TH21190B - The process for making the free-branched long-chain polypropylene polymer and its usefulness. - Google Patents

Abstract

Revealed a process for making most amorphous to crystalline polypropylene polymer materials, gel-free, typically solid. Which has separate branches at the free ends of various polypropylene units And have a viscosity when stretched and can harden with stress By making this polypropylene polymer material degrade as well. Peroxides are mostly non-oxygenated at certain temperatures for a certain period of time, and then inactivate free radicals in this material.

Claims (2)

1. A process for making polypropylene polymer material that is gel-free, normally solid with branch index index less than 1 and viscosity on elongation that can be stress-hardened by polymeric materials. The mostly non-crystalline non-crystalline propylene polymer, is a normal solid which is not viscous when stretching stress-hardening, which includes: (1) peroxide blends with The decomposition temperature is low to the linear propylene polymer material, where the material is at room temperature up to 120 \ 'C in a mixing vessel in an oxygen-free atmosphere or an oxygen-equivalent substance. Significantly (2) heat the resulting mixtures or maintain the resulting mix in an anaerobic atmosphere. Or significantly oxygen-equivalent substances at room temperature up to 120 \ 'C is a sufficient time for the degradation of peroxide, for the formation of linear propylene polymer materials. Significant amount of rupture occurs, and for producing significant quantities of long-chain branching, but not sufficient to induce gelling of polypropylene material. The polymer (3) is significantly effective against polypropylene polymer materials in an aerobic atmosphere or with an oxygen-equivalent substance. This significantly makes all the free radicals present in the aforementioned polypropylene material not agile. 2. Process according to claim 1, in which the polypropylene polymer material is The majority of amorphous to crystalline nors mentioned are semi-crystalline polypropylene, mostly isotactic, gel-free, typically solid. Clause 1, where this low decomposition temperature peroxide has a half-life of less than or equal to 5 minutes in the temperature range from approximately 90 \ 'C to 120 \' C, or less than 40 minutes in the temperature range from approximately 60 \ '. A half-life of approximately 90 \ 'H or has a half-life of less than 60 minutes in the temperature range from room temperature to approximately 60 \' H 4. The process of claim 3, where this low decomposition temperature peroxide is selected from Group consisting of Di (sec-butyl) peroxidicar-botanate, bis (2-ethoxi) peroxidicarbonate, di-cyclohexilper out Di-n-propyl-peroxidicarbonate, di-n-butyl peroxidiccarbonate, di-sec-buty Tilper Oxidicarbonate, Di-isopropyl Peroxidicarbonate, t-Butyl Peroxidation Neodecanoate, t-amylperoxy Neodeka-Noate and t-butyl peroxipivalate 5. Process according to claim 1, the half-life of this low decomposition temperature peroxide is approximately 10 s to approx. 5 minutes at the temperature used in step (2) 6. Process according to claim 1, where the temperature of this step (2) is 60 \ '- 110 \' h 7. The process according to claim 1, where this temperature is 70 \ '- 105 \' C 8. Method according to claim 1, where the peroxide concentration at this low decomposition temperature is from 0.005 to 0.05 mmol / g of the propylene polymer material. The precursor method 9. The process according to claim 3, the peroxide concentration at this low decomposition temperature is from 0.005 to 0.05 mmol / g of the substrate polypropylene polymer 1 0. The process according to claim 1, which stabilizes this polypropylene polymer material or maintains at the applied temperature in step (2) for at least 20 seconds before the temperature peroxide is added. Low Decomposition 1 1. A process for making a gel-free, normally solid polypropylene polymer material with a branching index of less than 1 and having a elongated viscosity that causes Stress-hardened from amorphous to crystalline polypropylene material, usually solids which are not viscous when elongated with stress-hardening, which includes: (1) Mix peroxide with low decomposition temperature and peroxide with high decomposition temperature. With linear propylene polymer materials, in which the material is at room temperature up to 120 \ 'z in a mixing vessel in an atmosphere where there is no oxygen or a substance equivalent to oxygen is significantly (2 ) Heats or maintains this effective mixture in an atmosphere where there is no significant oxygen or oxygen-equivalent substance at room temperature up to 120 \ 'C for a sufficient time for the decomposition of the peroxide at Low decomposition temperature, for making linear, propylene polymer materials. Significant amount of rupture occurs, and for producing significant quantities of long-chain branching, but not sufficient to induce gelling of polypropylene material. The polymer (3) reacts to this polypropylene polymer material in an atmosphere where there is no oxygen or an oxygen-equivalent substance present. Which significantly makes all available free radicals present in the aforementioned propylene polymer material. From peroxides with low decomposition temperatures, this high decomposition temperature peroxides decomposes and then free any remaining free radicals. The high decomposition temperature peroxide contained in the aforementioned polypropylene material is not agile. 1 2. The process of claim 11, in which polypropylene is a Mostly crystalline morphology, as mentioned above, is semi-crystalline polypropylene, mostly isotactic, gel-free, usually solid.1 3. Process according to claim 11, where This low decomposition temperature peroxide is selectable from a group consisting of di (sec-butyl) peroxidicarbonate bis (2-ethoxy) peroxidicar. Botanate, di-cyclohexylperoxidicarbonate, di-n-propyl peroxidicarbonate, di-n-butyl peroxid Carbonate, di-sec-butylperoxidicarbonate, diisopropyl peroxidiccarbonate, t-butyl peroxini Odecanoate, t-amylperoxy Neodecanoate and t-butyl peroxipivalate 1 4. Process according to claim 11, where this high decomposition temperature peroxide is selected from the group consisting of 2,5-dimethyl-2, 5-bis (t-butoperoxi) hexane, bis (t-butyoperoxi-isopropyl) benzene, Dicumyl peroxide, 4, 4-di-t-butyl peroxy-n-butyl-valerate, t-amyl peroxibenzoate, t-butyl Taper oxybenzoate, 2, 2-di-t-butylperoxibutane, t-butyl peroxy-3, 5, 5-trymethylhelene Gxanoate, t-butiperoxisopropyl carbonate and 1, 1-di-t-butylperoxyclohexane 1. 5. Based process. Clause 11, this low decomposition peroxide has a half-life of less than or equal to 5 minutes in the temperature range from approximately 90 \ 'C to 120 \' C, or half-life of less than 40 minutes in the temperature range from Approximately 60 \ 'C to approximately 90 \' H, or half-life of less than 60 minutes in the temperature range from room temperature to approximately 60 \ 'C, and this high decomposition temperature peroxide has a half-life greater than or equal to 20 minutes at 90 \ 'H, but less than 60 minutes at the temperature used in step (3) 1 6. Treatment according to claim 15, this low decomposition temperature peroxide has a half-life of 10 s to 5 min at the Used in step (2) 1 7. Process according to the clause Clause 15, this high decomposition temperature peroxide has a half-life of 10 s to 10 min at the temperature used in step (3) 1 8. The process of claim 11, where the temperature of the step (2) Is 60 \ '- 110 \' C 1 9. Process according to claim 11, where the temperature of this step (2) is 70 \ '- 105 \' H 2 0. Process according to claim 11, where the temperature of the step (3) This is about 130 \ '- 150 \' h 2. 1. Process according to claim 19 where the temperature of this step (3) is approximately 140 \ '- 150 \' h 2. 2. Process according to claim 11, where the temperature of this step (2) is stable and maintained for at least 20 seconds before the addition of peroxides with low and high decomposition temperatures.