TH10935B - Mixtures of polymerized organic resins and parts prepared from them - Google Patents

Abstract

Describe the polyol (allyl carbonate) organic resin mixtures, for example, diethylene glycolbis (allicl carbonate) from approximately 30 to 90. % By wt. And mixtures of apical aliphatic urethanes, consisting of an allylyl or acrylic function group, from approximately 10 to 70, for example, 10 to 30% by weight. That can form a polymer It is prepared from such a mixture that produces a cast that has a low yellowness (b *) and is not released from the mold before it is molded. Polymerization substances prepared from the above mixtures. May be used to prepare photochromic objects. For example, a lens By adding a photochromic substance, for example, by transferring heat to the polymerization substance,

Claims (9)

1. Organic compound to polymerize, consisting of copolymerized mixtures of: (a) polyols (allyl carbons) and (b) from approx. 10 to approximately 70% by weight of the end-aliphatic urethane mixtures with a function group chosen from a group consisting of allic and acrylic group. Aliphatic mixture The aforementioned urethanes, represented by at least two of the following representations: (1) DBABD (2) DBABD \ '(3) D \' - BABD \ ', where D represents the tip containing the moo. The lillil D \ 'represents the tip, which contains the acrylic group B, the part containing the aliphatic biscarbamic, which is represented by the formula -OC (O) -NH (E) NH-C (O) -O- where E is the aliphatic residual. The diisocyanates and A in each aliphatic urethane contained in the aliphatic urethane mix represent the rest of the aliphatic urethanes. Saturated diol, selected from a group containing C2-C6, alkane, diol, diethylene glycol, polyester, diol, polyether diol or polycas. Carbonate diols, mole ratios of the aforementioned allil groups Towards the acrylic group in aliphatic The eurethane contained in the mixture is from approximately 15: 1 to approximately 1: 1. 2. Polymerization compound according to claim 1, polyol (allyl carbonate) is diethylene glycolbis (A Lalil carbonate) and aliphatic mixtures Eurethanes are present in amounts from approximately 10 to approximately 30 percent by weight. 3. Mixture that can form polymers according to claim 1, where A is the remainder of the polyester. Saturated diols with a molecular weight of approximately 400 to approximately 1000 or C2-C6 alkanes. 4. Mixture that can form a polymer. According to claim 3, where the polyester diol is poly (caprolactone) diol 5. Mixture that can form polymers According to claim 3, the alkane diol is 1,4-butane diol. 6. Mixture that can form polymers According to claim 1, that aliphatic diisocyanate is isophoron diisocyanate. 7. Mixture that can form polymers According to claim 2, where A is the rest of the polyester Saturated diols with a molecular weight of approximately 400 to approximately 1000 or C2-C6 alkanes. 8.Mixtures that can form polymers According to claim No. 7, which is the polyester diol that is poly (Caprolactone) diol alkane diol is 1,4-butane, diol and aliphatic. Diisocyanate is an isophorone. Diisocyanate 9.Mixtures that can form polymers According to claim 8, where D is the alkyl group and D \ 'is the acrylic group. CH2 = C (L) -C (O) -O-CH2-CH2- where L is hydrogen or methyl 1. 0. Mixture that can form polymers According to claim 1, where D is an allil group and D \ 'is acrylic group. CH2 = C (L) -C (O) -O-CH2-CH2- where L is hydrogen or methyl 1. 1. Mixture that can form a polymer. According to claim 3, where D is an allil group, D \ 'is acrylic group. CH2 = C (L) -C (O) -O-CH2-CH2- where L is hydrogen or methyl polyester, diol is poly (caprolactone) diol. And that alkydiol is 1,4-butanediol 1. 2. Mixture that can form a polymer. According to claim No. 2, which aliphatic mixtures Eurethane is also composed of A mixture of urethanes, represented by the expression (1) DBA \ '- BD (2) DBA "-BD (3) D \' - BA \ '- BD (4) D \' - BA" - BD, where A \ 'is a polyester diol and A "is C2-C6 alkane diol 1. 3. Mixture that can form polymers According to Clause 12, which the polyester That diol is poly (Caprolactone) diol Which has a molecular weight of about 400 to roughly 1,000, and that alkane diol is 1,4-butanediol 1. 4. Mixture that can form a polymer. According to claim 13, where D is an allil group and D \ 'is acrylic group. CH2 = C (L) -C (O) -O-CH2-CH2- where L is hydrogen or methyl 1. 5. Mixture that can form polymers According to Clause 14, which Aliphatic Diisocyanate is an isophorone. Diisocyanate 1 6. Mixture that can form polymers According to claim No. 2, which the aliphatic mixtures Eurethanes are made up of blends of urethanes, which are represented by (1) DBA \ '- BD (2) DBA \' - BD \ '(3) D \' - BA \ '- performances. BD \ ', where A \' is a polyester diol 1. 7. Mixture that can form polymers According to Clause 16, which polyester That diol is poly (Caprolactone) diol, with a molecular weight of about 400 to approximately 1000 1. 8.Mixtures that can form polymers According to claim 17, where D is an allil group and D \ 'is the acrylic group. CH2 = C (L) -C (O) -O-CH2-CH2- where L is hydrogen or methyl 1. 9.Mixtures that can form polymers According to Clause 18, which Aliphatic Diisocyanate is an isophorone. Diisocyanate 2 0. Mixture that can form polymers According to claim 2, the mixture is from approximately 0.1 to approximately 0.5 percent by weight of dialkyl. Pyrocarbonate, which can be represented by the formula R "-OC (O) -OC (O) -OR", where R "is selectable from a group consisting of C1-C12 alkyls and C6-C10 cycloalkyls, depending on the weight of the mixtures that are Resulting in a copolymer that 2 1. Mixture that can form a polymer. According to claim 20, which dialkylpyrocorbate is diethylpyrocarbonate 2. 2. Mixture that can form a polymer. According to claim 12, the mixtures are from approximately 0.1 to approximately 0.5 percent by weight of dialkylpyrocarbonate, which can be represented by the formula R "-OC (O) -OC (O) -OR", where R "is selectable from a group consisting of C1-C12 alkyls and C6-C10 cycloalkyls, depending on the weight of the mixtures that are Resulting in 2 copolymers 3. Mixture that can form polymers According to claim 22, which dialkylpyrocarbonate is diethylpyrocarbonate 2. 4. Mixture that can form a polymer. According to claim 16, the mixtures are from approximately 0.1 to approximately 0.5 percent by weight of dialkyl. Pyrocarbonate, which can be represented by the formula R "-OC (O) -OC (O) -OR", where R "is selectable from a group consisting of C1-C12 alkyls and C6-C10 cycloalkyls, depending on the weight of the mixtures that are Resulting in a copolymer that 2 5. Mixture that can form polymers According to claim 24, which dialkylpyrocorbate is diethylpyrocarbonate 2. 6.The solid organic resin is prepared by polymerizing the mixture according to claim 2 to form a polymer 2. 7. Solid organic resin according to claim 26, which contains photochromic content. Of photochromic substances Of organic photochromic substances Which can be selected from a group consisting of Spiro (Indolino) Naphthoxacine Spiro (Indolino) Pyridobenzoxene Spiro (Indolino) Benzopyran Spiro (indolino), naphthopyran chromums, spiro (benzene, dolino), pyridobenzoxene Spiro (dolino benzene) Naphthoxene Spiro (dolino benzene) Naphthopyran Metal dithisonate full guide full gimide spiro (dihydroindolysine) And mixtures of these photochromic substances 2 8.Solid organic resin according to claim 26, in which photochromic substances are selected from a group consisting of spiro (indolino), naphthoxin, spiro (indolino). Pyridobenzocene, spiro (indolino) benzoxene chromium and a mixture of these 2 photoschromic substances 9. Solid organic resin is prepared by polymerizing the mixture according to claim 12 to form a polymer 3. 0. Solid organic resins are prepared by polymerizing the mixture according to claim 16.