초록 ▼

Fluoropolymers are made by admixing tetrafluoroethylene, hexfluoropropylene, and vinylidene fluoride; reacting the reaction admixture to generate a set of fluoropolymeric oligomers; irradiating the fluoropolymeric oligomeric precursor admixture (preferably with electron beam radiation) to form free

Fluoropolymers are made by admixing tetrafluoroethylene, hexfluoropropylene, and vinylidene fluoride; reacting the reaction admixture to generate a set of fluoropolymeric oligomers; irradiating the fluoropolymeric oligomeric precursor admixture (preferably with electron beam radiation) to form free radical sites on individual fluoropolymeric oligomers of the set and generate thereby a set of free radical oligomer derivatives in the fluoropolymeric oligomeric precursor admixture; and reacting the fluoropolymeric oligomeric precursor admixture to derive the fluoropolymer compound from the free radical oligomer derivatives. In a second approach, fluoropolymers are made by admixing tetrafluoroethylene, hexfluoropropylene, and vinylidene fluoride and irradiating the admixture.

대표청구항 ▼

What is claimed is: 1. A method for making a branched polymer composition, comprising: (a) reacting monomers into a plurality of oligomer molecules, each oligomer molecule in said plurality of oligomer molecules having a first end and a second end; and (b) irradiating said oligomer molecules with r

What is claimed is: 1. A method for making a branched polymer composition, comprising: (a) reacting monomers into a plurality of oligomer molecules, each oligomer molecule in said plurality of oligomer molecules having a first end and a second end; and (b) irradiating said oligomer molecules with radiation sufficient for energizing at least one atom at an interim location between said first end and said second end on each oligomer molecule to form activated oligomer molecules so that (1) the energized atom directly separates from the activated oligomer molecule at said interim location, and (2) a free radical site remains on each activated oligomer molecule at said interim location; (c) wherein a plurality of said activated oligomer molecules bond at said free radical sites at their respective interim locations, forming branched polymer portions; (d) said branched polymer composition consists essentially of polymer molecules having said branched polymer portions; and (e) said branched polymer composition comprises polymer selected from the group consisting of fluoroelastomer, acrylic elastomer, ethylene/acrylic elastomer, nitrile rubber, polyurethane, silicone rubber, ethylene-propylene rubber, thermoplastic elastomer derived from fluoroelastomeric oligomer in said oligomer molecules, thermoplastic elastomer derived from acrylic elastomeric oligomer in said oligomer molecules, thermoplastic elastomer derived from ethylene/acrylic elastomeric oligomer in said oligomer molecules, thermoplastic elastomer derived from nitrile rubber oligomer in said oligomer molecules, thermoplastic elastomer derived from polyurethane oligomer in said oligomer molecules, thermoplastic elastomer derived from silicone rubber oligomer in said oligomer molecules, and thermoplastic elastomer derived from ethylene-propylene rubber oligomer in said oligomer molecules. 2. A method according to claim 1 wherein said reacting comprises irradiating the monomers to generate the oligomer molecules. 3. A method according to claim 1 wherein said irradiating uses electron beam radiation. 4. A method according to claim 1 wherein said irradiating uses electron beam radiation of from about 0.1 MeRAD to about 40 MeRAD. 5. A method according to claim 1 wherein said irradiating uses electron beam radiation from about 5 MeRAD to about 20 MeRAD. 6. A branched polymer composition made by: (a) reacting monomers into a plurality of oligomer molecules, each oligomer molecule in said plurality of oligomer molecules having a first end and a second end; and (b) irradiating said oligomer molecules with radiation sufficient for energizing at least one atom at an interim location between said first end and said second end on each oligomer molecule to form activated oligomer molecules so that (1) the energized atom directly separates from the activated oligomer molecule at said interim location, and (2) a free radical site remains on each activated oligomer molecule at said interim location; (c) wherein a plurality of said activated oligomer molecules bond at said free radical sites at their respective interim locations forming branched polymer portions; (d) said branched polymer composition consists essentially of polymer molecules having said branched polymer portions; and (e) said branched polymer composition comprises polymer selected from the group consisting of fluoroelastomer, acrylic elastomer, ethylene/acrylic elastomer, nitrile rubber, polyurethane, silicone rubber, ethylene-propylene rubber, thermoplastic elastomer derived from fluoroelastomeric oligomer in said oligomer molecules, thermoplastic elastomer derived from acrylic elastomeric oligomer in said oligomer molecules, thermoplastic elastomer derived from ethylene/acrylic elastomeric oligomer in said oligomer molecules, thermoplastic elastomer derived from nitrile rubber oligomer in said oligomer molecules, thermoplastic elastomer derived from polyurethane oligomer in said oligomer molecules, thermoplastic elastomer derived from silicone rubber oligomer in said oligomer molecules, and thermoplastic elastomer derived from ethylene-propylene rubber oligomer in said oligomer molecules. 7. A polymer according to claim 6 wherein said irradiating uses electron beam radiation. 8. A polymer according to claim 6 wherein said irradiating uses electron beam radiation of from about 0.1 MeRAD to about 40 MeRAD. 9. A polymer according to claim 6 wherein said irradiating uses electron beam radiation from about 5 MeRAD to about 20 MeRAD. 10. A polymer according to claim 6 wherein said reacting comprises irradiating the monomers to generate the oligomer molecules. 11. A polymer according to claim 10 wherein said irradiating the monomers uses electron beam radiation. 12. A polymer according to claim 10 wherein said irradiating the monomers uses electron beam radiation of from about 0.1 MeRAD to about 40 MeRAD. 13. A polymer according to claim 10 wherein said irradiating the monomers uses electron beam radiation from about 5 MeRAD to about 20 MeRAD. 14. An article of polymer made by a process comprising forming said article from a branched polymer composition made by a process comprising: (a) reacting monomers into a plurality of oligomer molecules, each oligomer molecule in said plurality of oligomer molecules having a first end and a second end; and (b) irradiating said oligomer molecules with radiation sufficient for energizing at least one atom at an interim location between said first end and said second end on each oligomer molecule to form activated oligomer molecules so that (1) the energized atom directly separates from the activated oligomer molecule at said interim location, and (2) a free radical site remains on each activated oligomer molecule at said interim location; (c) wherein a plurality of said activated molecules bond at said free radical sites at their respective interim locations forming branched polymer portions; (d) said branched polymer composition consists essentially of polymer molecules having said branched polymer portions; and (e) said branched polymer composition comprises polymer selected from the group consisting of fluoroelastomer, acrylic elastomer, ethylene/acrylic elastomer, nitrile rubber, polyurethane, silicone rubber, ethylene-propylene rubber, thermoplastic elastomer derived from fluoroelastomeric oligomer in said oligomer molecules, thermoplastic elastomer derived from acrylic elastomeric oligomer in said oligomer molecules, thermoplastic elastomer derived from ethylene/acrylic elastomeric oligomer in said oligomer molecules, thermoplastic elastomer derived from nitrile rubber oligomer in said oligomer molecules, thermoplastic elastomer derived from polyurethane oligomer in said oligomer molecules, thermoplastic elastomer derived from silicone rubber oligomer in said oligomer molecules, and thermoplastic elastomer derived from ethylene-propylene rubber oligomer in said oligomer molecules. 15. An article according to claim 14 wherein said irradiating uses electron beam radiation. 16. An article according to claim 15 wherein said irradiating uses electron beam radiation of from about 0.1 MeRAD to about 40 MeRAD. 17. An article according to claim 16 wherein said irradiating uses electron beam radiation from about 5 MeRAD to about 20 MeRAD. 18. An article according to claim 14 wherein said article is selected from the group consisting of a seal, a gasket, a pump diaphragm, a hose, and an o-ring. 19. An article according to claim 18, wherein said article is a seal. 20. A method of making a polymer article comprising a branched polymer composition, said method comprising: (a) placing monomers into the cavity of a mold for said article; (b) forming said branched polymer composition by reacting said monomers in said mold into a plurality of oligomer molecules, each oligomer molecule in said plurality of oligomer molecules having a first end and a second end; and (c) irradiating said oligomer molecules with radiation sufficient for energizing at least one atom at an interim location between said first end and said second end on each oligomer molecule to form activated oligomer molecules so that (1) the energized atom directly separates from the activated oligomer molecule at said interim location, and (2) a free radical site remains on each activated oligomer molecule at said interim location; (d) wherein a plurality of said activated oligomer molecules bond at said free radical sites at their respective interim locations forming branched polymer portions; (e) said branched polymer composition consists essentially of polymer molecules having said branched polymer portions; and (f) said branched polymer composition comprises polymer selected from the group consisting of fluoroelastomer, acrylic elastomer, ethylene/acrylic elastomer, nitrile rubber, polyurethane, silicone rubber, ethylene-propylene rubber, thermoplastic elastomer derived from fluoroelastomeric oligomer in said oligomer molecules, thermoplastic elastomer derived from acrylic elastomeric oligomer in said oligomer molecules, thermoplastic elastomer derived from ethylene/acrylic elastomeric oligomer in said oligomer molecules, thermoplastic elastomer derived from nitrile rubber oligomer in said oligomer molecules, thermoplastic elastomer derived from polyurethane oligomer in said oligomer molecules, thermoplastic elastomer derived from silicone rubber oligomer in said oligomer molecules, and thermoplastic elastomer derived from ethylene-propylene rubber oligomer in said oligomer molecules. 21. A method according to claim 20 wherein said irradiating uses electron beam radiation. 22. A method according to claim 20 wherein said irradiating uses electron beam radiation of from about 0.1 MeRAD to about 40 MeRAD. 23. A method according to claim 20 wherein said irradiating uses electron beam radiation from about 5 MeRAD to about 20 MeRAD. 24. A method according to claim 20 wherein said article is selected from the group consisting of a seal, a gasket, a pump diaphragm, a hose, and an o-ring. 25. A method of making a polymer article comprising a branched polymer composition, said method comprising: (a) placing monomers into the cavity of a mold for said article; and (b) forming said branched polymer composition by irradiating said monomers with radiation sufficient for generating oligomers comprising a plurality of oligomer molecules, each oligomer molecule in said plurality of oligomer molecules having a first end and a second end, and for energizing at least one atom at an interim location on each activated oligomer molecule in a plurality of activated oligomer molecules in said oligomers so that (1) the energized atom directly separates from the activated oligomer molecule at said interim location, and (2) a free radical site remains on each activated oligomer molecule at said interim location; (c) wherein a plurality of said activated oligomer molecules bond at said free radical sites at their respective interim locations forming branched polymer portions; (d) said branched polymer composition consists essentially of polymer molecules having said branched polymer portions; and (e) said branched polymer composition comprises polymer selected from the group consisting of fluoroelastomer, acrylic elastomer, ethylene/acrylic elastomer, nitrile rubber, polyurethane, silicone rubber, ethylene-propylene rubber, thermoplastic elastomer derived from fluoroelastomeric oligomer in said oligomers, thermoplastic elastomer derived from acrylic elastomeric oligomer in said oligomers, thermoplastic elastomer derived from ethylene/acrylic elastomeric oligomer in said oligomers, thermoplastic elastomer derived from nitrile rubber oligomer in said oligomers, thermoplastic elastomer derived from polyurethane oligomer in said oligomers, thermoplastic elastomer derived from silicone rubber oligomer in said oligomers, and thermoplastic elastomer derived from ethylene-propylene rubber oligomer in said oligomers. 26. A method according to claim 25 wherein said irradiating uses electron beam radiation. 27. A method according to claim 25 wherein said irradiating uses electron beam radiation of from about 0.1 MeRAD to about 40 MeRAD. 28. A method according to claim 25 wherein said irradiating uses electron beam radiation from about 5 MeRAD to about 20 MeRAD. 29. A method according to claim 25 wherein said article is selected from the group consisting of a seal, a gasket, a pump diaphragm, a hose, and an o-ring. 30. An article of polymer made by a process according to the method of claim 20. 31. An article according to claim 30 wherein said irradiating uses electron beam radiation. 32. An article according to claim 30 wherein said irradiating uses electron beam radiation of from about 0.1 MeRAD to about 40 MeRAD. 33. An article according to claim 30 wherein said irradiating uses electron beam radiation from about 5 MeRAD to about 20 MeRAD. 34. An article according to claim 30 wherein said article is selected from the group consisting of a seal, a gasket, a pump diaphragm, a hose, and an o-ring. 35. An article of polymer made by a process according to the method of claim 25. 36. An article according to claim 35 wherein said irradiating uses electron beam radiation. 37. An article according to claim 35 wherein said irradiating uses electron beam radiation of from about 0.1 MeRAD to about 40 MeRAD. 38. An article according to claim 35 wherein said irradiating uses electron beam radiation from about 5 MeRAD to about 20 MeRAD. 39. An article according to claim 35 wherein said article is selected from the group consisting of a seal, a gasket, a pump diaphragm, a hose, and an o-ring.