Low rise, user friendly latex foams for sealing insulative cavities of a building are provided. The foams may be applied to the interface of the sheathing and the studs within the insulative cavities to reduce air leaks. The latex foams may also be applied to the face of the studs to obtain an addit
Low rise, user friendly latex foams for sealing insulative cavities of a building are provided. The foams may be applied to the interface of the sheathing and the studs within the insulative cavities to reduce air leaks. The latex foams may also be applied to the face of the studs to obtain an additional seal against air infiltration. The foam can be used to affix fiberglass batts, batt flanges, and vapor barriers to the framing without mechanical fasteners. A tackifier may be added to impart an adhesive quality to the foam. The tacky nature of the foam permits the drywall or vapor barrier to be repositioned without damage. Drywall is held onto the face of the studs by the tacky foam while mechanical fasteners are inserted to permanently affix the drywall to the framing. The compressive nature of the foam permits drywall to be attached without significant bowing or detachment.
대표청구항▼
1. A method of forming an interior surface of a building wall, said building wall including a frame formed of a plurality of studs interconnecting a top plate and a bottom plate, thereby forming insulative cavities between said studs, said building wall being backed by sheathing, each of said studs
1. A method of forming an interior surface of a building wall, said building wall including a frame formed of a plurality of studs interconnecting a top plate and a bottom plate, thereby forming insulative cavities between said studs, said building wall being backed by sheathing, each of said studs having an interior face, comprising the steps of: spraying a material selected from a foamable material and a foamable reaction mixture to said interior face of said studs, wherein said spraying comprises:a) delivering a first component including at least one functionalized resin selected from a functionalized water-dispersible resin and a functionalized water-soluble resin through a first delivery line to an application device;b) delivering a second component including a crosslinking agent that crosslinks at or about room temperature into said application device, wherein one or both of said first and second component includes a blowing agent, and wherein one or both of said first and second component includes a tackifier; andc) mixing said first and second components within said application device to form said foamable reaction mixture by permitting said crosslinking agent and said at least one functionalized resin to chemically react while said blowing agent initiates a foaming reaction and forms a tacky, elastomeric foam; wherein the material is sprayed along an interface between the exterior sheathing and the bottom plate, along the top plate, and along the vertical length of the studs; andpositioning an interior member on said elastomeric foam, wherein said elastomeric foam affixes said interior member to said interior face of said studs, and wherein said elastomeric foam, said foamable material and said foamable reaction mixture are free of isocyanate. 2. The method of claim 1, wherein said interior member is a vapor barrier, said foam holding said vapor barrier to said interior face of said studs. 3. The method of claim 2, wherein said vapor barrier may be repeatedly repositioned. 4. The method of claim 2, further comprising the step of: affixing drywall on said vapor barrier with mechanical fasteners without significant bowing or detachment of said drywall from said vapor barrier. 5. The method of claim 4, further comprising the step of: spraying said foamable reaction mixture to a first interface of said studs and sheathing, a second interface of said top plate and said sheathing, and a third interface of said bottom plate and said sheathing within one or more of said insulative cavities. 6. The method of claim 1, wherein said blowing agent is selected from a single chemical compound that generates a gas upon heating, irradiation, or photo initiation, said method further including the step of degrading said blowing agent to generate a gas and initiate said foaming reaction. 7. The method of claim 1, wherein said blowing agent is formed of an acid and a base, wherein said first component includes said base when said second component includes said acid; and wherein said first component includes said acid when said second component includes said base, said method further comprising the step of reacting said acid and said base to form a gas to initiate said foaming reaction. 8. The method of claim 7, wherein said acid is polyacrylic acid, said base is sodium bicarbonate, and said foam has a structure; and wherein said polyacrylic acid reacts with said sodium bicarbonate to form CO2 gas as said blowing agent and said polyacrylic acid further reacts with said crosslinking agent to become integrated with said foam structure. 9. The method of claim 7, wherein said base is sodium bicarbonate having a mean particle size from about 2 to about 40 microns. 10. The method of claim 1, wherein said blowing agent is a phase change blowing agent under pressure, said method further including the step of releasing said blowing agent from said pressure to initiate a phase change of said blowing agent from a liquid to a gas and initiate said foaming reaction. 11. The method of claim 10, wherein said phase change blowing agent is selected from low boiling point hydrocarbons and inert gases. 12. The method of claim 1, wherein said at least one of said functionalized resin, said crosslinking agent, and said blowing agent are encapsulated in one or more encapsulating shells, said method further comprising releasing said functionalized resin, said crosslinking agent, and/or said blowing agent from said one or more encapsulating shells. 13. The method of claim 1, wherein said first component comprises one or more members selected from a functionalized latex and an acrylic solution. 14. The method of claim 1, wherein said second component further comprises a nonfunctionalized latex. 15. The method of claim 1, wherein at least one of said first component and said second component further includes an alcohol co-solvent. 16. The method of claim 1, wherein said crosslinking agent is selected from aziridines, multifunctional carbodiimides, polyfunctional aziridines, melamine formaldehyde, polysiloxanes and multifunctional epoxies. 17. A method of sealing a wall cavity defined between opposing vertically oriented wall panels affixed to opposing sides of a top plate comprising: applying a gasket member selected from a foamable material and a foamable reaction mixture on opposing sides of said top plate; wherein said applying comprises:a) delivering a first component including at least one functionalized resin selected from a functionalized water-dispersible resin and a functionalized water-soluble resin through a first delivery line to an application device;b) delivering a second component including a crosslinking agent that crosslinks at or about room temperature into said application device, wherein one or both of said first and second component includes a blowing agent; andc) mixing said first and second components within said application device to form a foamable reaction mixture, and permitting said crosslinking agent and said at least one functionalized resin to chemically react while said blowing agent initiates a foaming reaction and forms a sealing and/or insulative elastomeric foam; andaffixing said wall panels on said opposing sides of said top plate over said gasket member, wherein a foam seal is formed to restrict the flow of air into an attic space from said wall cavity, and wherein said elastomeric foam, said foamable material and said foamable reaction mixture are free of isocyanate. 18. The method of claim 17, wherein said crosslinking agent is selected from aziridines, multifunctional carbodiimides, polyfunctional aziridines, melamine formaldehyde, polysiloxanes and multifunctional epoxies. 19. The method of claim 17, wherein said blowing agent is selected from a single chemical compound that generates a gas upon heating, irradiation, or photo initiation, said method further including the step of degrading said blowing agent to generate a gas and initiate said foaming reaction. 20. The method of claim 17, wherein said blowing agent is formed of an acid and a base, wherein said first component includes said base when said second component includes said acid; and wherein said first component includes said acid when said second component includes said base, said method further comprising the step of reacting said acid and said base to form a gas to initiate said foaming reaction. 21. The method of claim 20, wherein said acid is polyacrylic acid, said base is sodium bicarbonate, and said foam has a structure; and wherein said polyacrylic acid reacts with said sodium bicarbonate to form CO2 gas as said blowing agent and said polyacrylic acid further reacts with said crosslinking agent to become integrated with said foam structure. 22. The method of claim 17, wherein said blowing agent is a phase change blowing agent under pressure, said method further including the step of releasing said blowing agent from said pressure to initiate a phase change of said blowing agent from a liquid to a gas and initiate said foaming reaction. 23. The method of claim 17, further comprising forming said foam seal by: applying a gasket member to opposing sides of the top plate by spraying a foamable composition or a foamable reaction mixture onto said opposing sides of the top plate and initiating a foaming reaction to form the elastomeric foam seal.
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