Abstract: Polyurethane foams formed at above atmospheric pressure conditions using methylene diisocyanate or a specific mixture of polyisocyanate and with a major portion of methylene diisocyanate (MDI) with a specific mixture of polyether and graft polyols produces high density viscoelastic foams with improved hand touch (surface smoothness) that better retain viscoelasticity over time. The foam-forming ingredients are mixed together and foamed at controlled pressures in the range 1.05 to 1.5 bar (absolute), preferably 1.1 to 1.3 bar (absolute).

Abstract: Polyurethane foams formed using a specific mixture of polyether and graft polyols with toluene diisocyanate have fine cell size (over 70 pores per inch) and higher durability with IFD25 retention over 70% after 12,000 cycles of roll-shear. The foam-forming ingredients are mixed together and foamed at controlled pressures in the range 1.0 to 1.5 (absolute), preferably 1.05 to 1.5 bar (absolute). The foams make particularly good carpet cushions.

Abstract: Polyurethane foams formed at above atmospheric pressure conditions using methylene diisocyanate or a specific mixture of polyisocyanate and with a major portion of methylene diisocyanate (MDI) with a specific mixture of polyether and graft polyols produces high density viscoelastic foams with improved hand touch (surface smoothness) that better retain viscoelasticity over time. The foam-forming ingredients are mixed together and foamed at controlled pressures in the range 1.05 to 1.5 bar (absolute), preferably 1.1 to 1.3 bar (absolute).

Abstract: Polyurethane foams formed under vacuum (below atmospheric pressure) conditions using toluene diisocyanate or a specific mixture of polyisocyanates with a specific mixture of polyether and graft polyols produces a foam with lower density and better flame retardancy than latex foam, but with equally high resiliency. The foam-forming ingredients are mixed together and foamed under controlled pressures in the range 0.6 to 0.95 bar (absolute), preferably 0.8 to 0.95 bar (absolute). The resulting foam has a ball rebound above about 65 percent.

Abstract: An apparatus for shaping a slab of compressible or cellular polymer material (80), such as polyurethane foam, shapes such slab by cutting portions of the material from one surface. A moving patterned platform (32), preferably an endless belt or a series of interconnected panels, is interposed between a compression roller (56) and a cooperating surface (18) and defines at least one recess (36) or at least one projection (320) or a combination of recesses and projections. When the slab is compressed between the compression roller and the platform, which is supported by the cooperating surface, a portion of the material fills the recess or recesses in the moving platform.

Abstract: A method for shaping a slab of polyurethane foam (80) cuts portions of the foam material from one surface. A moving patterned platform (32) is interposed in a gap formed between a compression roller (56) and a drive roller (18) and defines at least one recess (36). The slab is introduced into the gap and foam material is compressed into the recess. At least a portion of the compressed material within the recess is then cut from the surface of the slab by a blade (76) just as the slab emerges from the gap to produce a profile-cut surface with a shaped portion corresponding to the shape of the recess in the patterned platform.

Abstract: A laminate structure for making a cushioned component for a vehicle interior, such as a seat cushion or head rest, has a high density foam bonded to an interior surface of a seat cover material. After the laminate structure is formed into a desired shape for the cushioned component, it is inserted into a vacuum mold having a mold surface with a shape corresponding with a desired exterior surface shape of the cushioned component. Liquid foam-forming material is injected into the laminate structure within the mold and allowed to cure to form the cushioned component. The high density foam of the laminate structure preferably has a density of at least 4 lbs/ft3 and an air permeability of 5 to 100 ft3/ft2 minute. This high density foam may be created by felting a polyurethane foam.

Abstract: The present invention relates to mattress or furniture insulator pads that are placed between the coil springs and the cushioning material in mattresses or furniture, such as chair seats. Such insulator pads prevent the springs from piercing the furniture cushion and provide a bridge across the springs to more evenly distribute weight over the springs. The insulator pads according to the invention have three layers formed by sandwiching polyurethane foam between stiffening layers, preferably formed from polypropylene openmesh netting. Most preferably, a five layer insulator pad has the polyurethane foam sandwiched between stiffening layers and also has outer layers of polyurethane foam, applied adjacent to the stiffening layers, forming the top and bottom surfaces of the pad. Such outer layer foam sheets provide friction characteristics that retard relative movement between the cushion and the springs.

Abstract: Foaming a polyurethane foam at above atmospheric pressure conditions using a mixture of polyisocyanate and a specific mixture of low molecular weight (high OH number) polyether and graft polyols produces viscoelastic foams with high firmness, low energy losses and high temperature sensitivity such that firmness is reduced by at least 25% when the foam is heated from room temperature (e.g., about 70° F. (21° C.)) to 100° F. (38° C.). The foam-forming ingredients are mixed together and foamed at controlled pressures in the range 1.05 to 1.5 bar (absolute), preferably 1.1 to 1.3 bar (absolute).

Abstract: Methods and apparatus for eliminating or reducing a surface skin when producing a flexible polyurethane foam slab are disclosed. The top surface of the chemically reactive polyurethane foaming mixture is heated during and/or after the foaming mixture expands. The heating preferably is conducted so as to prevent a significant temperature gradient from forming between the internal temperature of the foaming mixture and the top surface of that mixture. Preferably, heat is applied so as to heat from the top surface of the foaming mixture in an escalating fashion to higher temperatures as the foam is conveyed along a conveying path away from the foaming mixture dispensing device.

Abstract: An ester polyurethane foam is prepared by reacting a mixture of one or more polyester polyols with one or more isocyanates and one or more silicone surfactants in the presence of a blowing agent, such as water, and other additives, such as catalysts. The cured foam is chemically treated in a caustic solution to form a hydrophilic ester polyurethane foam having a water absorption rate of at least 20 pounds of water per square foot per minute, preferably at least 25 pounds of water per square foot per minute. The foam also has greater water holding capacity and wet strength than cellulose.

Abstract: An ink retaining flexible polyurethane foam is prepared by reacting a polyether polyol with from 50 to 80 parts by weight, based on the weight of polyol, of a polyisocyanate component having one or a mixture of methylene diisocyanates. The foam has pore sizes above 70 pores per linear inch, preferably in the range of 70 to 90 pores per linear inch in an uncompressed state. The foam is reticulated to improve liquid holding capacity, and, depending upon cell size, compressed into a container. The foam absorbs and retains ink, and is resistant against attack from ink, producing less than 2.0% solvent extractables.

Abstract: An apparatus for continuously shaping a compressible or cellular polymer material, such as polyurethane foam, by cutting portions of the material from a surface of a slab of the material includes a compression roller, a support surface, a blade and a moving patterned platform interposed between the compression roller and the support surface. The moving patterned platform, preferably an endless belt or a series of interconnected panels, defines at least one recess, and may define a pattern of recesses of complex or simple shapes and at various depths. When the slab of cellular polymer material is compressed between the compression roller and the support surface, a portion of the material fills the recess or recesses in the moving patterned belt. The blade then transversely cuts from the surface of the slab a portion of the material within the recesses in the platform just as the slab emerges from between the compression roller and the support surface.

Abstract: A method for shaping a slab of compressible or cellular polymer material, such as polyurethane foam, by cutting portions of the material from one surface uses a compression roller, a support surface, a blade and a moving patterned platform interposed between the compression roller and the support surface. The moving patterned platform, preferably an endless belt or a series of interconnected panels, defines at least one recess, and may define a pattern of recesses of complex or simple shapes and at various depths. When the slab of cellular polymer material is compressed between the compression roller and the support surface, a portion of the material fills the recess or recesses in the moving patterned belt. At least a portion of the compressed material within the recesses is then cut from the surface of the slab by the blade just as the slab emerges from between the compression roller and the support surface.

Abstract: A hinged flexible polyurethane foam protective packaging element is formed from a flexible polyurethane foam laminated to a polyethylene, polypropylene or urethane film. The flexible polyurethane foam has a density in the range of 0.7 lbs/ft3 to 2.8 lbs/ft3 and IFD25 in the range of 25 lbs to 270 lbs. The film has a thickness from 2 mil to 125 mil. The foam is cut through all or substantially all of its thickness without cutting through a portion of the film. The uncut portion of the film creates a repeatably bendable hinge.

Abstract: A fuel delivery system for a liquid fuel cell particularly useful for portable electronic devices includes (a) a container defining a volume for holding a liquid fuel; (b) a reservoir structure positioned within the volume and into which at least a portion of the liquid fuel wicks and from which said liquid fuel subsequently may be metered, such as by pumping. The reservoir structure is formed from a material with a free rise wick height greater than at least one half of the longest dimension of the reservoir structure. Among materials with such wicking capability are foams, bundled fibers and nonwoven fibers, including particularly felted and unfelted reticulated polyurethane foams. The container may have a generally flat and thin profile, formed as a pouch or envelope with substantially planar top and bottom faces of flexible film material, such that the container holding the reservoir structure and filled with liquid fuel can be bent or shaped.

Abstract: A machine for rotary cutting of continuous synthetic foam sheets while compressed between two rollers has a roller drive featuring individually adjustable roller speed to allow use of rollers of dissimilar diameter, such as a large diameter pattern roller and a small diameter compression roller. The roller drive may be selectively engaged for driving each roller with a separate drive motor or both rollers with a single motor through a gear train, allowing conversion of the machine to conventional foam convoluting using similar sized rollers.

Abstract: Apparatus for continuously shaping a compressible or cellular polymer material, such as polyurethane foam, by cutting portions of the material from a surface of one or more slabs of material (180) includes two compression rollers (146, 146a), two moving patterned platforms (132, 132a) interposed between the compression rollers, and one or more cutting blades (76) for transversely cutting the slab or slabs just as the cellular material emerges from between the compression rollers. At least one of the moving patterned platforms, preferably an endless belt, defines a recess or pattern of recesses. When a single slab or multiple slabs of material are fed and compressed between the compression rollers, a portion of the material from one side of the slab or slabs fills the recess or recesses in one of the moving patterned belts. The blade then transversely cuts the cellular material.

Abstract: Polyurethane foams formed under vacuum (below atmospheric pressure) conditions using methylene diisocyanate or a specific mixture of polyisocyanate and with a major portion of methylene diisocyanate (MDI) with a specific mixture of polyether and graft polyols produces cushioning foams with lower density (1.4 to 1.8 pounds per cubic foot) and higher support factor (above 2.4). The foam-forming ingredients are mixed together and foamed under controlled pressures in the range 0.5 to 0.9 bar (absolute), preferably 0.6 to 0.8 bar (absolute). A major portion of the MDI is 4,4′ methylene diisocyanate.

Abstract: An ink retaining flexible polyurethane foam is prepared by reacting a polyether polyol with from 20 to 50 parts by weight, based on the weight of polyol, of a polyisocyanate component having one or a mixture of toluene diisocyanates, such that the 2,4 isomer of toluene diisocyanate includes no more than seventy-five percent by weight of the polyisocyanate component, preferably no more than seventy two and one half percent by weight. The foam has pore sizes in the range of 70 to 88 pores per inch in an uncompressed state. The foam is reticulated to improve liquid holding capacity, and, depending upon pore size, felted to compression ratios from 1 to 2 up to from 1 to 20. The foam absorbs and retains ink, and is resistant against attack from ink, emitting less than 2.0% solvent extractables, preferably less than 1.1% solvent extractables.