CN1224640C - Method for preparing uvioresistant polyester by nanometer titania in situ - Google Patents

Method for preparing uvioresistant polyester by nanometer titania in situ Download PDF

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CN1224640C
CN1224640C CN 200310122743 CN200310122743A CN1224640C CN 1224640 C CN1224640 C CN 1224640C CN 200310122743 CN200310122743 CN 200310122743 CN 200310122743 A CN200310122743 A CN 200310122743A CN 1224640 C CN1224640 C CN 1224640C
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titanium oxide
nano
polyester
nanometer titanium
titanium dioxide
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CN1552764A (en
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徐宏
程存康
林嵩
古宏晨
吴亚妮
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Shanghai Jiaotong University
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Abstract

The present invention relates to a preparation method of ultra-violet radiation resistant polyester by utilizing nanometer titanium dioxide in situ, which belongs to the technical field of composite materials. The preparation method comprises the following steps: firstly, adopting nanometer titanium dioxide as an ultraviolet shielding agent and processing the nanometer titanium dioxide in an inorganic/organic complex surface modification mode in order to cause the nanometer titanium dioxide to be homogeneously dispersed over one of polymerized monomer of polyester, namely dibasic alcohol; then, processing the prepared nanometer titanium dioxide/dibasic alcohol slurry into the average particle diameter of the nanometer titanium oxide to be smaller than 50 nm by dispersing at high speed and circularly grinding with sand; finally, polymerizing or copolymerizing the nanometer titanium dioxide/dibasic alcohol slurry with other monomers of polyester; obtaining the ultra-violet radiation resistant nanometer titanium dioxide/polyester composite material in situ in the process of polymerization. The ultraviolet shielding index of fabrics obtained by spinning and weaving the composite materials is larger than 50, the ultraviolet shielding rate of thin films prepared from the materials is larger than 99%, and the mechanical property is decreased by smaller than 5% after the materials are irradiated by ultraviolet rays for 1000 hours. The composite material can be applied to the technical fields of fiber, thin films, engineering plastics, etc. in order to enhance the capabilities of shielding ultraviolet rays and resisting aging of the materials.

Description

Utilize the method for nano titanium oxide in-situ preparing anti-ultraviolet radiation poly ester
Technical field
The present invention relates to a kind of preparation method of polyester, particularly a kind of method of utilizing nano titanium oxide in-situ preparing anti-ultraviolet radiation poly ester.Belong to field of compound material.
Technical background
In recent years, because forest vegetation is destroyed aggravation, Sunspot Activities is frequent and factors such as a large amount of uses freon refrigerant make the mankind be faced with enhanced ultraviolet radiation day by day, ultraviolet ray be divided into UVC (200~280nm), UVB (280~320nm), UVA (320~400nm) three districts.UVC is absorbed by ozonosphere, to the basic not damaged effect of human body.UVB can be absorbed by dermis of skin, and permanent irradiation erythema, inflammation, skin aging can occur, can cause skin carcinoma when serious.The UVA penetrance is dark more than UVB, can make skin pitch-dark, and long-term accumulation will cause skin aging.Simultaneously, the energy that ultraviolet ray has is about 314~419KJ/mol, is enough to destroy chemical bond, the initiation autoxidation reaction of polymkeric substance, causes the degradation with aging of polymkeric substance such as plastics, rubber, coating resin, and the loss that therefore cause every year is huge.
At present, the polyester with the ageing-resistant function of uvioresistant mainly adopts interpolation uvioresistant additive to carry out the preparation of blended melting method.The uvioresistant additive is divided into organic and inorganic two big classes.Inorganic UV shield agent becomes research and uses focus with characteristics such as the chemistry of its brilliance and thermostability, non-migrating, tasteless, nontoxic, nonirritants.Find by literature search, Chinese patent application number is: 00816956.X, name is called: contain m-phthalic acid, 1, the copolyester of 4-cyclohexanedimethanol and ultraviolet absorber compounds and by its goods of making, publication number is: 1409737, this patent disclosure a kind of copolyester blend of anti-ultraviolet radiation, it comprises having 1, the polyethylene terephthalate base copolyester of 4-cyclohexanedimethanol: significant quantity be selected from benzoxazinone, dimeric benzotriazole, the ultraviolet radiation absorber of triazine and composition thereof, through uviolizing after 1536 hours, the colour-change of sheet material is littler 3.4 times than unmodified with the copolyester blend sheet material of this method preparation.But this method has certain toxicity owing to adopted the UV light absorber of organic class, and their less stable in resin matrix are decomposed in material processing easily simultaneously, and the heat resistance of goods is restricted.Simultaneously skin there is pungency, is not suitable for being applied to fields such as weaving, packaging film.
Summary of the invention
The present invention is directed to the problems referred to above that exist in the background technology, propose a kind of method of utilizing nano titanium oxide in-situ preparing anti-ultraviolet radiation poly ester, make it solve above deficiency.The present invention has at first abandoned organic class UV light absorber, but adopt the inorganic nano ultraviolet screening agent, overcome traditional blend melt spinning method fully and existed UV light absorber and in polymkeric substance, reunite and disperse disadvantages such as intensity irregular, material is low, heat resistance difference, overcome deficiencies such as back finishing technique fabric feeling, ventilative, wearing comfort and function weather resistance be not good.The uvioresistant polyester that the inventive method makes is compared with conventional polyester, and the processibility of material, mechanical property and resistance toheat are unaffected, the remarkable long-acting environment friendly of uvioresistant effect.
The present invention is achieved by the following technical solutions, the preparation method that the present invention proposes polyester is as follows: at first adopting nano titanium oxide is ultraviolet screening agent, then it is carried out inorganic/organic complex surface modification, with organic agent or coupling agent nano titanium oxide is carried out surface organic modification, carry out inorganic modified with surface bag silicon alclad to nano titanium oxide, make it can be dispersed in one of monomer of polyester--in-the dibasic alcohol, by metering the nano titanium oxide/dibasic alcohol slurry for preparing is arrived the median size of nano-titanium oxide less than 50 nanometers by high speed dispersion and circulation sanded then, last and other monomers of polyester carry out polymerization or copolymerization, and original position obtains having good mechanics in polymerization process, anti-ultraviolet nano titanium dioxide/the polyester composite of thermal property.
This material can be used for preparing antiultraviolet fiber, film and various ageing-resistant injection moulding polyester articles etc.Thus the matrix material spinning weave the fabric that obtains the ultraviolet screener index greater than 50, material is made the rate of ultraviolet shield of film greater than 99%.After 1000 hours, the mechanical properties decrease amplitude is less than 5% in uviolizing for material.
Below method of the present invention is done further to limit, concrete steps are as follows:
(1) nano-titanium oxide is carried out the surface inorganic coating modification, at first adopting chemical precipitation method to coat thickness on the nano-titanium oxide surface is the silicon-dioxide of 5 nanometers, adopt equally then and carry out alumina-coated on the nano-titanium oxide of chemical precipitation method after wrapping silicon-dioxide again, coating layer also is 5 nanometers, obtains the modified Nano titanium oxide of surface bag silicon alclad at last.
(2) will be dispersed in 95% the ethanolic soln through inorganic modified nano-titanium oxide, the mass percentage content of nano-titanium oxide is 20%, with polymer organic treatment agent or coupling agent it is carried out surface organic modification again, consumption is 3~15% of a nano-titanium oxide, and washing and filtering places 1 hour dry for standby of 100 ℃ of baking ovens.
(3) with above-mentioned process inorganic/nano-titanium oxide of organic complex modification is dispersed in the dibasic alcohol, solid content is 5~30% mass percents, at first adopt high speed dispersor that nano-titanium oxide/dibasic alcohol slurry is mixed, use sand mill that slurry is ground dispersion till the titanium oxide particle diameter reaches below 50 nanometers then, detect with laser particle analyzer.
(4) another monomer of the nano-titanium oxide that above-mentioned steps is obtained/dibasic alcohol slurry and polyester---aromatic binary carboxylic acid carries out polyreaction under the condition that has catalyzer and stablizer to exist, the nano-titanium oxide addition of modification accounts for 0.5%~5% of polyester total amount, according to the different field that final material is used, original position obtains the nano-titanium oxide/polyester composite of different molecular weight.
Nano-titanium oxide of the present invention is a rutile crystal type, particle diameter 10~30 nanometers.Described bag silicon is handled and is adopted acid to drip chemical precipitation method, is presoma with the water glass, and the metering of silicon-dioxide quality percentage ratio is 5~10% of nano-titanium oxide.Described alclad is handled and is adopted alkali to drip chemical precipitation method, is presoma with Tai-Ace S 150, and the metering of aluminum oxide quality percentage ratio is 3~8% of nano-titanium oxide.
Polymer organic treatment agent of the present invention is a polyoxyethylene glycol, one or more in polyvinylpyrrolidone, polyvinyl alcohol, polyacrylic acid, the polyacrylamide.Described coupling agent is meant silane coupling agent, one or more in titanate coupling agent and the aluminic acid ester.
The dibasic alcohol of polyester of the present invention is a kind of in ethylene glycol, propylene glycol, the butyleneglycol, and another kind of monomer can be one or more in dimethyl terephthalate (DMT), terephthalic acid, dimethyl isophthalate, naphthalene two dimethyl phthalates.
Nano-titanium oxide through modification of the present invention can participate in the polyester reaction separately, also can together carry out polyreaction with chemical fibre of titanium dioxide.
In-situ polymerization of the present invention prepares nano-titanium oxide/polyester composite and can be used on fields such as fiber, film and engineering plastics.
Compared with prior art, that the present invention at first selects for use is nontoxic, the stabilized nano titanium oxide is as ultraviolet screening agent, and it is carried out having suppressed behind the surface bag silicon photocatalytic activity of nano-titanium oxide, can improve the ageing-resistant performance of goods, adopt surperficial bag rate to improve dispersiveness in the dibasic alcohol of nano-titanium oxide in addition, adopt surface organic modification, can reduce the catalytic activity of nano-titanium oxide greatly, improve PET hue the polyester degraded.It is worthy of note that the present invention adopts in-situ polymerization, solved the agglomeration traits of nano titania particle in matrix, truly realized nanometer homodisperse effect.Nano-titanium oxide/polyester composite of obtaining of method can be used for preparing antiultraviolet fiber, film and various ageing-resistant injection moulding polyester articles etc. thus.Thus the matrix material spinning weave the fabric that obtains the ultraviolet screener index greater than 50, material is made the rate of ultraviolet shield of film greater than 99%.
Embodiment
Provide following examples in conjunction with content of the present invention:
Embodiment 1
Have at 5000mL that to add concentration in the glass reaction still of recirculated water chuck under condition of stirring be that the sodium silicate aqueous solution 2500mL of 0.2molL (presses SiO 2: TiO 2=10%, mass percent), add 500mL deionized water and 30 gram Sodium hexametaphosphate 99s again, heated and stirred 30 minutes, after treating that Sodium hexametaphosphate 99 all dissolves, adding 300 gram median sizes is the rutile type nano titanium oxide of 10 nanometers, aqueous sodium hydroxide solution regulator solution pH value with 1molL is 9.5 ± 1, heat up and stir, when temperature rose to 85 ℃, the continuous dropping of beginning concentration was 10% aqueous sulfuric acid (mass percent), rate of addition is always 9.5 ± 1 with the pH value of keeping reaction solution, after 45 minutes, stop to drip sulfuric acid, the insulation ageing adds analytical pure sulfuric acid aluminium 50 gram backs and (presses Al in reaction solution after 5 hours 2O 3: TiO 2=5%, mass percent), the solution pH value becomes about 2~3, under 85 ℃ of situations, the aqueous sodium hydroxide solution of Dropwise 5 % stops to drip after the reaction soln pH value is 8.5 in 45 minutes, continues insulation ageing 2 hours, filter, wash 3 times after, place 100 ℃ of baking oven dry for standby.
The ethanol of adding 95% in the 2000mL beaker, stir and add 30 gram polyvinylpyrrolidones down, be heated to 70 ℃, after treating that polyvinylpyrrolidone dissolves fully, get the above-mentioned nano-titanium oxide of handling through bag silicon alclad and it is pulverized, and weighing 300 grams place above-mentioned ethanolic soln with stirrer, at 70 ℃ of following stirring reactions after 1 hour, filter, after washing is placed on and activates 1 hour in 100 ℃ of baking ovens, dry for standby.
Above-mentioned nano-titanium oxide through inorganic/organic common modification is dispersed in 1500mL ethylene glycol, and to be made into concentration be 20% slurry, at first in high speed dispersor with its dispersion, in the recirculation system sand grinding machine, grind then, in the process of lapping slurry is carried out testing graininess with laser particle analyzer, when the mean particle size of nano-titanium oxide in the slurry during less than 50 nanometers, stop to grind, the discharging slurry is standby.
8000g terephthalic acid, 3812g ethylene glycol and above-mentioned nano-titanium oxide slurry 235 grams are together added in 30 liters of polyester stills the making beating back, use antimony glycol to be polymerization stabilizer, carry out polyreaction as polycondensation catalyst, trimethyl phosphite 99.Feed nitrogen, the esterification of this process is carried out under 0.2Mpa pressure, polycondensation final stage still internal pressure should remain below 80Pa.Keep high vacuum discharging after 220 minutes, obtain nano-titanium oxide/polyester composite.The form and aspect L value 82.82 of resin, form and aspect b value 3.59, limiting viscosity are 0.680,260.8 ℃ of fusing points, carboxyl-content are 20mol.t -1, glycol ether content is 0.9%.
With above-mentioned nano-titanium oxide/polyester composite resin 150 ℃ of dryings after 48 hours in vacuum drying oven, the ultraviolet screener index UPF value of carrying out making after spinning, drawing-off, the manufacturing thickness and be 50 microns plain is 50.
With above-mentioned nano-titanium oxide/polyester composite resin 150 ℃ of dryings after 6 hours in vacuum drying oven, the film that carries out making after membrane, the drawing-off thickness and be 20 microns is a transparence, ultraviolet average transmittances (280~400nm) 0.9%.
Embodiment 2
According to embodiment 1 described method, different is to carry out the surface bag silicon of nano-titanium oxide by SiO 2: TiO 2=5%, mass percent, alclad is pressed Al 2O 3: TiO 2=3%, mass percent, the polyvinylpyrrolidone consumption is 15% of a nano-titanium oxide consumption.
According to nano-titanium oxide/polyester composite that embodiment 1 described method prepares, the form and aspect L value 80.10 of resin, form and aspect b value 6.07, limiting viscosity are 0.660,260.1 ℃ of fusing points, carboxyl-content are 20mol.t -1, glycol ether content is 0.8%.
With above-mentioned nano-titanium oxide/polyester composite resin 150 ℃ of dryings after 48 hours in vacuum drying oven, the ultraviolet screener index UPF value of carrying out making after spinning, drawing-off, the manufacturing thickness and be 50 microns plain is 50.
With above-mentioned nano-titanium oxide/polyester composite resin 150 ℃ of dryings after 6 hours in vacuum drying oven, the film that carries out making after membrane, the drawing-off thickness and be 20 microns is a transparence, ultraviolet average transmittances (280~400nm) 0.14%.
Embodiment 3
According to embodiment 1 described method, different is to carry out the surface bag silicon of nano-titanium oxide by SiO 2: TiO 2=8%, mass percent, alclad is pressed Al 2O 3: TiO 2=8%, mass percent.
According to nano-titanium oxide/polyester composite that embodiment 1 described method prepares, the form and aspect L value 81.65 of resin, form and aspect b value 5.66, limiting viscosity are 0.659,262.7 ℃ of fusing points, carboxyl-content are 19mol.t -1, glycol ether content is 1.1%.
With above-mentioned nano-titanium oxide/polyester composite resin 150 ℃ of dryings after 48 hours in vacuum drying oven, the ultraviolet screener index UPF value of carrying out making after spinning, drawing-off, the manufacturing thickness and be 50 microns plain is 50.
With above-mentioned nano-titanium oxide/polyester composite resin 150 ℃ of dryings after 6 hours in vacuum drying oven, the film that carries out making after membrane, the drawing-off thickness and be 20 microns is a transparence, ultraviolet average transmittances (280~400nm) 0.12%.
Embodiment 4
Carry out the inorganic/organic surface modifying of nano-titanium oxide according to embodiment 1 described method, different is, and to carry out organically-modified agents useful for same be polyoxyethylene glycol, and consumption is 3% of a nano-titanium oxide consumption, and other processing modes are all identical with temperature of reaction.
Be dispersed in the ethylene glycol according to the nano-titanium oxide of embodiment 1 described method with modification, different is that solid content of slurry is 5%.
8000g dimethyl terephthalate (DMT), 944g ethylene glycol and above-mentioned nano-titanium oxide slurry 4388 grams are together added in 30 liters of polyester stills the making beating back, use antimony glycol to be polymerization stabilizer, carry out polyreaction as polycondensation catalyst, trimethyl phosphite 99.Esterification is carried out under normal pressure, and polycondensation final stage still internal pressure should remain below 80Pa.Keep high vacuum discharging after 185 minutes, obtain nano-titanium oxide/polyester composite, the form and aspect L value 85.52 of resin, form and aspect b value 5.18, limiting viscosity are 0.656,261.2 ℃ of fusing points, carboxyl-content are 22mol.t -1, glycol ether content is 1.2%.
With above-mentioned nano-titanium oxide/polyester composite resin 150 ℃ of dryings after 48 hours in vacuum drying oven, the ultraviolet screener index UPF value of carrying out making after spinning, drawing-off, the manufacturing thickness and be 50 microns plain is 168.
With above-mentioned nano-titanium oxide/polyester composite resin 150 ℃ of dryings after 6 hours in vacuum drying oven, the film that carries out making after membrane, the drawing-off thickness and be 20 microns is a transparence, ultraviolet average transmittances (280~400nm) 0.08%.
Embodiment 5
Carry out the inorganic/organic surface modifying of nano-titanium oxide according to embodiment 1 described method, different is, and to carry out organically-modified agents useful for same be silane coupling agent agent KH560, and consumption is 3% of a nano-titanium oxide consumption.Other processing modes are all identical with temperature of reaction.
Be dispersed in the ethylene glycol according to the nano-titanium oxide of embodiment 1 described method with modification, different is that solid content of slurry is 30%.
With the 7600g dimethyl terephthalate (DMT), 400 gram dimethyl isophthalates, 4182 gram ethylene glycol and above-mentioned nano-titanium oxide slurry 1330 grams are together in 30 liters of polyester stills of making beating back adding, use antimony glycol to be polymerization stabilizer, carry out polyreaction as polycondensation catalyst, trimethyl phosphite 99.Esterification is carried out under normal pressure, and polycondensation final stage still internal pressure should remain below 80Pa.Keep high vacuum discharging after 160 minutes, obtain nano-titanium oxide/polyester composite, the form and aspect L value 83.46 of resin, form and aspect b value 6.39, limiting viscosity are 0.645,263.2 ℃ of fusing points, carboxyl-content are 26mol.t -1, glycol ether content is 1.5%.
With above-mentioned nano-titanium oxide/polyester composite resin 150 ℃ of dryings after 48 hours in vacuum drying oven, the ultraviolet screener index UPF value of carrying out making after spinning, drawing-off, the manufacturing thickness and be 50 microns plain is 159.
With above-mentioned nano-titanium oxide/polyester composite resin 150 ℃ of dryings after 6 hours in vacuum drying oven, the film that carries out making after membrane, the drawing-off thickness and be 20 microns is a transparence, ultraviolet average transmittances (280~400nm) 0.11%.
Embodiment 6
Carry out the inorganic/organic surface modifying of nano-titanium oxide according to embodiment 1 described method, different is, and to carry out organically-modified agents useful for same be the titanate coupling agent agent, and other processing modes are all identical with temperature of reaction.
Be dispersed in the ethylene glycol according to the nano-titanium oxide of embodiment 1 described method with modification, different is that solid content of slurry is 17.5%.
With the 8000g terephthalic acid, 5933 gram butyleneglycols and above-mentioned nano-titanium oxide slurry 1220 grams together in 30 liters of polyester stills of making beating back adding, use tetrabutyl titanate to be polymerization stabilizer as polycondensation catalyst, trimethyl phosphite 99, carry out polyreaction.Esterification is carried out under normal pressure, and polycondensation final stage still internal pressure should remain below 80Pa.Keep high vacuum discharging after 150 minutes, obtain nano-titanium oxide/polyester composite, the form and aspect L value 86.78 of resin, form and aspect b value 7.08, limiting viscosity are 1.06,219.2 ℃ of fusing points.
With above-mentioned nano-titanium oxide/polyester composite resin 80 ℃ of dryings after 12 hours in vacuum drying oven, behind the injection molding standard testing batten, the tensile strength of sample is 58MPa, notched Izod impact strength is 5.8KJ/M2, dimension card modification temperature is 175 ℃, after 1000 hours, the every mechanical properties decrease of material is less than 5% through uviolizing for sample, and material b value is 8.23.
Embodiment 7
According to embodiment 1 described method, different is in polymerization process, except original position adds nano-titanium oxide, chemical fibre of titanium dioxide 28 grams of using as the polyester delustring that also added mean particle size and be 300 nanometers (account for 0.3% of weight polyester, mass percent), behind the in-situ polymerization, obtain nano-titanium oxide/delustring polyester composite.The form and aspect L value 88.97 of resin, form and aspect b value 3.78, limiting viscosity are 0.686,261.1 ℃ of fusing points, carboxyl-content are 26mol.t -1, glycol ether content is 1.0%.
With above-mentioned nano-titanium oxide/polyester composite resin 150 ℃ of dryings after 48 hours in vacuum drying oven, the ultraviolet screener index UPF value of carrying out making after spinning, drawing-off, the manufacturing thickness and be 50 microns plain is 69.
With above-mentioned nano-titanium oxide/polyester composite resin 150 ℃ of dryings after 6 hours in vacuum drying oven, the film that carries out making after membrane, the drawing-off thickness and be 20 microns is a transparence, ultraviolet average transmittances (280~400nm) 0.09%.

Claims (7)

1, a kind of method of utilizing nano titanium oxide in-situ preparing anti-ultraviolet radiation poly ester, it is characterized in that, the preparation method is as follows: at first adopting nano titanium oxide is ultraviolet screening agent, then it is carried out inorganic/organic complex surface modification, with organic agent or coupling agent nano titanium oxide is carried out surface organic modification, carry out inorganic modified with surface bag silicon alclad to nano titanium oxide, making one of its monomer that can be dispersed in polyester is in the dibasic alcohol, by metering the nano titanium oxide/dibasic alcohol slurry for preparing is arrived the median size of nano-titanium oxide less than 50 nanometers by high speed dispersion and circulation sanded then, last and other monomers of polyester carry out polymerization or copolymerization, and original position obtains anti-ultraviolet nano titanium dioxide/polyester composite in polymerization process.
2, the method for utilizing nano titanium oxide in-situ preparing anti-ultraviolet radiation poly ester according to claim 1 is characterized in that concrete steps are as follows:
(1) nano-titanium oxide is carried out the surface inorganic coating modification, at first adopting chemical precipitation method to coat thickness on the nano-titanium oxide surface is the silicon-dioxide of 5 nanometers, adopt equally then and carry out alumina-coated on the nano-titanium oxide of chemical precipitation method after wrapping silicon-dioxide again, coating layer also is 5 nanometers, obtains the modified Nano titanium oxide of surface bag silicon alclad at last;
(2) will be dispersed in 95% the ethanolic soln through inorganic modified nano-titanium oxide, the mass percentage content of nano-titanium oxide is 20%, with polymer organic treatment agent or coupling agent it is carried out surface organic modification again, consumption is 3~15% of a nano-titanium oxide, and washing and filtering places 1 hour dry for standby of 100 ℃ of baking ovens;
(3) with above-mentioned process inorganic/nano-titanium oxide of organic complex modification is dispersed in the dibasic alcohol, solid content is 5~30% mass percents, at first adopt high speed dispersor that nano-titanium oxide/dibasic alcohol slurry is mixed, use sand mill that slurry is ground dispersion till the titanium oxide particle diameter reaches below 50 nanometers then;
(4) another monomer of the nano-titanium oxide that above-mentioned steps is obtained/dibasic alcohol slurry and polyester---aromatic binary carboxylic acid carries out polyreaction under the condition that has catalyzer and stablizer to exist, the nano-titanium oxide addition of modification accounts for 0.5%~5% of polyester total amount, according to the field that final material is used, original position obtains the nano-titanium oxide/polyester composite of various molecular weight.
3, the method for utilizing nano titanium oxide in-situ preparing anti-ultraviolet radiation poly ester according to claim 1 and 2 is characterized in that, described nano-titanium oxide is a rutile crystal type, particle diameter 10~30 nanometers.
4, the method for utilizing nano titanium oxide in-situ preparing anti-ultraviolet radiation poly ester according to claim 2, it is characterized in that, described bag silicon is handled and is adopted acid to drip chemical precipitation method, with the water glass is presoma, the silicon-dioxide metering is 5~10% mass percents of nano-titanium oxide, described alclad is handled and is adopted alkali to drip chemical precipitation method, is presoma with Tai-Ace S 150, and the aluminum oxide metering is 3~8% mass percents of nano-titanium oxide.
5, the method for utilizing nano titanium oxide in-situ preparing anti-ultraviolet radiation poly ester according to claim 2, it is characterized in that, described polymer organic treatment agent is a polyoxyethylene glycol, in polyvinylpyrrolidone, polyvinyl alcohol, polyacrylic acid, the polyacrylamide one or more, described coupling agent is meant silane coupling agent, one or more in titanate coupling agent and the aluminic acid ester.
6, the method for utilizing nano titanium oxide in-situ preparing anti-ultraviolet radiation poly ester according to claim 1 and 2, it is characterized in that, the dibasic alcohol of described polyester is a kind of in ethylene glycol, propylene glycol, the butyleneglycol, and another kind of monomer is one or more in dimethyl terephthalate (DMT), terephthalic acid, dimethyl isophthalate, naphthalene two dimethyl phthalates.
7, the method for utilizing nano titanium oxide in-situ preparing anti-ultraviolet radiation poly ester according to claim 1 and 2, it is characterized in that, described nano-titanium oxide through modification participates in the polyester reaction separately, perhaps together carries out polyreaction with chemical fibre of titanium dioxide.
CN 200310122743 2003-12-19 2003-12-19 Method for preparing uvioresistant polyester by nanometer titania in situ Expired - Fee Related CN1224640C (en)

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