Abstract: A thermal appliance is provided. The thermal appliance includes a heating compartment inside of an enclosure, with insulation disposed between the heating compartment and enclosure. Retainers or standoffs are also included in the thermal appliance to prevent air gaps from forming between the insulation and the heating compartment, and to prevent the insulation from making contact with the enclosure.

Abstract: A thermal appliance is provided. The thermal appliance includes a heating compartment inside of an enclosure, with insulation disposed between the heating compartment and enclosure. Retainers or standoffs are also included in the thermal appliance to prevent air gaps from forming between the insulation and the heating compartment, and to prevent the insulation from making contact with the enclosure.

Abstract: A method of forming a needled fiberglass glass insulation product is provided. The formation of the needled insulation product may be conducted in a process in which the fibers are formed, a binder is sprayed onto the fibers, the fibers are collected and formed into a fiberglass pack, the fiberglass pack is passed through the oven, and at least partially cured insulation blanket is passed through a needling apparatus. The reduction in thickness and increased density caused by the needling process permits the production of lower thickness and high density insulation products.

Abstract: A thermal appliance is provided. The thermal appliance includes a heating compartment inside of an enclosure, with insulation disposed between the heating compartment and enclosure. Retainers or standoffs are also included in the thermal appliance to prevent air gaps from forming between the insulation and the heating compartment, and to prevent the insulation from making contact with the enclosure.

Abstract: A method of forming a needled fiberglass glass insulation product is provided. The formation of the needled insulation product may be conducted in a process in which the fibers are formed, a binder is sprayed onto the fibers, the fibers are collected and formed into a fiberglass pack, the fiberglass pack is passed through the oven, and at least partially cured insulation blanket is passed through a needling apparatus. The reduction in thickness and increased density caused by the needling process permits the production of lower thickness and high density insulation products.

Abstract: A method of forming a needled rotary fiberglass glass insulation product is provided. The formation of the needled insulation product may be conducted in a continuous in-line process in which the fibers are rotary formed, a binder is sprayed onto the hot fibers, the fibers are collected onto a conveyor and formed into a fiberglass pack, the fiberglass pack is passed through the oven, and the cured insulation blanket is passed through a needling apparatus. The reduction in thickness and increased density caused by the needling process permits the production of lower thickness and higher density insulation products. In particular, the needled insulation product may have a thickness of less than about 0.75 inches and a density from about 1 pcf to about 10 pcf. The needled insulation product may be utilized in household appliances, water heaters, and HVAC equipment.

Abstract: An insulated scuttle cover configured for placement within a building scuttle opening is provided. The insulated scuttle cover includes a scuttle panel configured to cover the building scuttle opening. The scuttle panel is further configured to be supported when positioned within the building scuttle opening. An insulated pouch assembly is positioned adjacent to the scuttle panel. The insulated pouch assembly includes insulation material sealed within a flexible pouch. The insulated pouch assembly is positioned on an attic side of the scuttle panel. The insulated scuttle cover is configured to prevent or substantially retard the flow of air passing through the building scuttle opening.

Abstract: Insulated scuttle covers configured for placement within a building scuttle opening are provided. The insulated scuttle cover includes a scuttle panel configured to cover the building scuttle opening and further configured to be supported when positioned within the building scuttle opening. An insulative assembly is attached to the scuttle panel. The insulative assembly includes insulation material encapsulated by a jacket. The insulated scuttle cover is configured to prevent or substantially retard the flow of air passing through the building scuttle opening.

Abstract: An insulation panel and a method of insulating a pipeline are disclosed by the present application. In one exemplary embodiment, the insulation panel includes one or more pieces of compressible fiberglass insulation material and a coated fabric cover encasing the one or more pieces of insulation material. The coated fabric cover includes a first fastening portion disposed along a first end of the insulation panel and a second fastening portion disposed between the first end and a second end of the insulation panel. The first end of the insulation panel overlaps the second end of the insulation panel when the insulation panel is installed on a pipeline or other structure. Further, attachment of the first fastening portion to the second fastening portion secures the coated fabric cover around the pipeline or other structure.

Abstract: Insulated scuttle covers configured for placement within a building scuttle opening are provided. The insulated scuttle cover includes a scuttle panel configured to cover the building scuttle opening and further configured to be supported when positioned within the building scuttle opening. An insulative assembly is attached to the scuttle panel. The insulative assembly includes insulation material encapsulated by a jacket. The insulated scuttle cover is configured to prevent or substantially retard the flow of air passing through the building scuttle opening.

Abstract: A pipeline and an insulation system for a pipeline are disclosed by the present application. In one exemplary embodiment, a pipeline includes a pipe, insulation disposed around the pipe, a hard outer shell that encases the insulation disposed around the pipe, and a plurality of insulation panels secured around the hard outer shell that encases the insulation disposed around the pipe. The insulation panel includes one or more pieces of compressible fiberglass insulation material having an R value per inch of thickness from about 2 to about 13 hr-sq ft-deg F/Btu measured at 75 degrees Fahrenheit and a coated fabric cover encasing the one or more pieces of insulation material. The coated fabric cover has a weight from about 5 to about 40 oz/sq yd.

Abstract: Insulation for high temperature applications includes glass fibers having an average diameter of between about 2.7 to about 3.8 microns. In one possible embodiment the insulation includes a polyacrylic acid binder. Such insulation has about 98 weight percent glass fibers and about 2 weight percent binder.

Abstract: A needled rotary fiberglass glass insulation product including (1) a plurality of single component rotary glass fibers where at least a portion of the fibers are entangled and mechanically bonded and (2) a binder applied to at least a portion of the glass fibers is provided. The needled insulation product may have a thickness less than about 0.75 inches and a density from about 1 pcf to about 10 pcf. In exemplary embodiments, the thickness may be from about 0.25 to about 0.5 inches and the density may be from about 3 pcf to about 5 pcf. Additionally, a fire-retarding layer may be positioned on the insulation product. The needled rotary glass insulation product has a thermal conductivity that is equivalent to or less than conventional, lofty insulation blankets and may be utilized in household appliances, water heaters, and HVAC equipment.

Abstract: A method of forming a needled rotary fiberglass glass insulation product is provided. The formation of the needled insulation product may be conducted in a continuous in-line process in which the fibers are rotary formed, a binder is sprayed onto the hot fibers, the fibers are collected onto a conveyor and formed into a fiberglass pack, the fiberglass pack is passed through the oven, and the cured insulation blanket is passed through a needling apparatus. The reduction in thickness and increased density caused by the needling process permits the production of lower thickness and higher density insulation products. In particular, the needled insulation product may have a thickness of less than about 0.75 inches and a density from about 1 pcf to about 10 pcf. The needled insulation product may be utilized in household appliances, water heaters, and HVAC equipment.

Abstract: A flexible composite multiple layer fire-resistant insulation structure has a primary facing surface and a secondary facing surface. There is at least one dimensionally stable membrane having a primary membrane surface and a secondary membrane surface. At least a portion of the secondary facing surface is attached to the primary membrane surface. There is also at least one lofted insulative layer having a primary insulative surface and a secondary insulative surface. The at least one woven fabric facing layer may be formed of various materials, including amorphous silica glass and S-glass fiberglass. Different weaving patterns may be used to weave the facing layer. The facing layer may include a fire resistive treatment, which may in turn include a phosphate containing compound, and more particularly, may include dicalcium phosphate. In certain embodiments, multiple layers of the above are provided, and the structure may be enclosed in an abrasion resisting sheath.

Abstract: Insulation for high temperature applications includes glass fibers having an average diameter of between about 2.7 to about 3.8 microns. In one possible embodiment the insulation includes a polyacrylic acid binder. Such insulation has about 98 weight percent glass fibers and about 2 weight percent binder.