A viscoelastic foam is provided having an amine-based polyol system to impart strength, recoverability and endurance to the foam, and an appropriately selected trifunctional non-amine-based polyol system to provide flexibility to the foam. The combination of amine-based and non amine-based polyols p
A viscoelastic foam is provided having an amine-based polyol system to impart strength, recoverability and endurance to the foam, and an appropriately selected trifunctional non-amine-based polyol system to provide flexibility to the foam. The combination of amine-based and non amine-based polyols provides a viscoelastic semi-rigid foam with excellent impact and recovery properties, recovering to substantially 100% of its initial volume and shape following an impact, yet with high rigidity and stiffness so that it is effective at absorbing high as well as low-energy impacts. A method of making the above viscoelastic foam is also provided. In a preferred embodiment, the foam is made using an allophanate-modified MDI prepolymer in order to provide the isocyanate in liquid form at standard temperature and pressure in order to simplify the production of the invented viscoelastic foams.
대표청구항▼
What is claimed is: 1. A semi-rigid viscoelastic foam made from a Part A composition and a Part B composition, said Part A composition comprising 20-50 weight percent isocyanate (NCO), said Part B composition comprising 1-15 parts by weight propylene oxide-extended monoethanolamine-based polyether
What is claimed is: 1. A semi-rigid viscoelastic foam made from a Part A composition and a Part B composition, said Part A composition comprising 20-50 weight percent isocyanate (NCO), said Part B composition comprising 1-15 parts by weight propylene oxide-extended monoethanolamine-based polyether polyol, 6-25 parts by weight propylene oxide-extended triethanolamine-based polyether polyol, 22-40 parts by weight propylene oxide-extended ethylenediamine-based polyether polyol, at least 10 parts by weight of an additional polyol selected from the group consisting of filled polyether polyols and unfilled polyether polyols, and 0.4-4 parts by weight catalyst, said Part B composition having 100 parts by weight total polyols, said Part A and Part B compositions being combined to provide said semi-rigid viscoelastic foam. 2. A semi-rigid viscoelastic foam made from a Part A composition and a Part B composition, said Part A composition comprising 20-50 weight percent isocyanate (NCO), said Part B composition comprising 1-15 parts by weight propylene oxide-extended monoethanolamine-based polyether polyol, 6-25 parts by weight propylene oxide-extended triethanolamine-based polyether polyol, 22-40 parts by weight propylene oxide-extended ethylenediamine-based polyether polyol, at least 10 parts by weight of an additional, tri-functional polyether polyol, and 0.4-4 parts by weight catalyst, said Part B composition having 100 parts by weight total polyols, said Part A and Part B compositions being combined to provide said semi-rigid viscoelastic foam. 3. A semi-rigid viscoelastic foam according to claim 1 or 2, having an index of 80-115. 4. A semi-rigid viscoelastic foam according to claim 1 or 2, having an index of about 90-100. 5. A semi-rigid viscoelastic foam according to claim 1 or 2, said Part B composition further comprising about 3 parts by weight water. 6. A semi-rigid viscoelastic foam according to claim 1 or 2, said Part B composition further comprising about 6 parts by weight black paste. 7. A semi-rigid viscoelastic foam according to claim 1 or 2, said isocyanate in said Part A composition being present in the form of 4, 4'-MDI. 8. A semi-rigid viscoelastic foam according to claim 7, said 4,4'-MDI being present in said Part A composition in an amount sufficient to provide an isocyanate (NCO) concentration of about 33.6 percent by weight. 9. A semi-rigid viscoelastic foam according to claim 1 or 2, said isocyanate in said Part A composition being present in the form of an allophanate-modified MDI prepolymer, said part A composition having an isocyanate (NCO) concentration of about 20-30 percent by weight. 10. A semi-rigid viscoelastic foam according to claim 1 or 2, said monoethanolamine based polyol being present in an amount of less than 10 parts by weight, said triethanol amine based polyol being present in an amount of greater than 10 parts by weight, and said ethylenediamine based polyol being present in an amount of 22-36 parts by weight. 11. A semi-rigid viscoelastic foam according to claim 1 or 2, said catalyst comprising amine catalyst in an amount of 0.4-2.5 parts by weight, delayed action catalyst in an amount of 0-1 parts by weight, and trimer catalyst in an amount of 0-1 parts by weight. 12. A semi-rigid viscoelastic foam according to claim 11, said amine catalyst being tertiary amine catalyst, said delayed action catalyst being a combination delayed action catalyst, said trimer catalyst being a quatemary ammonium salt timer catalyst. 13. A semi-rigid viscoelastic foam according to claim 1 or 2, said additional polyol being a glycerin based polyether polyol. 14. A semi-rigid viscoelastic foam according to claim 2, said tri-functional polyether polyol being a non-amine based polyether polyol. 15. A method of making a viscoelastic foam comprising the steps of: a) providing a Part A composition comprising 20-50 weight percent isocyanate; b) providing a Part B composition comprising 1-15 parts by weight propylene oxide-extended monoethanolamine-based polyether polyol, 6-25 parts by weight propylene oxide-extended triethanolamine-based polyether polyol, 22-40 parts by weight propylene oxide-extended ethylenediamine-based polyether polyol, at least 10 parts by weight of an additional polyol selected from the group consisting of filled polyether polyols and unfilled polyether polyols, and 0.4-4 parts by weight catalyst, said Part B composition having 100 parts by weight total polyols; and c) combining said Part A and Part B compositions to provide a semi-rigid viscoelastic foam having an index of 70-130. 16. A method of making a viscoelastic foam comprising the steps of: a) providing a Part A composition comprising 20-50 weight percent isocyanate; b) providing a Part B composition comprising 1-15 parts by weight propylene oxide-extended monoethanolamine-based polyether polyol, 6-25 parts by weight propylene oxide-extended triethanolamine-based polyether polyol, 22-40 parts by weight propylene oxide-extended ethylenediamine-based polyether polyol, at least 10 parts by weight of an additional, tri-functional polyether polyol, and 0.4-4 parts by weight catalyst, said Part B composition having 100 parts by weight total polyols; and c) combining said Part A and Part B compositions to provide a semi-rigid viscoelastic foam having an index of 70-130. 17. A method according to claim 15 or 16, said semi-rigid viscoelastic foam having an index of 90-100. 18. A method according to claim 15 or 16, said Part B composition further comprising about 3 parts by weight water. 19. A method according to claim 15 or 16, said Part B composition further comprising about 6 parts by weight black paste. 20. A method according to claim 15 or 16, said isocyanate in said Part A composition being present in the form of 4,4'-MDI. 21. A method according to claim 20, said 4,4'-MDI being present in said Part A composition an amount sufficient to provide an isocyanate (NCO) concentration of about 33.6 percent by weight in said Part A composition. 22. A method according to claim 15 or 16, said isocyanate in said Part A composition being present in the form of an allophanate-modified MDI prepolymer. 23. A method according to claim 15 or 16, said monoethanolamine based polyol being present in an amount of less than 10 parts by weight, said triethanol amine based polyol being present in an amount of greater than 10 parts by weight, and said ethylenediamine based polyol being present in in an amount of 22-36 parts by weight. 24. A method according to claim 15 or 16, said catalyst comprising amine catalyst in an amount of 0.4-2.5 parts by weight a delayed action catalyst in an amount of 0-1 parts by weight, and a trimer catalyst in an amount of 0-1 parts by weight. 25. A method according to claim 24, said amine catalyst being tertiary amine catalyst, said delayed action catalyst being a combination delayed action amine/delayed action tin catalyst, and said trimer catalyst being a quatemary ammonium salt trimer catalyst. 26. A semi-rigid viscoelastic foam according to claim 1 or 2, said Part B composition further comprising 3-15 parts by weight black paste. 27. A semi-rigid viscoelastic foam according to claim 1 or 2, having an index of 70-130. 28. A semi-rigid viscoelastic foam according to claim 1 or 2, said Part B composition having at least 40 parts by weight total amine-based polyether polyol, wherein the amounts of all polyether polyols in said Part B composition sum to 100 parts by weight. 29. A semi-rigid viscoelastic foam according to claim 1 or 2, said foam being recoverable following a high energy impact. 30. A semi-rigid viscoelastic foam according to claim 29, said foam being substantially 100% recoverable following said high energy impact. 31. A semi-rigid viscoelastic foam according to claim 1 or 2, wherein on impact with a flat circular impactor having a 4-inch diameter according to test method ASTM F2040, a sample of said foam measuring 5. 5"횞5.5"횞1" exhibits breakthrough acceleration in the range of 100 to 150 g's for an impact speed of 2-6 meters/second. 32. A semi-rigid viscoelastic foam, said foam being made from a Part A composition and a Part B composition, said Part A composition comprising 20-50 weight percent isocyanate (NCO), said Part B composition comprising water, at least one catalyst and each of the following, all in parts by weight: 1-15 parts propylene oxide-extended monoethanolamine-based polyether polyol, 6-25 parts propylene oxide-extended triethanolamine-based polyether polyol, 22-40 parts propylene oxide-extended ethylenediamine-based polyether polyol. 0-50 parts filled polyol, and 0-50 parts unfilled polyol; wherein said Part B composition includes at least one of said filled or unfilled polyols, said Part B composition having 100 parts by weight total polyols. 33. A semi-rigid viscoelastic foam according to claim 32, said filled and unfilled polyols each being glycerin-based and at least tri-functional. 34. A semi-rigid viscoelastic foam according to claim 33, said part B composition comprising 20-30 parts by weight unfilled polyol and 20-30 parts by weight filled polyol. 35. A semi-rigid viscoelastic foam according to claim 34, said foam having an index of 80-115. 36. A semi-rigid viscoelastic foam according to claim 1, 2, or 32, said part B composition comprising 40-60 parts by weight total amine-based polyol. 37. A semi-rigid viscoelastic foam according to claim 36, said part B composition comprising 20-30 parts by weight unfilled polyol and 20-30 parts by weight filled polyol. 38. A semi-rigid viscoelastic foam according to claim 37, said filled and unfilled polyols each being glycerin-based and at least tri-functional.
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