discrete embossing elements disposed in a first non-random pattern having at least one first single pattern unit. The total area of the distal ends of the discrete embossing elements in the first single pattern unit is less than about 5.0 cm2. The apparatus also includes a second embossing member having a plurality of linear embossing elements disposed in a second non-random pattern having at least one second single pattern unit. The total area of the second distal ends in the second single pattern unit is less than about 10 cm2. The second non-random pattern is coordinated with the first non-random pattern such that when engaged with each other the first single pattern unit and the second single pattern unit make up an embossing pattern single pattern unit.

Abstract: A process for the production of water-soluble pouches. The process comprises the steps of drawing a first film into a mould to form a first compartment, adding composition to the first compartment, drawing a second film into the mould to form a second compartment which comprises a composition and, preferably, sealing. The first film is perforated and the second film is drawn into the mould by means of suction applied through the first film. This eliminates the need to align separately formed pouches or containers. This also reduces the total amount of film needed to produce a multi-compartment pouch. Furthermore, it is very easy to vary the film material used according to what properties are desired. Since the different compartments may require different properties this adds flexibility to the process. Process particularly suited for the production of water soluble pouches such as cleaning or fabric care pouches.

Abstract: A method for producing a deep-nested embossed product is disclosed. The method comprises the steps of: a) providing an embossing apparatus having mating first and second embossing members; b) providing the first embossing member with a plurality of discrete embossing elements in a non-random pattern; c) providing the second embossing member with at least one linear embossing element; d) coordinating the at least one linear embossing element with the non-random pattern of first embossing elements; e) aligning the first embossing member and the second embossing member so that the non-random pattern of first embossing elements nest with the at least one linear embossing element to an engagement depth of greater than about 0.01 mm; f) providing one or more plies of material to the embossing apparatus; and, g) passing the one or more plies of the material between the first and second embossing members to produce the deep-nested embossed product.

Abstract: An apparatus for producing a deep-nested embossed product including a first embossing member and a second embossing member. The first embossing member has a plurality of discrete embossing elements disposed in a first non-random pattern. The second embossing member has a plurality of second embossing elements including at least one linear embossing element. The second embossing elements are disposed in a second non-random pattern such the first non-random pattern and the second non-random pattern nest together to a depth of greater than about 0.01 mm.